fbpx
Wikipedia

Ribosome

February 16, 2024

Ribosomes (/ˈrbəzm, -sm/) are macromolecular machines, found within all cells, that perform biological protein synthesis (messenger RNA translation). Ribosomal RNA is found in the ribosomal nucleus[clarification needed] where this synthesis happens. Ribosomes link amino acids together in the order specified by the codons of messenger RNA molecules to form polypeptide chains. Ribosomes consist of two major components: the small and large ribosomal subunits. Each subunit consists of one or more ribosomal RNA molecules and many ribosomal proteins (r-proteins).[1][2][3] The ribosomes and associated molecules are also known as the translational apparatus.

Large (red) and small (blue) subunits of a ribosome

Overview edit

The sequence of DNA that encodes the sequence of the amino acids in a protein is transcribed into a messenger RNA (mRNA) chain. Ribosomes bind to messenger RNAs and use their sequences[clarification needed] to determine the correct sequence of amino acids to generate a given protein. Amino acids are selected and carried to the ribosome by transfer RNA (tRNA) molecules, which enter the ribosome and bind to the messenger RNA chain via an anti-codon stem loop. For each coding triplet (codon) in the messenger RNA, there is a unique transfer RNA that must have the exact anti-codon match, and carries the correct amino acid for incorporating into a growing polypeptide chain. Once the protein is produced, it can then fold to produce a functional three-dimensional structure.

A ribosome is made from complexes of RNAs and proteins and is therefore a ribonucleoprotein complex. Each ribosome is composed of small (30S) and large (50S) components, called subunits, which are bound to each other:

  1. (30S) has mainly a decoding function and is also bound to the mRNA
  2. (50S) has mainly a catalytic function and is also bound to the aminoacylated tRNAs.

The synthesis of proteins from their building blocks takes place in four phases: initiation, elongation, termination, and recycling. The start codon in all mRNA molecules has the sequence AUG. The stop codon is one of UAA, UAG, or UGA; since there are no tRNA molecules that recognize these codons, the ribosome recognizes that translation is complete.[4] When a ribosome finishes reading an mRNA molecule, the two subunits separate and are usually broken up but can be reused. Ribosomes are ribozymes because the catalytic peptidyl transferase activity that links amino acids together is performed by the ribosomal RNA.[5]

Ribosomes are often associated with the intracellular membranes that make up the rough endoplasmic reticulum.

Ribosomes from bacteria, archaea, and eukaryotes in the three-domain system resemble each other to a remarkable degree, evidence of a common origin. They differ in their size, sequence, structure, and the ratio of protein to RNA. The differences in structure allow some antibiotics to kill bacteria by inhibiting their ribosomes while leaving human ribosomes unaffected. In all species, more than one ribosome may move along a single mRNA chain at one time (as a polysome), each "reading" a specific sequence and producing a corresponding protein molecule.

The mitochondrial ribosomes of eukaryotic cells functionally resemble many features of those in bacteria, reflecting the likely evolutionary origin of mitochondria.[6][7]

Discovery edit

Ribosomes were first observed in the mid-1950s by Romanian-American cell biologist George Emil Palade, using an electron microscope, as dense particles or granules.[8] They were initially called Palade granules due to their granular structure. The term "ribosome" was proposed in 1958 by Howard M. Dintzis:[9]

During the course of the symposium a semantic difficulty became apparent. To some of the participants, "microsomes" mean the ribonucleoprotein particles of the microsome fraction contaminated by other protein and lipid material; to others, the microsomes consist of protein and lipid contaminated by particles. The phrase "microsomal particles" does not seem adequate, and "ribonucleoprotein particles of the microsome fraction" is much too awkward. During the meeting, the word "ribosome" was suggested, which has a very satisfactory name and a pleasant sound. The present confusion would be eliminated if "ribosome" were adopted to designate ribonucleoprotein particles in sizes ranging from 35 to 100S.

— Albert Claude, Microsomal Particles and Protein Synthesis[10]

Albert Claude, Christian de Duve, and George Emil Palade were jointly awarded the Nobel Prize in Physiology or Medicine, in 1974, for the discovery of the ribosome.[11] The Nobel Prize in Chemistry 2009 was awarded to Venkatraman Ramakrishnan, Thomas A. Steitz and Ada E. Yonath for determining the detailed structure and mechanism of the ribosome.[12]

Structure edit

 
Ribosomes assemble polymeric protein molecules, the order of which is controlled by the messenger RNA's molecule sequence.
 
Ribosomal RNA composition for prokaryotes and eukaryotes

The ribosome is a complex cellular machine. It is largely made up of specialized RNA known as ribosomal RNA (rRNA) as well as dozens of distinct proteins (the exact number varies slightly between species). The ribosomal proteins and rRNAs are arranged into two distinct ribosomal pieces of different sizes, known generally as the large and small subunits of the ribosome. Ribosomes consist of two subunits that fit together and work as one to translate the mRNA into a polypeptide chain during protein synthesis. Because they are formed from two subunits of non-equal size, they are slightly longer on the axis than in diameter.

Prokaryotic ribosomes edit

Prokaryotic ribosomes are around 20 nm (200 Å) in diameter and are composed of 65% rRNA and 35% ribosomal proteins.[13] Eukaryotic ribosomes are between 25 and 30 nm (250–300 Å) in diameter with an rRNA-to-protein ratio that is close to 1.[14] Crystallographic work[15] has shown that there are no ribosomal proteins close to the reaction site for polypeptide synthesis. This suggests that the protein components of ribosomes do not directly participate in peptide bond formation catalysis, but rather that these proteins act as a scaffold that may enhance the ability of rRNA to synthesize protein (see: Ribozyme).

 
Molecular structure of the 30S subunit from Thermus thermophilus.[16] Proteins are shown in blue and the single RNA chain in brown.

The ribosomal subunits of prokaryotes and eukaryotes are quite similar.[17]

The unit of measurement used to describe the ribosomal subunits and the rRNA fragments is the Svedberg unit, a measure of the rate of sedimentation in centrifugation rather than size. This accounts for why fragment names do not add up: for example, bacterial 70S ribosomes are made of 50S and 30S subunits.

Prokaryotes have 70S ribosomes, each consisting of a small (30S) and a large (50S) subunit. E. coli, for example, has a 16S RNA subunit (consisting of 1540 nucleotides) that is bound to 21 proteins. The large subunit is composed of a 5S RNA subunit (120 nucleotides), a 23S RNA subunit (2900 nucleotides) and 31 proteins.[17]

Ribosome of E. coli (a bacterium)[18]: 962 
ribosome subunit rRNAs r-proteins
70S 50S 23S (2904 nt) 31
5S (120 nt)
30S 16S (1542 nt) 21

Affinity label for the tRNA binding sites on the E. coli ribosome allowed the identification of A and P site proteins most likely associated with the peptidyltransferase activity;[5] labelled proteins are L27, L14, L15, L16, L2; at least L27 is located at the donor site, as shown by E. Collatz and A.P. Czernilofsky.[19][20] Additional research has demonstrated that the S1 and S21 proteins, in association with the 3′-end of 16S ribosomal RNA, are involved in the initiation of translation.[21]

Archaeal ribosomes edit

Archaeal ribosomes share the same general dimensions of bacteria ones, being a 70S ribosome made up from a 50S large subunit, a 30S small subunit, and containing three rRNA chains. However, on the sequence level, they are much closer to eukaryotic ones than to bacterial ones. Every extra ribosomal protein archaea have compared to bacteria has a eukaryotic counterpart, while no such relation applies between archaea and bacteria.[22][23][24]

Eukaryotic ribosomes edit

Main article: Eukaryotic ribosome

Eukaryotes have 80S ribosomes located in their cytosol, each consisting of a small (40S) and large (60S) subunit. Their 40S subunit has an 18S RNA (1900 nucleotides) and 33 proteins.[25][26] The large subunit is composed of a 5S RNA (120 nucleotides), 28S RNA (4700 nucleotides), a 5.8S RNA (160 nucleotides) subunits and 49 proteins.[17][25][27]

eukaryotic cytosolic ribosomes (R. norvegicus)[18]: 65 
ribosome subunit rRNAs r-proteins
80S 60S 28S (4718 nt) 49
5.8S (160 nt)
5S (120 nt)
40S 18S (1874 nt) 33

During 1977, Czernilofsky published research that used affinity labeling to identify tRNA-binding sites on rat liver ribosomes. Several proteins, including L32/33, L36, L21, L23, L28/29 and L13 were implicated as being at or near the peptidyl transferase center.[28]

Plastoribosomes and mitoribosomes edit

Main articles: Mitochondrial ribosome and Chloroplast § Chloroplast ribosomes

In eukaryotes, ribosomes are present in mitochondria (sometimes called mitoribosomes) and in plastids such as chloroplasts (also called plastoribosomes). They also consist of large and small subunits bound together with proteins into one 70S particle.[17] These ribosomes are similar to those of bacteria and these organelles are thought to have originated as symbiotic bacteria.[17] Of the two, chloroplastic ribosomes are closer to bacterial ones than mitochondrial ones are. Many pieces of ribosomal RNA in the mitochondria are shortened, and in the case of 5S rRNA, replaced by other structures in animals and fungi.[29] In particular, Leishmania tarentolae has a minimalized set of mitochondrial rRNA.[30] In contrast, plant mitoribosomes have both extended rRNA and additional proteins as compared to bacteria, in particular, many pentatricopetide repeat proteins.[31]

The cryptomonad and chlorarachniophyte algae may contain a nucleomorph that resembles a vestigial eukaryotic nucleus.[32] Eukaryotic 80S ribosomes may be present in the compartment containing the nucleomorph.[33]

Making use of the differences edit

The differences between the bacterial and eukaryotic ribosomes are exploited by pharmaceutical chemists to create antibiotics that can destroy a bacterial infection without harming the cells of the infected person. Due to the differences in their structures, the bacterial 70S ribosomes are vulnerable to these antibiotics while the eukaryotic 80S ribosomes are not.[34] Even though mitochondria possess ribosomes similar to the bacterial ones, mitochondria are not affected by these antibiotics because they are surrounded by a double membrane that does not easily admit these antibiotics into the organelle.[35] A noteworthy counterexample is the antineoplastic antibiotic chloramphenicol, which inhibits bacterial 50S and eukaryotic mitochondrial 50S ribosomes.[36] Ribosomes in chloroplasts, however, are different: Antibiotic resistance in chloroplast ribosomal proteins is a trait that has to be introduced as a marker, with genetic engineering.[37]

Common properties edit

The various ribosomes share a core structure, which is quite similar despite the large differences in size. Much of the RNA is highly organized into various tertiary structural motifs, for example pseudoknots that exhibit coaxial stacking. The extra RNA in the larger ribosomes is in several long continuous insertions,[38] such that they form loops out of the core structure without disrupting or changing it.[17] All of the catalytic activity of the ribosome is carried out by the RNA; the proteins reside on the surface and seem to stabilize the structure.[17]

High-resolution structure edit

 
Figure 4: Atomic structure of the 50S subunit from Haloarcula marismortui. Proteins are shown in blue and the two RNA chains in brown and yellow.[39] The small patch of green in the center of the subunit is the active site.

The general molecular structure of the ribosome has been known since the early 1970s. In the early 2000s, the structure has been achieved at high resolutions, of the order of a few ångströms.

The first papers giving the structure of the ribosome at atomic resolution were published almost simultaneously in late 2000. The 50S (large prokaryotic) subunit was determined from the archaeon Haloarcula marismortui[39] and the bacterium Deinococcus radiodurans,[40] and the structure of the 30S subunit was determined from Thermus thermophilus.[16] These structural studies were awarded the Nobel Prize in Chemistry in 2009. In May 2001 these coordinates were used to reconstruct the entire T. thermophilus 70S particle at 5.5 Å resolution.[41]

Two papers were published in November 2005 with structures of the Escherichia coli 70S ribosome. The structures of a vacant ribosome were determined at 3.5 Å resolution using X-ray crystallography.[42] Then, two weeks later, a structure based on cryo-electron microscopy was published,[43] which depicts the ribosome at 11–15 Å resolution in the act of passing a newly synthesized protein strand into the protein-conducting channel.

The first atomic structures of the ribosome complexed with tRNA and mRNA molecules were solved by using X-ray crystallography by two groups independently, at 2.8 Å[44] and at 3.7 Å.[45] These structures allow one to see the details of interactions of the Thermus thermophilus ribosome with mRNA and with tRNAs bound at classical ribosomal sites. Interactions of the ribosome with long mRNAs containing Shine-Dalgarno sequences were visualized soon after that at 4.5–5.5 Å resolution.[46]

In 2011, the first complete atomic structure of the eukaryotic 80S ribosome from the yeast Saccharomyces cerevisiae was obtained by crystallography.[25] The model reveals the architecture of eukaryote-specific elements and their interaction with the universally conserved core. At the same time, the complete model of a eukaryotic 40S ribosomal structure in Tetrahymena thermophila was published and described the structure of the 40S subunit, as well as much about the 40S subunit's interaction with eIF1 during translation initiation.[26] Similarly, the eukaryotic 60S subunit structure was also determined from Tetrahymena thermophila in complex with eIF6.[27]

Function edit

Ribosomes are minute particles consisting of RNA and associated proteins that function to synthesize proteins. Proteins are needed for many cellular functions, such as repairing damage or directing chemical processes. Ribosomes can be found floating within the cytoplasm or attached to the endoplasmic reticulum. Their main function is to convert genetic code into an amino acid sequence and to build protein polymers from amino acid monomers.

Ribosomes act as catalysts in two extremely important biological processes called peptidyl transfer and peptidyl hydrolysis.[5][47] The "PT center is responsible for producing protein bonds during protein elongation".[47]

In summary, ribosomes have two main functions: Decoding the message, and the formation of peptide bonds. These two functions reside in the ribosomal subunits. Each subunit is made of one or more rRNAs and many r-proteins. The small subunit (30S in bacteria and archaea, 40S in eukaryotes) has the decoding function, whereas the large subunit (50S in bacteria and archaea, 60S in eukaryotes) catalyzes the formation of peptide bonds, referred to as the peptidyl-transferase activity. The bacterial (and archaeal) small subunit contains the 16S rRNA and 21 r-proteins (Escherichia coli), whereas the eukaryotic small subunit contains the 18S rRNA and 32 r-proteins (Saccharomyces cerevisiae, although the numbers vary between species). The bacterial large subunit contains the 5S and 23S rRNAs and 34 r-proteins (E. coli), with the eukaryotic large subunit containing the 5S, 5.8S, and 25S/28S rRNAs and 46 r-proteins (S. cerevisiae; again, the exact numbers vary between species).[48]

Translation edit

Main article: Translation (biology)

Ribosomes are the workplaces of protein biosynthesis, the process of translating mRNA into protein. The mRNA comprises a series of codons which are decoded by the ribosome so as to make the protein. Using the mRNA as a template, the ribosome traverses each codon (3 nucleotides) of the mRNA, pairing it with the appropriate amino acid provided by an aminoacyl-tRNA. Aminoacyl-tRNA contains a complementary anticodon on one end and the appropriate amino acid on the other. For fast and accurate recognition of the appropriate tRNA, the ribosome utilizes large conformational changes (conformational proofreading).[49] The small ribosomal subunit, typically bound to an aminoacyl-tRNA containing the first amino acid methionine, binds to an AUG codon on the mRNA and recruits the large ribosomal subunit. The ribosome contains three RNA binding sites, designated A, P, and E. The A-site binds an aminoacyl-tRNA or termination release factors;[50][51] the P-site binds a peptidyl-tRNA (a tRNA bound to the poly-peptide chain); and the E-site (exit) binds a free tRNA. Protein synthesis begins at a start codon AUG near the 5' end of the mRNA. mRNA binds to the P site of the ribosome first. The ribosome recognizes the start codon by using the Shine-Dalgarno sequence of the mRNA in prokaryotes and Kozak box in eukaryotes.

Although catalysis of the peptide bond involves the C2 hydroxyl of RNA's P-site adenosine in a proton shuttle mechanism, other steps in protein synthesis (such as translocation) are caused by changes in protein conformations. Since their catalytic core is made of RNA, ribosomes are classified as "ribozymes,"[52] and it is thought that they might be remnants of the RNA world.[53]

 
Figure 5: Translation of mRNA (1) by a ribosome (2)(shown as small and large subunits) into a polypeptide chain (3). The ribosome begins at the start codon of RNA (AUG) and ends at the stop codon (UAG).

In Figure 5, both ribosomal subunits (small and large) assemble at the start codon (towards the 5' end of the mRNA). The ribosome uses tRNA that matches the current codon (triplet) on the mRNA to append an amino acid to the polypeptide chain. This is done for each triplet on the mRNA, while the ribosome moves towards the 3' end of the mRNA. Usually in bacterial cells, several ribosomes are working parallel on a single mRNA, forming what is called a polyribosome or polysome.

Cotranslational folding edit

The ribosome is known to actively participate in the protein folding.[54][55] The structures obtained in this way are usually identical to the ones obtained during protein chemical refolding; however, the pathways leading to the final product may be different.[56][57] In some cases, the ribosome is crucial in obtaining the functional protein form. For example, one of the possible mechanisms of folding of the deeply knotted proteins relies on the ribosome pushing the chain through the attached loop.[58]

Addition of translation-independent amino acids edit

Presence of a ribosome quality control protein Rqc2 is associated with mRNA-independent protein elongation.[59][60] This elongation is a result of ribosomal addition (via tRNAs brought by Rqc2) of CAT tails: ribosomes extend the C-terminus of a stalled protein with random, translation-independent sequences of alanines and threonines.[61][62]

Ribosome locations edit

Ribosomes are classified as being either "free" or "membrane-bound".

 
Figure 6: A ribosome translating a protein that is secreted into the endoplasmic reticulum.

Free and membrane-bound ribosomes differ only in their spatial distribution; they are identical in structure. Whether the ribosome exists in a free or membrane-bound state depends on the presence of an ER-targeting signal sequence on the protein being synthesized, so an individual ribosome might be membrane-bound when it is making one protein, but free in the cytosol when it makes another protein.

Ribosomes are sometimes referred to as organelles, but the use of the term organelle is often restricted to describing sub-cellular components that include a phospholipid membrane, which ribosomes, being entirely particulate, do not. For this reason, ribosomes may sometimes be described as "non-membranous organelles".

Free ribosomes edit

Free ribosomes can move about anywhere in the cytosol, but are excluded from the cell nucleus and other organelles. Proteins that are formed from free ribosomes are released into the cytosol and used within the cell. Since the cytosol contains high concentrations of glutathione and is, therefore, a reducing environment, proteins containing disulfide bonds, which are formed from oxidized cysteine residues, cannot be produced within it.

Membrane-bound ribosomes edit

When a ribosome begins to synthesize proteins that are needed in some organelles, the ribosome making this protein can become "membrane-bound". In eukaryotic cells this happens in a region of the endoplasmic reticulum (ER) called the "rough ER". The newly produced polypeptide chains are inserted directly into the ER by the ribosome undertaking vectorial synthesis and are then transported to their destinations, through the secretory pathway. Bound ribosomes usually produce proteins that are used within the plasma membrane or are expelled from the cell via exocytosis.[63]

Biogenesis edit

Main article: Ribosome biogenesis

In bacterial cells, ribosomes are synthesized in the cytoplasm through the transcription of multiple ribosome gene operons. In eukaryotes, the process takes place both in the cell cytoplasm and in the nucleolus, which is a region within the cell nucleus. The assembly process involves the coordinated function of over 200 proteins in the synthesis and processing of the four rRNAs, as well as assembly of those rRNAs with the ribosomal proteins.[64]

Origin edit

The ribosome may have first originated as a protoribosome,[65] possibly containing a peptidyl transferase centre (PTC), in an RNA world, appearing as a self-replicating complex that only later evolved the ability to synthesize proteins when amino acids began to appear.[66] Studies suggest that ancient ribosomes constructed solely of rRNA could have developed the ability to synthesize peptide bonds.[67][68][69][70][71] In addition, evidence strongly points to ancient ribosomes as self-replicating complexes, where the rRNA in the ribosomes had informational, structural, and catalytic purposes because it could have coded for tRNAs and proteins needed for ribosomal self-replication.[72] Hypothetical cellular organisms with self-replicating RNA but without DNA are called ribocytes (or ribocells).[73][74]

As amino acids gradually appeared in the RNA world under prebiotic conditions,[75][76] their interactions with catalytic RNA would increase both the range and efficiency of function of catalytic RNA molecules.[66] Thus, the driving force for the evolution of the ribosome from an ancient self-replicating machine into its current form as a translational machine may have been the selective pressure to incorporate proteins into the ribosome's self-replicating mechanisms, so as to increase its capacity for self-replication.[72][77][78]

Heterogeneous ribosomes edit

Ribosomes are compositionally heterogeneous between species and even within the same cell, as evidenced by the existence of cytoplasmic and mitochondria ribosomes within the same eukaryotic cells. Certain researchers have suggested that heterogeneity in the composition of ribosomal proteins in mammals is important for gene regulation, i.e., the specialized ribosome hypothesis.[79][80] However, this hypothesis is controversial and the topic of ongoing research.[81][82]

Heterogeneity in ribosome composition was first proposed to be involved in translational control of protein synthesis by Vince Mauro and Gerald Edelman.[83] They proposed the ribosome filter hypothesis to explain the regulatory functions of ribosomes. Evidence has suggested that specialized ribosomes specific to different cell populations may affect how genes are translated.[84] Some ribosomal proteins exchange from the assembled complex with cytosolic copies[85] suggesting that the structure of the in vivo ribosome can be modified without synthesizing an entire new ribosome.

Certain ribosomal proteins are absolutely critical for cellular life while others are not. In budding yeast, 14/78 ribosomal proteins are non-essential for growth, while in humans this depends on the cell of study.[86] Other forms of heterogeneity include post-translational modifications to ribosomal proteins such as acetylation, methylation, and phosphorylation.[87] Arabidopsis,[88][89][90][91] Viral internal ribosome entry sites (IRESs) may mediate translations by compositionally distinct ribosomes. For example, 40S ribosomal units without eS25 in yeast and mammalian cells are unable to recruit the CrPV IGR IRES.[92]

Heterogeneity of ribosomal RNA modifications plays a significant role in structural maintenance and/or function and most mRNA modifications are found in highly conserved regions.[93][94] The most common rRNA modifications are pseudouridylation and 2'-O-methylation of ribose.[95]

See also edit

References edit

  1. ^ Konikkat S (February 2016). (Ph.D. thesis). Carnegie Mellon University. Archived from the original on 3 August 2017.
  2. ^ Weiler EW, Nover L (2008). Allgemeine und Molekulare Botanik (in German). Stuttgart: Georg Thieme Verlag. p. 532. ISBN 9783131527912.
  3. ^ de la Cruz J, Karbstein K, Woolford JL (2015). "Functions of ribosomal proteins in assembly of eukaryotic ribosomes in vivo". Annual Review of Biochemistry. 84: 93–129. doi:10.1146/annurev-biochem-060614-033917. PMC 4772166. PMID 25706898.
  4. ^ "Scitable by nature translation / RNA translation".
  5. ^ a b c Tirumalai MR, Rivas M, Tran Q, Fox GE (November 2021). "The Peptidyl Transferase Center: a Window to the Past". Microbiol Mol Biol Rev. 85 (4): e0010421. doi:10.1128/MMBR.00104-21. PMC 8579967. PMID 34756086.
  6. ^ Benne R, Sloof P (1987). "Evolution of the mitochondrial protein synthetic machinery". Bio Systems. 21 (1): 51–68. Bibcode:1987BiSys..21...51B. doi:10.1016/0303-2647(87)90006-2. PMID 2446672.
  7. ^ . Archived from the original on 2009-03-20. Retrieved 2011-04-28.
  8. ^ Palade GE (January 1955). "A small particulate component of the cytoplasm". The Journal of Biophysical and Biochemical Cytology. 1 (1): 59–68. doi:10.1083/jcb.1.1.59. PMC 2223592. PMID 14381428.
  9. ^ Rheinberger, Hans-Jörg (September 2022). "A Brief History of Protein Biosynthesis and Ribosome Research". Lindau Nobel Laureate Meetings. Retrieved 2023-08-16.
  10. ^ Roberts RB, ed. (1958). "Introduction". Microsomal Particles and Protein Synthesis. New York: Pergamon Press, Inc.
  11. ^ "The Nobel Prize in Physiology or Medicine 1974". Nobelprize.org. The Nobel Foundation. from the original on 26 January 2013. Retrieved 10 December 2012.
  12. ^ "2009 Nobel Prize in Chemistry". The Nobel Foundation. from the original on 28 April 2012. Retrieved 10 December 2012.
  13. ^ Kurland CG (1960). "Molecular characterization of ribonucleic acid from Escherichia coli ribosomes". Journal of Molecular Biology. 2 (2): 83–91. doi:10.1016/s0022-2836(60)80029-0.
  14. ^ Wilson DN, Doudna Cate JH (May 2012). "The structure and function of the eukaryotic ribosome". Cold Spring Harbor Perspectives in Biology. 4 (5): a011536. doi:10.1101/cshperspect.a011536. PMC 3331703. PMID 22550233.
  15. ^ Nissen P, Hansen J, Ban N, Moore PB, Steitz TA (August 2000). (PDF). Science. 289 (5481): 920–30. Bibcode:2000Sci...289..920N. doi:10.1126/science.289.5481.920. PMID 10937990. S2CID 8370119. Archived from the original (PDF) on 2020-11-30.
  16. ^ a b Wimberly BT, Brodersen DE, Clemons WM, Morgan-Warren RJ, Carter AP, Vonrhein C, Hartsch T, Ramakrishnan V (September 2000). "Structure of the 30S ribosomal subunit". Nature. 407 (6802): 327–39. Bibcode:2000Natur.407..327W. doi:10.1038/35030006. PMID 11014182. S2CID 4419944.
  17. ^ a b c d e f g Alberts B, Johnson A, Lewis J, Raff M, Roberts K, Walter P (2002). "Membrane-bound Ribosomes Define the Rough ER". Molecular Biology of the Cell (4th ed.). New York: Garland Science. p. 342. ISBN 978-0-8153-4072-0.
  18. ^ a b Garrett R, Grisham CM (2009). Biochemistry (4th ed.). Cengage Learning Services. ISBN 978-0-495-11464-2.
  19. ^ Collatz E, Küchler E, Stöffler G, Czernilofsky AP (April 1976). "The site of reaction on ribosomal protein L27 with an affinity label derivative of tRNA Met f". FEBS Letters. 63 (2): 283–6. doi:10.1016/0014-5793(76)80112-3. PMID 770196.
  20. ^ Czernilofsky AP, Collatz EE, Stöffler G, Kuechler E (January 1974). "Proteins at the tRNA binding sites of Escherichia coli ribosomes". Proceedings of the National Academy of Sciences of the United States of America. 71 (1): 230–4. Bibcode:1974PNAS...71..230C. doi:10.1073/pnas.71.1.230. PMC 387971. PMID 4589893.
  21. ^ Czernilofsky AP, Kurland CG, Stöffler G (October 1975). "30S ribosomal proteins associated with the 3'-terminus of 16S RNA". FEBS Letters. 58 (1): 281–4. doi:10.1016/0014-5793(75)80279-1. PMID 1225593.
  22. ^ Cullen KE (2009). "Archaeal Ribosomes". Encyclopedia of Life Science. New York: Facts On File. pp. 1–5. doi:10.1002/9780470015902.a0000293.pub3. ISBN 9780470015902. S2CID 243730576.
  23. ^ Tirumalai MR, Anane-Bediakoh D, Rajesh R, Fox GE (November 2021). "Net Charges of the Ribosomal Proteins of the S10 and spc Clusters of Halophiles Are Inversely Related to the Degree of Halotolerance". Microbiol. Spectr. 9 (3): e0178221. doi:10.1128/spectrum.01782-21. PMC 8672879. PMID 34908470.
  24. ^ Wang J, Dasgupta I, Fox GE (28 April 2009). "Many nonuniversal archaeal ribosomal proteins are found in conserved gene clusters". Archaea. 2 (4): 241–51. doi:10.1155/2009/971494. PMC 2686390. PMID 19478915.
  25. ^ a b c Ben-Shem A, Garreau de Loubresse N, Melnikov S, Jenner L, Yusupova G, Yusupov M (December 2011). "The structure of the eukaryotic ribosome at 3.0 Å resolution". Science. 334 (6062): 1524–9. Bibcode:2011Sci...334.1524B. doi:10.1126/science.1212642. PMID 22096102. S2CID 9099683.
  26. ^ a b Rabl J, Leibundgut M, Ataide SF, Haag A, Ban N (February 2011). "Crystal structure of the eukaryotic 40S ribosomal subunit in complex with initiation factor 1" (PDF). Science. 331 (6018): 730–6. Bibcode:2011Sci...331..730R. doi:10.1126/science.1198308. hdl:20.500.11850/153130. PMID 21205638. S2CID 24771575.
  27. ^ a b Klinge S, Voigts-Hoffmann F, Leibundgut M, Arpagaus S, Ban N (November 2011). "Crystal structure of the eukaryotic 60S ribosomal subunit in complex with initiation factor 6". Science. 334 (6058): 941–8. Bibcode:2011Sci...334..941K. doi:10.1126/science.1211204. PMID 22052974. S2CID 206536444.
  28. ^ Fabijanski S, Pellegrini M (1977). "Identification of proteins at the peptidyl-tRNA binding site of rat liver ribosomes". Molecular & General Genetics. 184 (3): 551–6. doi:10.1007/BF00431588. PMID 6950200. S2CID 9751945.
  29. ^ Agrawal RK, Sharma MR (December 2012). "Structural aspects of mitochondrial translational apparatus". Current Opinion in Structural Biology. 22 (6): 797–803. doi:10.1016/j.sbi.2012.08.003. PMC 3513651. PMID 22959417.
  30. ^ Sharma MR, Booth TM, Simpson L, Maslov DA, Agrawal RK (June 2009). "Structure of a mitochondrial ribosome with minimal RNA". Proceedings of the National Academy of Sciences of the United States of America. 106 (24): 9637–42. Bibcode:2009PNAS..106.9637S. doi:10.1073/pnas.0901631106. PMC 2700991. PMID 19497863.
  31. ^ Waltz F, Nguyen TT, Arrivé M, Bochler A, Chicher J, Hammann P, Kuhn L, Quadrado M, Mireau H, Hashem Y, Giegé P (January 2019). "Small is big in Arabidopsis mitochondrial ribosome". Nature Plants. 5 (1): 106–117. doi:10.1038/s41477-018-0339-y. PMID 30626926. S2CID 58004990.
  32. ^ Archibald JM, Lane CE (2009). "Going, going, not quite gone: nucleomorphs as a case study in nuclear genome reduction". The Journal of Heredity. 100 (5): 582–90. doi:10.1093/jhered/esp055. PMID 19617523.
  33. ^ "Specialized Internal Structures of Prokaryotes | Boundless Microbiology". courses.lumenlearning.com. Retrieved 2021-09-24.
  34. ^ Recht MI, Douthwaite S, Puglisi JD (June 1999). "Basis for prokaryotic specificity of action of aminoglycoside antibiotics". The EMBO Journal. 18 (11): 3133–8. doi:10.1093/emboj/18.11.3133. PMC 1171394. PMID 10357824.
  35. ^ O'Brien TW (May 1971). "The general occurrence of 55 S ribosomes in mammalian liver mitochondria". The Journal of Biological Chemistry. 246 (10): 3409–17. doi:10.1016/S0021-9258(18)62239-2. PMID 4930061.
  36. ^ "Chloramphenicol-lnduced Bone Marrow Suppression". JAMA. 213 (7): 1183–1184. 1970-08-17. doi:10.1001/jama.1970.03170330063011. ISSN 0098-7484. PMID 5468266.
  37. ^ Newman SM, Boynton JE, Gillham NW, Randolph-Anderson BL, Johnson AM, Harris EH (December 1990). "Transformation of chloroplast ribosomal RNA genes in Chlamydomonas: molecular and genetic characterization of integration events". Genetics. 126 (4): 875–88. doi:10.1093/genetics/126.4.875. PMC 1204285. PMID 1981764.
  38. ^ Penev PI, Fakhretaha-Aval S, Patel VJ, Cannone JJ, Gutell RR, Petrov AS, Williams LD, Glass JB (August 2020). "Supersized ribosomal RNA expansion segments in Asgard archaea". Genome Biology and Evolution. 12 (10): 1694–1710. doi:10.1093/gbe/evaa170. PMC 7594248. PMID 32785681.
  39. ^ a b Ban N, Nissen P, Hansen J, Moore PB, Steitz TA (August 2000). "The complete atomic structure of the large ribosomal subunit at 2.4 A resolution". Science. 289 (5481): 905–20. Bibcode:2000Sci...289..905B. CiteSeerX 10.1.1.58.2271. doi:10.1126/science.289.5481.905. PMID 10937989.
  40. ^ Schluenzen F, Tocilj A, Zarivach R, Harms J, Gluehmann M, Janell D, Bashan A, Bartels H, Agmon I, Franceschi F, Yonath A (September 2000). "Structure of functionally activated small ribosomal subunit at 3.3 angstroms resolution". Cell. 102 (5): 615–23. doi:10.1016/S0092-8674(00)00084-2. PMID 11007480. S2CID 1024446.
  41. ^ Yusupov MM, Yusupova GZ, Baucom A, Lieberman K, Earnest TN, Cate JH, Noller HF (May 2001). "Crystal structure of the ribosome at 5.5 A resolution". Science. 292 (5518): 883–96. Bibcode:2001Sci...292..883Y. doi:10.1126/science.1060089. PMID 11283358. S2CID 39505192.
  42. ^ Schuwirth BS, Borovinskaya MA, Hau CW, Zhang W, Vila-Sanjurjo A, Holton JM, Cate JH (November 2005). "Structures of the bacterial ribosome at 3.5 A resolution". Science. 310 (5749): 827–34. Bibcode:2005Sci...310..827S. doi:10.1126/science.1117230. PMID 16272117. S2CID 37382005.
  43. ^ Mitra K, Schaffitzel C, Shaikh T, Tama F, Jenni S, Brooks CL, Ban N, Frank J (November 2005). "Structure of the E. coli protein-conducting channel bound to a translating ribosome". Nature. 438 (7066): 318–24. Bibcode:2005Natur.438..318M. doi:10.1038/nature04133. PMC 1351281. PMID 16292303.
  44. ^ Selmer M, Dunham CM, Murphy FV, Weixlbaumer A, Petry S, Kelley AC, Weir JR, Ramakrishnan V (September 2006). "Structure of the 70S ribosome complexed with mRNA and tRNA". Science. 313 (5795): 1935–42. Bibcode:2006Sci...313.1935S. doi:10.1126/science.1131127. PMID 16959973. S2CID 9737925.
  45. ^ Korostelev A, Trakhanov S, Laurberg M, Noller HF (September 2006). "Crystal structure of a 70S ribosome-tRNA complex reveals functional interactions and rearrangements". Cell. 126 (6): 1065–77. doi:10.1016/j.cell.2006.08.032. PMID 16962654. S2CID 13452915.
  46. ^ Yusupova G, Jenner L, Rees B, Moras D, Yusupov M (November 2006). "Structural basis for messenger RNA movement on the ribosome". Nature. 444 (7117): 391–4. Bibcode:2006Natur.444..391Y. doi:10.1038/nature05281. PMID 17051149. S2CID 4419198.
  47. ^ a b "Specialized Internal Structures of Prokaryotes". courses.lumenlearning.com. Boundless Microbiology. Retrieved 2018-09-27.
  48. ^ Lafontaine, D.; Tollervey, D. (2001). "The function and synthesis of ribosomes". Nat Rev Mol Cell Biol. 2 (7): 514–520. doi:10.1038/35080045. hdl:1842/729. PMID 11433365. S2CID 2637106.
  49. ^ Savir Y, Tlusty T (April 2013). "The ribosome as an optimal decoder: A lesson in molecular recognition". Cell. 153 (2): 471–479. Bibcode:2013APS..MARY46006T. doi:10.1016/j.cell.2013.03.032. PMID 23582332.
  50. ^ Korkmaz G, Sanyal S (September 2017). "Escherichia coli". The Journal of Biological Chemistry. 292 (36): 15134–15142. doi:10.1074/jbc.M117.785238. PMC 5592688. PMID 28743745.
  51. ^ Konevega AL, Soboleva NG, Makhno VI, Semenkov YP, Wintermeyer W, Rodnina MV, Katunin VI (January 2004). "Purine bases at position 37 of tRNA stabilize codon-anticodon interaction in the ribosomal A site by stacking and Mg2+-dependent interactions". RNA. 10 (1): 90–101. doi:10.1261/rna.5142404. PMC 1370521. PMID 14681588.
  52. ^ Rodnina MV, Beringer M, Wintermeyer W (January 2007). "How ribosomes make peptide bonds". Trends in Biochemical Sciences. 32 (1): 20–26. doi:10.1016/j.tibs.2006.11.007. PMID 17157507.
  53. ^ Cech, T.R. (August 2000). "Structural biology. The ribosome is a ribozyme". Science. 289 (5481): 878–879. doi:10.1126/science.289.5481.878. PMID 10960319. S2CID 24172338.
  54. ^ Banerjee D, Sanyal S (October 2014). "Protein folding activity of the ribosome (PFAR) – a target for antiprion compounds". Viruses. 6 (10): 3907–3924. doi:10.3390/v6103907. PMC 4213570. PMID 25341659.
  55. ^ Fedorov AN, Baldwin TO (December 1997). "Cotranslational protein folding". The Journal of Biological Chemistry. 272 (52): 32715–32718. doi:10.1074/jbc.272.52.32715. PMID 9407040.
  56. ^ Baldwin RL (June 1975). "Intermediates in protein folding reactions and the mechanism of protein folding". Annual Review of Biochemistry. 44 (1): 453–475. doi:10.1146/annurev.bi.44.070175.002321. PMID 1094916.
  57. ^ Das D, Das A, Samanta D, Ghosh J, Dasgupta S, Bhattacharya A, Basu A, Sanyal S, Das Gupta C (August 2008). "Role of the ribosome in protein folding" (PDF). Biotechnology Journal. 3 (8): 999–1009. doi:10.1002/biot.200800098. PMID 18702035.
  58. ^ Dabrowski-Tumanski P, Piejko M, Niewieczerzal S, Stasiak A, Sulkowska JI (December 2018). "Protein knotting by active threading of nascent polypeptide chain exiting from the ribosome exit channel". The Journal of Physical Chemistry B. 122 (49): 11616–11625. doi:10.1021/acs.jpcb.8b07634. PMID 30198720. S2CID 52176392.
  59. ^ Brandman O, Stewart-Ornstein J, Wong D, Larson A, Williams CC, Li GW, Zhou S, King D, Shen PS, Weibezahn J, Dunn JG, Rouskin S, Inada T, Frost A, Weissman JS (November 2012). "A ribosome-bound quality control complex triggers degradation of nascent peptides and signals translation stress". Cell. 151 (5): 1042–1054. doi:10.1016/j.cell.2012.10.044. PMC 3534965. PMID 23178123.
  60. ^ Defenouillère Q, Yao Y, Mouaikel J, Namane A, Galopier A, Decourty L, Doyen A, Malabat C, Saveanu C, Jacquier A, Fromont-Racine M (March 2013). "Cdc48-associated complex bound to 60S particles is required for the clearance of aberrant translation products". Proceedings of the National Academy of Sciences of the United States of America. 110 (13): 5046–5051. Bibcode:2013PNAS..110.5046D. doi:10.1073/pnas.1221724110. PMC 3612664. PMID 23479637.
  61. ^ Shen PS, Park J, Qin Y, Li X, Parsawar K, Larson MH, Cox J, Cheng Y, Lambowitz AM, Weissman JS, Brandman O, Frost A (January 2015). "Protein synthesis. Rqc2p and 60S ribosomal subunits mediate mRNA-independent elongation of nascent chains". Science. 347 (6217): 75–78. Bibcode:2015Sci...347...75S. doi:10.1126/science.1259724. PMC 4451101. PMID 25554787.
  62. ^ Keeley, J.; Gutnikoff, R. (2 January 2015). "Ribosome studies turn up new mechanism of protein synthesis" (Press release). Howard Hughes Medical Institute. from the original on 12 January 2015. Retrieved 16 January 2015.
  63. ^ Alberts B, Johnson A, Lewis J, Raff M, Roberts K, Walter P (2002). "Membrane-bound Ribosomes Define the Rough ER". Molecular Biology of the Cell (4th ed.). New York: Garland Science. ISBN 978-0-8153-4072-0.
  64. ^ Kressler, Dieter; Hurt, Ed; Babler, Jochen (2009). "Driving ribosome assembly" (PDF). Biochimica et Biophysica Acta (BBA) - Molecular Cell Research. 1803 (6): 673–683. doi:10.1016/j.bbamcr.2009.10.009. PMID 19879902.
  65. ^ Dance, Amber (28 February 2023). "How did life begin? One key ingredient is coming into view - A Nobel-prizewinning scientist's team has taken a big step forward in its quest to reconstruct an early-Earth RNA capable of building proteins". Nature. 615 (7950): 22–25. doi:10.1038/d41586-023-00574-4. PMID 36854922.
  66. ^ a b Noller HF (April 2012). "Evolution of protein synthesis from an RNA world". Cold Spring Harbor Perspectives in Biology. 4 (4): a003681. doi:10.1101/cshperspect.a003681. PMC 3312679. PMID 20610545.
  67. ^ Dabbs ER (1986). Mutant studies on the prokaryotic ribosome. New York: Springer-Verlag.
  68. ^ Noller HF, Hoffarth V, Zimniak L (June 1992). "Unusual resistance of peptidyl transferase to protein extraction procedures". Science. 256 (5062): 1416–9. Bibcode:1992Sci...256.1416N. doi:10.1126/science.1604315. PMID 1604315.
  69. ^ Nomura M, Mizushima S, Ozaki M, Traub P, Lowry CV (1969). "Structure and function of ribosomes and their molecular components". Cold Spring Harbor Symposia on Quantitative Biology. 34: 49–61. doi:10.1101/sqb.1969.034.01.009. PMID 4909519.
  70. ^ Krupkin M, Matzov D, Tang H, Metz M, Kalaora R, Belousoff MJ, Zimmerman E, Bashan A, Yonath A (Oct 2011). "A vestige of a prebiotic bonding machine is functioning within the contemporary ribosome". Phil. Trans. R. Soc. B. 366 (1580): 2972–8. doi:10.1098/rstb.2011.0146. PMC 3158926. PMID 21930590.
  71. ^ Bose T, Fridkin G, Davidovich C, Krupkin M, Dinger N, Falkovich AH, Peleg Y, Agmon I, Bashan A, Yonat A (Feb 2022). "Origin of life: protoribosome forms peptide bonds and links RNA and protein dominated worlds". Nucleic Acids Res. 50 (4): 1815–1828. doi:10.1093/nar/gkac052. PMC 8886871. PMID 35137169.
  72. ^ a b Root-Bernstein M, Root-Bernstein R (February 2015). "The ribosome as a missing link in the evolution of life". Journal of Theoretical Biology. 367: 130–158. doi:10.1016/j.jtbi.2014.11.025. PMID 25500179.
  73. ^ Yarus M (2002). "Primordial genetics: phenotype of the ribocyte". Annual Review of Genetics. 36: 125–51. doi:10.1146/annurev.genet.36.031902.105056. PMID 12429689.
  74. ^ Forterre P, Krupovic M (2012). "The Origin of Virions and Virocells: The Escape Hypothesis Revisited". Viruses: Essential Agents of Life. pp. 43–60. doi:10.1007/978-94-007-4899-6_3. ISBN 978-94-007-4898-9.
  75. ^ Caetano-Anollés G, Seufferheld MJ (2013). "The coevolutionary roots of biochemistry and cellular organization challenge the RNA world paradigm". Journal of Molecular Microbiology and Biotechnology. 23 (1–2): 152–77. doi:10.1159/000346551. PMID 23615203. S2CID 41725226.
  76. ^ Saladino R, Botta G, Pino S, Costanzo G, Di Mauro E (August 2012). "Genetics first or metabolism first? The formamide clue". Chemical Society Reviews. 41 (16): 5526–65. doi:10.1039/c2cs35066a. hdl:11573/494138. PMID 22684046.
  77. ^ Fox GE (September 2010). "Origin and Evolution of the Ribosome". Cold Spring Harb Perspect Biol. 2 (9): a003483. doi:10.1101/cshperspect.a003483. PMC 2926754. PMID 20534711.
  78. ^ Fox GE (2016). "Origins and early evolution of the ribosome". In Hernández G, Jagus R (eds.). Evolution of the Protein Synthesis Machinery and Its Regulation. Switzerland: Springer, Cham. pp. 31–60. doi:10.1007/978-3-319-39468-8. ISBN 978-3-319-39468-8. S2CID 27493054.
  79. ^ Shi Z, Fujii K, Kovary KM, Genuth NR, Röst HL, Teruel MN, Barna M (July 2017). "Heterogeneous Ribosomes Preferentially Translate Distinct Subpools of mRNAs Genome-wide". Molecular Cell. Elsevier BV. 67 (1): 71–83.e7. doi:10.1016/j.molcel.2017.05.021. PMC 5548184. PMID 28625553.
  80. ^ Xue S, Barna M (May 2012). "Specialized ribosomes: a new frontier in gene regulation and organismal biology". Nature Reviews. Molecular Cell Biology. Springer Science and Business Media LLC. 13 (6): 355–369. doi:10.1038/nrm3359. PMC 4039366. PMID 22617470.
  81. ^ Ferretti MB, Karbstein K (May 2019). "Does functional specialization of ribosomes really exist?". RNA. Cold Spring Harbor Laboratory. 25 (5): 521–538. doi:10.1261/rna.069823.118. PMC 6467006. PMID 30733326.
  82. ^ Farley-Barnes KI, Ogawa LM, Baserga SJ (October 2019). "Ribosomopathies: Old Concepts, New Controversies". Trends in Genetics. Elsevier BV. 35 (10): 754–767. doi:10.1016/j.tig.2019.07.004. PMC 6852887. PMID 31376929.
  83. ^ Mauro VP, Edelman GM (September 2002). "The ribosome filter hypothesis". Proceedings of the National Academy of Sciences of the United States of America. 99 (19): 12031–6. Bibcode:2002PNAS...9912031M. doi:10.1073/pnas.192442499. PMC 129393. PMID 12221294.
  84. ^ Xue S, Barna M (May 2012). "Specialized ribosomes: a new frontier in gene regulation and organismal biology". Nature Reviews. Molecular Cell Biology. 13 (6): 355–69. doi:10.1038/nrm3359. PMC 4039366. PMID 22617470.
  85. ^ Mathis AD, Naylor BC, Carson RH, Evans E, Harwell J, Knecht J, Hexem E, Peelor FF, Miller BF, Hamilton KL, Transtrum MK, Bikman BT, Price JC (February 2017). "Mechanisms of In Vivo Ribosome Maintenance Change in Response to Nutrient Signals". Molecular & Cellular Proteomics. 16 (2): 243–254. doi:10.1074/mcp.M116.063255. PMC 5294211. PMID 27932527.
  86. ^ Steffen KK, McCormick MA, Pham KM, MacKay VL, Delaney JR, Murakami CJ, et al. (May 2012). "Ribosome deficiency protects against ER stress in Saccharomyces cerevisiae". Genetics. Genetics Society of America. 191 (1): 107–118. doi:10.1534/genetics.111.136549. PMC 3338253. PMID 22377630.
  87. ^ Lee SW, Berger SJ, Martinović S, Pasa-Tolić L, Anderson GA, Shen Y, et al. (April 2002). "Direct mass spectrometric analysis of intact proteins of the yeast large ribosomal subunit using capillary LC/FTICR". Proceedings of the National Academy of Sciences of the United States of America. 99 (9): 5942–5947. Bibcode:2002PNAS...99.5942L. doi:10.1073/pnas.082119899. PMC 122881. PMID 11983894.
  88. ^ Carroll AJ, Heazlewood JL, Ito J, Millar AH (February 2008). "Analysis of the Arabidopsis cytosolic ribosome proteome provides detailed insights into its components and their post-translational modification". Molecular & Cellular Proteomics. 7 (2): 347–369. doi:10.1074/mcp.m700052-mcp200. PMID 17934214.
  89. ^ Odintsova TI, Müller EC, Ivanov AV, Egorov TA, Bienert R, Vladimirov SN, et al. (April 2003). "Characterization and analysis of posttranslational modifications of the human large cytoplasmic ribosomal subunit proteins by mass spectrometry and Edman sequencing". Journal of Protein Chemistry. 22 (3): 249–258. doi:10.1023/a:1025068419698. PMID 12962325. S2CID 10710245.
  90. ^ Yu Y, Ji H, Doudna JA, Leary JA (June 2005). "Mass spectrometric analysis of the human 40S ribosomal subunit: native and HCV IRES-bound complexes". Protein Science. 14 (6): 1438–1446. doi:10.1110/ps.041293005. PMC 2253395. PMID 15883184.
  91. ^ Zeidan Q, Wang Z, De Maio A, Hart GW (June 2010). "O-GlcNAc cycling enzymes associate with the translational machinery and modify core ribosomal proteins". Molecular Biology of the Cell. 21 (12): 1922–1936. doi:10.1091/mbc.e09-11-0941. PMC 2883937. PMID 20410138.
  92. ^ Landry DM, Hertz MI, Thompson SR (December 2009). "RPS25 is essential for translation initiation by the Dicistroviridae and hepatitis C viral IRESs". Genes & Development. 23 (23): 2753–2764. doi:10.1101/gad.1832209. PMC 2788332. PMID 19952110.
  93. ^ Decatur WA, Fournier MJ (July 2002). "rRNA modifications and ribosome function". Trends in Biochemical Sciences. 27 (7): 344–51. doi:10.1016/s0968-0004(02)02109-6. PMID 12114023.
  94. ^ Natchiar SK, Myasnikov AG, Kratzat H, Hazemann I, Klaholz BP (November 2017). "Visualization of chemical modifications in the human 80S ribosome structure". Nature. 551 (7681): 472–477. Bibcode:2017Natur.551..472N. doi:10.1038/nature24482. PMID 29143818. S2CID 4465175.
  95. ^ Guo H (August 2018). "Specialized ribosomes and the control of translation". Biochemical Society Transactions. 46 (4): 855–869. doi:10.1042/BST20160426. PMID 29986937. S2CID 51609077.

External links edit

 
Wikimedia Commons has media related to Ribosomes.
  • Lab computer simulates ribosome in motion
  • , Gwen V. Childs, copied
  • Ribosome in Proteopedia—The free, collaborative 3D encyclopedia of proteins & other molecules
  • Ribosomal proteins families in ExPASy 2011-04-30 at the Wayback Machine
  • Molecule of the Month 2009-10-27 at the Wayback Machine :
  • 3D electron microscopy structures of ribosomes at the EM Data Bank (EMDB)
  •   This article incorporates public domain material from . NCBI. Archived from the original on 2009-12-08.

February 16, 2024
ribosome, macromolecular, machines, found, within, cells, that, perform, biological, protein, synthesis, messenger, translation, ribosomal, found, ribosomal, nucleus, clarification, needed, where, this, synthesis, happens, link, amino, acids, together, order, . Ribosomes ˈ r aɪ b e z oʊ m s oʊ m are macromolecular machines found within all cells that perform biological protein synthesis messenger RNA translation Ribosomal RNA is found in the ribosomal nucleus clarification needed where this synthesis happens Ribosomes link amino acids together in the order specified by the codons of messenger RNA molecules to form polypeptide chains Ribosomes consist of two major components the small and large ribosomal subunits Each subunit consists of one or more ribosomal RNA molecules and many ribosomal proteins r proteins 1 2 3 The ribosomes and associated molecules are also known as the translational apparatus Large red and small blue subunits of a ribosomeCell biologyAnimal cell diagramComponents of a typical animal cell Nucleolus Nucleus Ribosome dots as part of 5 Vesicle Rough endoplasmic reticulum Golgi apparatus or Golgi body Cytoskeleton Smooth endoplasmic reticulum Mitochondrion Vacuole Cytosol fluid that contains organelles with which comprises cytoplasm Lysosome Centrosome Cell membrane Contents 1 Overview 2 Discovery 3 Structure 3 1 Prokaryotic ribosomes 3 2 Archaeal ribosomes 3 3 Eukaryotic ribosomes 3 4 Plastoribosomes and mitoribosomes 3 5 Making use of the differences 3 6 Common properties 3 7 High resolution structure 4 Function 4 1 Translation 4 1 1 Cotranslational folding 4 2 Addition of translation independent amino acids 5 Ribosome locations 5 1 Free ribosomes 5 2 Membrane bound ribosomes 6 Biogenesis 7 Origin 8 Heterogeneous ribosomes 9 See also 10 References 11 External linksOverview editThe sequence of DNA that encodes the sequence of the amino acids in a protein is transcribed into a messenger RNA mRNA chain Ribosomes bind to messenger RNAs and use their sequences clarification needed to determine the correct sequence of amino acids to generate a given protein Amino acids are selected and carried to the ribosome by transfer RNA tRNA molecules which enter the ribosome and bind to the messenger RNA chain via an anti codon stem loop For each coding triplet codon in the messenger RNA there is a unique transfer RNA that must have the exact anti codon match and carries the correct amino acid for incorporating into a growing polypeptide chain Once the protein is produced it can then fold to produce a functional three dimensional structure A ribosome is made from complexes of RNAs and proteins and is therefore a ribonucleoprotein complex Each ribosome is composed of small 30S and large 50S components called subunits which are bound to each other 30S has mainly a decoding function and is also bound to the mRNA 50S has mainly a catalytic function and is also bound to the aminoacylated tRNAs The synthesis of proteins from their building blocks takes place in four phases initiation elongation termination and recycling The start codon in all mRNA molecules has the sequence AUG The stop codon is one of UAA UAG or UGA since there are no tRNA molecules that recognize these codons the ribosome recognizes that translation is complete 4 When a ribosome finishes reading an mRNA molecule the two subunits separate and are usually broken up but can be reused Ribosomes are ribozymes because the catalytic peptidyl transferase activity that links amino acids together is performed by the ribosomal RNA 5 Ribosomes are often associated with the intracellular membranes that make up the rough endoplasmic reticulum Ribosomes from bacteria archaea and eukaryotes in the three domain system resemble each other to a remarkable degree evidence of a common origin They differ in their size sequence structure and the ratio of protein to RNA The differences in structure allow some antibiotics to kill bacteria by inhibiting their ribosomes while leaving human ribosomes unaffected In all species more than one ribosome may move along a single mRNA chain at one time as a polysome each reading a specific sequence and producing a corresponding protein molecule The mitochondrial ribosomes of eukaryotic cells functionally resemble many features of those in bacteria reflecting the likely evolutionary origin of mitochondria 6 7 Discovery editRibosomes were first observed in the mid 1950s by Romanian American cell biologist George Emil Palade using an electron microscope as dense particles or granules 8 They were initially called Palade granules due to their granular structure The term ribosome was proposed in 1958 by Howard M Dintzis 9 During the course of the symposium a semantic difficulty became apparent To some of the participants microsomes mean the ribonucleoprotein particles of the microsome fraction contaminated by other protein and lipid material to others the microsomes consist of protein and lipid contaminated by particles The phrase microsomal particles does not seem adequate and ribonucleoprotein particles of the microsome fraction is much too awkward During the meeting the word ribosome was suggested which has a very satisfactory name and a pleasant sound The present confusion would be eliminated if ribosome were adopted to designate ribonucleoprotein particles in sizes ranging from 35 to 100S Albert Claude Microsomal Particles and Protein Synthesis 10 Albert Claude Christian de Duve and George Emil Palade were jointly awarded the Nobel Prize in Physiology or Medicine in 1974 for the discovery of the ribosome 11 The Nobel Prize in Chemistry 2009 was awarded to Venkatraman Ramakrishnan Thomas A Steitz and Ada E Yonath for determining the detailed structure and mechanism of the ribosome 12 Structure edit nbsp Ribosomes assemble polymeric protein molecules the order of which is controlled by the messenger RNA s molecule sequence nbsp Ribosomal RNA composition for prokaryotes and eukaryotesThe ribosome is a complex cellular machine It is largely made up of specialized RNA known as ribosomal RNA rRNA as well as dozens of distinct proteins the exact number varies slightly between species The ribosomal proteins and rRNAs are arranged into two distinct ribosomal pieces of different sizes known generally as the large and small subunits of the ribosome Ribosomes consist of two subunits that fit together and work as one to translate the mRNA into a polypeptide chain during protein synthesis Because they are formed from two subunits of non equal size they are slightly longer on the axis than in diameter Prokaryotic ribosomes edit Prokaryotic ribosomes are around 20 nm 200 A in diameter and are composed of 65 rRNA and 35 ribosomal proteins 13 Eukaryotic ribosomes are between 25 and 30 nm 250 300 A in diameter with an rRNA to protein ratio that is close to 1 14 Crystallographic work 15 has shown that there are no ribosomal proteins close to the reaction site for polypeptide synthesis This suggests that the protein components of ribosomes do not directly participate in peptide bond formation catalysis but rather that these proteins act as a scaffold that may enhance the ability of rRNA to synthesize protein see Ribozyme nbsp Molecular structure of the 30S subunit from Thermus thermophilus 16 Proteins are shown in blue and the single RNA chain in brown The ribosomal subunits of prokaryotes and eukaryotes are quite similar 17 The unit of measurement used to describe the ribosomal subunits and the rRNA fragments is the Svedberg unit a measure of the rate of sedimentation in centrifugation rather than size This accounts for why fragment names do not add up for example bacterial 70S ribosomes are made of 50S and 30S subunits Prokaryotes have 70S ribosomes each consisting of a small 30S and a large 50S subunit E coli for example has a 16S RNA subunit consisting of 1540 nucleotides that is bound to 21 proteins The large subunit is composed of a 5S RNA subunit 120 nucleotides a 23S RNA subunit 2900 nucleotides and 31 proteins 17 Ribosome of E coli a bacterium 18 962 ribosome subunit rRNAs r proteins70S 50S 23S 2904 nt 315S 120 nt 30S 16S 1542 nt 21Affinity label for the tRNA binding sites on the E coli ribosome allowed the identification of A and P site proteins most likely associated with the peptidyltransferase activity 5 labelled proteins are L27 L14 L15 L16 L2 at least L27 is located at the donor site as shown by E Collatz and A P Czernilofsky 19 20 Additional research has demonstrated that the S1 and S21 proteins in association with the 3 end of 16S ribosomal RNA are involved in the initiation of translation 21 Archaeal ribosomes edit Archaeal ribosomes share the same general dimensions of bacteria ones being a 70S ribosome made up from a 50S large subunit a 30S small subunit and containing three rRNA chains However on the sequence level they are much closer to eukaryotic ones than to bacterial ones Every extra ribosomal protein archaea have compared to bacteria has a eukaryotic counterpart while no such relation applies between archaea and bacteria 22 23 24 Eukaryotic ribosomes edit Main article Eukaryotic ribosome Eukaryotes have 80S ribosomes located in their cytosol each consisting of a small 40S and large 60S subunit Their 40S subunit has an 18S RNA 1900 nucleotides and 33 proteins 25 26 The large subunit is composed of a 5S RNA 120 nucleotides 28S RNA 4700 nucleotides a 5 8S RNA 160 nucleotides subunits and 49 proteins 17 25 27 eukaryotic cytosolic ribosomes R norvegicus 18 65 ribosome subunit rRNAs r proteins80S 60S 28S 4718 nt 495 8S 160 nt 5S 120 nt 40S 18S 1874 nt 33During 1977 Czernilofsky published research that used affinity labeling to identify tRNA binding sites on rat liver ribosomes Several proteins including L32 33 L36 L21 L23 L28 29 and L13 were implicated as being at or near the peptidyl transferase center 28 Plastoribosomes and mitoribosomes edit Main articles Mitochondrial ribosome and Chloroplast Chloroplast ribosomes In eukaryotes ribosomes are present in mitochondria sometimes called mitoribosomes and in plastids such as chloroplasts also called plastoribosomes They also consist of large and small subunits bound together with proteins into one 70S particle 17 These ribosomes are similar to those of bacteria and these organelles are thought to have originated as symbiotic bacteria 17 Of the two chloroplastic ribosomes are closer to bacterial ones than mitochondrial ones are Many pieces of ribosomal RNA in the mitochondria are shortened and in the case of 5S rRNA replaced by other structures in animals and fungi 29 In particular Leishmania tarentolae has a minimalized set of mitochondrial rRNA 30 In contrast plant mitoribosomes have both extended rRNA and additional proteins as compared to bacteria in particular many pentatricopetide repeat proteins 31 The cryptomonad and chlorarachniophyte algae may contain a nucleomorph that resembles a vestigial eukaryotic nucleus 32 Eukaryotic 80S ribosomes may be present in the compartment containing the nucleomorph 33 Making use of the differences edit The differences between the bacterial and eukaryotic ribosomes are exploited by pharmaceutical chemists to create antibiotics that can destroy a bacterial infection without harming the cells of the infected person Due to the differences in their structures the bacterial 70S ribosomes are vulnerable to these antibiotics while the eukaryotic 80S ribosomes are not 34 Even though mitochondria possess ribosomes similar to the bacterial ones mitochondria are not affected by these antibiotics because they are surrounded by a double membrane that does not easily admit these antibiotics into the organelle 35 A noteworthy counterexample is the antineoplastic antibiotic chloramphenicol which inhibits bacterial 50S and eukaryotic mitochondrial 50S ribosomes 36 Ribosomes in chloroplasts however are different Antibiotic resistance in chloroplast ribosomal proteins is a trait that has to be introduced as a marker with genetic engineering 37 Common properties edit The various ribosomes share a core structure which is quite similar despite the large differences in size Much of the RNA is highly organized into various tertiary structural motifs for example pseudoknots that exhibit coaxial stacking The extra RNA in the larger ribosomes is in several long continuous insertions 38 such that they form loops out of the core structure without disrupting or changing it 17 All of the catalytic activity of the ribosome is carried out by the RNA the proteins reside on the surface and seem to stabilize the structure 17 High resolution structure edit nbsp Figure 4 Atomic structure of the 50S subunit from Haloarcula marismortui Proteins are shown in blue and the two RNA chains in brown and yellow 39 The small patch of green in the center of the subunit is the active site The general molecular structure of the ribosome has been known since the early 1970s In the early 2000s the structure has been achieved at high resolutions of the order of a few angstroms The first papers giving the structure of the ribosome at atomic resolution were published almost simultaneously in late 2000 The 50S large prokaryotic subunit was determined from the archaeon Haloarcula marismortui 39 and the bacterium Deinococcus radiodurans 40 and the structure of the 30S subunit was determined from Thermus thermophilus 16 These structural studies were awarded the Nobel Prize in Chemistry in 2009 In May 2001 these coordinates were used to reconstruct the entire T thermophilus 70S particle at 5 5 A resolution 41 Two papers were published in November 2005 with structures of the Escherichia coli 70S ribosome The structures of a vacant ribosome were determined at 3 5 A resolution using X ray crystallography 42 Then two weeks later a structure based on cryo electron microscopy was published 43 which depicts the ribosome at 11 15 A resolution in the act of passing a newly synthesized protein strand into the protein conducting channel The first atomic structures of the ribosome complexed with tRNA and mRNA molecules were solved by using X ray crystallography by two groups independently at 2 8 A 44 and at 3 7 A 45 These structures allow one to see the details of interactions of the Thermus thermophilus ribosome with mRNA and with tRNAs bound at classical ribosomal sites Interactions of the ribosome with long mRNAs containing Shine Dalgarno sequences were visualized soon after that at 4 5 5 5 A resolution 46 In 2011 the first complete atomic structure of the eukaryotic 80S ribosome from the yeast Saccharomyces cerevisiae was obtained by crystallography 25 The model reveals the architecture of eukaryote specific elements and their interaction with the universally conserved core At the same time the complete model of a eukaryotic 40S ribosomal structure in Tetrahymena thermophila was published and described the structure of the 40S subunit as well as much about the 40S subunit s interaction with eIF1 during translation initiation 26 Similarly the eukaryotic 60S subunit structure was also determined from Tetrahymena thermophila in complex with eIF6 27 Function editRibosomes are minute particles consisting of RNA and associated proteins that function to synthesize proteins Proteins are needed for many cellular functions such as repairing damage or directing chemical processes Ribosomes can be found floating within the cytoplasm or attached to the endoplasmic reticulum Their main function is to convert genetic code into an amino acid sequence and to build protein polymers from amino acid monomers Ribosomes act as catalysts in two extremely important biological processes called peptidyl transfer and peptidyl hydrolysis 5 47 The PT center is responsible for producing protein bonds during protein elongation 47 In summary ribosomes have two main functions Decoding the message and the formation of peptide bonds These two functions reside in the ribosomal subunits Each subunit is made of one or more rRNAs and many r proteins The small subunit 30S in bacteria and archaea 40S in eukaryotes has the decoding function whereas the large subunit 50S in bacteria and archaea 60S in eukaryotes catalyzes the formation of peptide bonds referred to as the peptidyl transferase activity The bacterial and archaeal small subunit contains the 16S rRNA and 21 r proteins Escherichia coli whereas the eukaryotic small subunit contains the 18S rRNA and 32 r proteins Saccharomyces cerevisiae although the numbers vary between species The bacterial large subunit contains the 5S and 23S rRNAs and 34 r proteins E coli with the eukaryotic large subunit containing the 5S 5 8S and 25S 28S rRNAs and 46 r proteins S cerevisiae again the exact numbers vary between species 48 Translation edit Main article Translation biology Ribosomes are the workplaces of protein biosynthesis the process of translating mRNA into protein The mRNA comprises a series of codons which are decoded by the ribosome so as to make the protein Using the mRNA as a template the ribosome traverses each codon 3 nucleotides of the mRNA pairing it with the appropriate amino acid provided by an aminoacyl tRNA Aminoacyl tRNA contains a complementary anticodon on one end and the appropriate amino acid on the other For fast and accurate recognition of the appropriate tRNA the ribosome utilizes large conformational changes conformational proofreading 49 The small ribosomal subunit typically bound to an aminoacyl tRNA containing the first amino acid methionine binds to an AUG codon on the mRNA and recruits the large ribosomal subunit The ribosome contains three RNA binding sites designated A P and E The A site binds an aminoacyl tRNA or termination release factors 50 51 the P site binds a peptidyl tRNA a tRNA bound to the poly peptide chain and the E site exit binds a free tRNA Protein synthesis begins at a start codon AUG near the 5 end of the mRNA mRNA binds to the P site of the ribosome first The ribosome recognizes the start codon by using the Shine Dalgarno sequence of the mRNA in prokaryotes and Kozak box in eukaryotes Although catalysis of the peptide bond involves the C2 hydroxyl of RNA s P site adenosine in a proton shuttle mechanism other steps in protein synthesis such as translocation are caused by changes in protein conformations Since their catalytic core is made of RNA ribosomes are classified as ribozymes 52 and it is thought that they might be remnants of the RNA world 53 nbsp Figure 5 Translation of mRNA 1 by a ribosome 2 shown as small and large subunits into a polypeptide chain 3 The ribosome begins at the start codon of RNA AUG and ends at the stop codon UAG In Figure 5 both ribosomal subunits small and large assemble at the start codon towards the 5 end of the mRNA The ribosome uses tRNA that matches the current codon triplet on the mRNA to append an amino acid to the polypeptide chain This is done for each triplet on the mRNA while the ribosome moves towards the 3 end of the mRNA Usually in bacterial cells several ribosomes are working parallel on a single mRNA forming what is called a polyribosome or polysome Cotranslational folding edit The ribosome is known to actively participate in the protein folding 54 55 The structures obtained in this way are usually identical to the ones obtained during protein chemical refolding however the pathways leading to the final product may be different 56 57 In some cases the ribosome is crucial in obtaining the functional protein form For example one of the possible mechanisms of folding of the deeply knotted proteins relies on the ribosome pushing the chain through the attached loop 58 Addition of translation independent amino acids edit Presence of a ribosome quality control protein Rqc2 is associated with mRNA independent protein elongation 59 60 This elongation is a result of ribosomal addition via tRNAs brought by Rqc2 of CAT tails ribosomes extend the C terminus of a stalled protein with random translation independent sequences of alanines and threonines 61 62 Ribosome locations editRibosomes are classified as being either free or membrane bound nbsp Figure 6 A ribosome translating a protein that is secreted into the endoplasmic reticulum Free and membrane bound ribosomes differ only in their spatial distribution they are identical in structure Whether the ribosome exists in a free or membrane bound state depends on the presence of an ER targeting signal sequence on the protein being synthesized so an individual ribosome might be membrane bound when it is making one protein but free in the cytosol when it makes another protein Ribosomes are sometimes referred to as organelles but the use of the term organelle is often restricted to describing sub cellular components that include a phospholipid membrane which ribosomes being entirely particulate do not For this reason ribosomes may sometimes be described as non membranous organelles Free ribosomes edit Free ribosomes can move about anywhere in the cytosol but are excluded from the cell nucleus and other organelles Proteins that are formed from free ribosomes are released into the cytosol and used within the cell Since the cytosol contains high concentrations of glutathione and is therefore a reducing environment proteins containing disulfide bonds which are formed from oxidized cysteine residues cannot be produced within it Membrane bound ribosomes edit When a ribosome begins to synthesize proteins that are needed in some organelles the ribosome making this protein can become membrane bound In eukaryotic cells this happens in a region of the endoplasmic reticulum ER called the rough ER The newly produced polypeptide chains are inserted directly into the ER by the ribosome undertaking vectorial synthesis and are then transported to their destinations through the secretory pathway Bound ribosomes usually produce proteins that are used within the plasma membrane or are expelled from the cell via exocytosis 63 Biogenesis editMain article Ribosome biogenesis In bacterial cells ribosomes are synthesized in the cytoplasm through the transcription of multiple ribosome gene operons In eukaryotes the process takes place both in the cell cytoplasm and in the nucleolus which is a region within the cell nucleus The assembly process involves the coordinated function of over 200 proteins in the synthesis and processing of the four rRNAs as well as assembly of those rRNAs with the ribosomal proteins 64 Origin editThe ribosome may have first originated as a protoribosome 65 possibly containing a peptidyl transferase centre PTC in an RNA world appearing as a self replicating complex that only later evolved the ability to synthesize proteins when amino acids began to appear 66 Studies suggest that ancient ribosomes constructed solely of rRNA could have developed the ability to synthesize peptide bonds 67 68 69 70 71 In addition evidence strongly points to ancient ribosomes as self replicating complexes where the rRNA in the ribosomes had informational structural and catalytic purposes because it could have coded for tRNAs and proteins needed for ribosomal self replication 72 Hypothetical cellular organisms with self replicating RNA but without DNA are called ribocytes or ribocells 73 74 As amino acids gradually appeared in the RNA world under prebiotic conditions 75 76 their interactions with catalytic RNA would increase both the range and efficiency of function of catalytic RNA molecules 66 Thus the driving force for the evolution of the ribosome from an ancient self replicating machine into its current form as a translational machine may have been the selective pressure to incorporate proteins into the ribosome s self replicating mechanisms so as to increase its capacity for self replication 72 77 78 Heterogeneous ribosomes editRibosomes are compositionally heterogeneous between species and even within the same cell as evidenced by the existence of cytoplasmic and mitochondria ribosomes within the same eukaryotic cells Certain researchers have suggested that heterogeneity in the composition of ribosomal proteins in mammals is important for gene regulation i e the specialized ribosome hypothesis 79 80 However this hypothesis is controversial and the topic of ongoing research 81 82 Heterogeneity in ribosome composition was first proposed to be involved in translational control of protein synthesis by Vince Mauro and Gerald Edelman 83 They proposed the ribosome filter hypothesis to explain the regulatory functions of ribosomes Evidence has suggested that specialized ribosomes specific to different cell populations may affect how genes are translated 84 Some ribosomal proteins exchange from the assembled complex with cytosolic copies 85 suggesting that the structure of the in vivo ribosome can be modified without synthesizing an entire new ribosome Certain ribosomal proteins are absolutely critical for cellular life while others are not In budding yeast 14 78 ribosomal proteins are non essential for growth while in humans this depends on the cell of study 86 Other forms of heterogeneity include post translational modifications to ribosomal proteins such as acetylation methylation and phosphorylation 87 Arabidopsis 88 89 90 91 Viral internal ribosome entry sites IRESs may mediate translations by compositionally distinct ribosomes For example 40S ribosomal units without eS25 in yeast and mammalian cells are unable to recruit the CrPV IGR IRES 92 Heterogeneity of ribosomal RNA modifications plays a significant role in structural maintenance and or function and most mRNA modifications are found in highly conserved regions 93 94 The most common rRNA modifications are pseudouridylation and 2 O methylation of ribose 95 See also editAminoglycosides Biological machines Posttranslational modification Protein dynamics RNA tertiary structure Translation genetics Wobble base pair Ada Yonath Israeli crystallographer known for her pioneering work on the structure of the ribosome for which she won the Nobel Prize References edit Konikkat S February 2016 Dynamic Remodeling Events Drive the Removal of the ITS2 Spacer Sequence During Assembly of 60S Ribosomal Subunits in S cerevisiae Ph D thesis Carnegie Mellon University Archived from the original on 3 August 2017 Weiler EW Nover L 2008 Allgemeine und Molekulare Botanik in German Stuttgart Georg Thieme Verlag p 532 ISBN 9783131527912 de la Cruz J Karbstein K Woolford JL 2015 Functions of ribosomal proteins in assembly of eukaryotic ribosomes in vivo Annual Review of Biochemistry 84 93 129 doi 10 1146 annurev biochem 060614 033917 PMC 4772166 PMID 25706898 Scitable by nature translation RNA translation a b c Tirumalai MR Rivas M Tran Q Fox GE November 2021 The Peptidyl Transferase Center a Window to the Past Microbiol Mol Biol Rev 85 4 e0010421 doi 10 1128 MMBR 00104 21 PMC 8579967 PMID 34756086 Benne R Sloof P 1987 Evolution of the mitochondrial protein synthetic machinery Bio Systems 21 1 51 68 Bibcode 1987BiSys 21 51B doi 10 1016 0303 2647 87 90006 2 PMID 2446672 Ribosomes Archived from the original on 2009 03 20 Retrieved 2011 04 28 Palade GE January 1955 A small particulate component of the cytoplasm The Journal of Biophysical and Biochemical Cytology 1 1 59 68 doi 10 1083 jcb 1 1 59 PMC 2223592 PMID 14381428 Rheinberger Hans Jorg September 2022 A Brief History of Protein Biosynthesis and Ribosome Research Lindau Nobel Laureate Meetings Retrieved 2023 08 16 Roberts RB ed 1958 Introduction Microsomal Particles and Protein Synthesis New York Pergamon Press Inc The Nobel Prize in Physiology or Medicine 1974 Nobelprize org The Nobel Foundation Archived from the original on 26 January 2013 Retrieved 10 December 2012 2009 Nobel Prize in Chemistry The Nobel Foundation Archived from the original on 28 April 2012 Retrieved 10 December 2012 Kurland CG 1960 Molecular characterization of ribonucleic acid from Escherichia coli ribosomes Journal of Molecular Biology 2 2 83 91 doi 10 1016 s0022 2836 60 80029 0 Wilson DN Doudna Cate JH May 2012 The structure and function of the eukaryotic ribosome Cold Spring Harbor Perspectives in Biology 4 5 a011536 doi 10 1101 cshperspect a011536 PMC 3331703 PMID 22550233 Nissen P Hansen J Ban N Moore PB Steitz TA August 2000 The structural basis of ribosome activity in peptide bond synthesis PDF Science 289 5481 920 30 Bibcode 2000Sci 289 920N doi 10 1126 science 289 5481 920 PMID 10937990 S2CID 8370119 Archived from the original PDF on 2020 11 30 a b Wimberly BT Brodersen DE Clemons WM Morgan Warren RJ Carter AP Vonrhein C Hartsch T Ramakrishnan V September 2000 Structure of the 30S ribosomal subunit Nature 407 6802 327 39 Bibcode 2000Natur 407 327W doi 10 1038 35030006 PMID 11014182 S2CID 4419944 a b c d e f g Alberts B Johnson A Lewis J Raff M Roberts K Walter P 2002 Membrane bound Ribosomes Define the Rough ER Molecular Biology of the Cell 4th ed New York Garland Science p 342 ISBN 978 0 8153 4072 0 a b Garrett R Grisham CM 2009 Biochemistry 4th ed Cengage Learning Services ISBN 978 0 495 11464 2 Collatz E Kuchler E Stoffler G Czernilofsky AP April 1976 The site of reaction on ribosomal protein L27 with an affinity label derivative of tRNA Met f FEBS Letters 63 2 283 6 doi 10 1016 0014 5793 76 80112 3 PMID 770196 Czernilofsky AP Collatz EE Stoffler G Kuechler E January 1974 Proteins at the tRNA binding sites of Escherichia coli ribosomes Proceedings of the National Academy of Sciences of the United States of America 71 1 230 4 Bibcode 1974PNAS 71 230C doi 10 1073 pnas 71 1 230 PMC 387971 PMID 4589893 Czernilofsky AP Kurland CG Stoffler G October 1975 30S ribosomal proteins associated with the 3 terminus of 16S RNA FEBS Letters 58 1 281 4 doi 10 1016 0014 5793 75 80279 1 PMID 1225593 Cullen KE 2009 Archaeal Ribosomes Encyclopedia of Life Science New York Facts On File pp 1 5 doi 10 1002 9780470015902 a0000293 pub3 ISBN 9780470015902 S2CID 243730576 Tirumalai MR Anane Bediakoh D Rajesh R Fox GE November 2021 Net Charges of the Ribosomal Proteins of the S10 and spc Clusters of Halophiles Are Inversely Related to the Degree of Halotolerance Microbiol Spectr 9 3 e0178221 doi 10 1128 spectrum 01782 21 PMC 8672879 PMID 34908470 Wang J Dasgupta I Fox GE 28 April 2009 Many nonuniversal archaeal ribosomal proteins are found in conserved gene clusters Archaea 2 4 241 51 doi 10 1155 2009 971494 PMC 2686390 PMID 19478915 a b c Ben Shem A Garreau de Loubresse N Melnikov S Jenner L Yusupova G Yusupov M December 2011 The structure of the eukaryotic ribosome at 3 0 A resolution Science 334 6062 1524 9 Bibcode 2011Sci 334 1524B doi 10 1126 science 1212642 PMID 22096102 S2CID 9099683 a b Rabl J Leibundgut M Ataide SF Haag A Ban N February 2011 Crystal structure of the eukaryotic 40S ribosomal subunit in complex with initiation factor 1 PDF Science 331 6018 730 6 Bibcode 2011Sci 331 730R doi 10 1126 science 1198308 hdl 20 500 11850 153130 PMID 21205638 S2CID 24771575 a b Klinge S Voigts Hoffmann F Leibundgut M Arpagaus S Ban N November 2011 Crystal structure of the eukaryotic 60S ribosomal subunit in complex with initiation factor 6 Science 334 6058 941 8 Bibcode 2011Sci 334 941K doi 10 1126 science 1211204 PMID 22052974 S2CID 206536444 Fabijanski S Pellegrini M 1977 Identification of proteins at the peptidyl tRNA binding site of rat liver ribosomes Molecular amp General Genetics 184 3 551 6 doi 10 1007 BF00431588 PMID 6950200 S2CID 9751945 Agrawal RK Sharma MR December 2012 Structural aspects of mitochondrial translational apparatus Current Opinion in Structural Biology 22 6 797 803 doi 10 1016 j sbi 2012 08 003 PMC 3513651 PMID 22959417 Sharma MR Booth TM Simpson L Maslov DA Agrawal RK June 2009 Structure of a mitochondrial ribosome with minimal RNA Proceedings of the National Academy of Sciences of the United States of America 106 24 9637 42 Bibcode 2009PNAS 106 9637S doi 10 1073 pnas 0901631106 PMC 2700991 PMID 19497863 Waltz F Nguyen TT Arrive M Bochler A Chicher J Hammann P Kuhn L Quadrado M Mireau H Hashem Y Giege P January 2019 Small is big in Arabidopsis mitochondrial ribosome Nature Plants 5 1 106 117 doi 10 1038 s41477 018 0339 y PMID 30626926 S2CID 58004990 Archibald JM Lane CE 2009 Going going not quite gone nucleomorphs as a case study in nuclear genome reduction The Journal of Heredity 100 5 582 90 doi 10 1093 jhered esp055 PMID 19617523 Specialized Internal Structures of Prokaryotes Boundless Microbiology courses lumenlearning com Retrieved 2021 09 24 Recht MI Douthwaite S Puglisi JD June 1999 Basis for prokaryotic specificity of action of aminoglycoside antibiotics The EMBO Journal 18 11 3133 8 doi 10 1093 emboj 18 11 3133 PMC 1171394 PMID 10357824 O Brien TW May 1971 The general occurrence of 55 S ribosomes in mammalian liver mitochondria The Journal of Biological Chemistry 246 10 3409 17 doi 10 1016 S0021 9258 18 62239 2 PMID 4930061 Chloramphenicol lnduced Bone Marrow Suppression JAMA 213 7 1183 1184 1970 08 17 doi 10 1001 jama 1970 03170330063011 ISSN 0098 7484 PMID 5468266 Newman SM Boynton JE Gillham NW Randolph Anderson BL Johnson AM Harris EH December 1990 Transformation of chloroplast ribosomal RNA genes in Chlamydomonas molecular and genetic characterization of integration events Genetics 126 4 875 88 doi 10 1093 genetics 126 4 875 PMC 1204285 PMID 1981764 Penev PI Fakhretaha Aval S Patel VJ Cannone JJ Gutell RR Petrov AS Williams LD Glass JB August 2020 Supersized ribosomal RNA expansion segments in Asgard archaea Genome Biology and Evolution 12 10 1694 1710 doi 10 1093 gbe evaa170 PMC 7594248 PMID 32785681 a b Ban N Nissen P Hansen J Moore PB Steitz TA August 2000 The complete atomic structure of the large ribosomal subunit at 2 4 A resolution Science 289 5481 905 20 Bibcode 2000Sci 289 905B CiteSeerX 10 1 1 58 2271 doi 10 1126 science 289 5481 905 PMID 10937989 Schluenzen F Tocilj A Zarivach R Harms J Gluehmann M Janell D Bashan A Bartels H Agmon I Franceschi F Yonath A September 2000 Structure of functionally activated small ribosomal subunit at 3 3 angstroms resolution Cell 102 5 615 23 doi 10 1016 S0092 8674 00 00084 2 PMID 11007480 S2CID 1024446 Yusupov MM Yusupova GZ Baucom A Lieberman K Earnest TN Cate JH Noller HF May 2001 Crystal structure of the ribosome at 5 5 A resolution Science 292 5518 883 96 Bibcode 2001Sci 292 883Y doi 10 1126 science 1060089 PMID 11283358 S2CID 39505192 Schuwirth BS Borovinskaya MA Hau CW Zhang W Vila Sanjurjo A Holton JM Cate JH November 2005 Structures of the bacterial ribosome at 3 5 A resolution Science 310 5749 827 34 Bibcode 2005Sci 310 827S doi 10 1126 science 1117230 PMID 16272117 S2CID 37382005 Mitra K Schaffitzel C Shaikh T Tama F Jenni S Brooks CL Ban N Frank J November 2005 Structure of the E coli protein conducting channel bound to a translating ribosome Nature 438 7066 318 24 Bibcode 2005Natur 438 318M doi 10 1038 nature04133 PMC 1351281 PMID 16292303 Selmer M Dunham CM Murphy FV Weixlbaumer A Petry S Kelley AC Weir JR Ramakrishnan V September 2006 Structure of the 70S ribosome complexed with mRNA and tRNA Science 313 5795 1935 42 Bibcode 2006Sci 313 1935S doi 10 1126 science 1131127 PMID 16959973 S2CID 9737925 Korostelev A Trakhanov S Laurberg M Noller HF September 2006 Crystal structure of a 70S ribosome tRNA complex reveals functional interactions and rearrangements Cell 126 6 1065 77 doi 10 1016 j cell 2006 08 032 PMID 16962654 S2CID 13452915 Yusupova G Jenner L Rees B Moras D Yusupov M November 2006 Structural basis for messenger RNA movement on the ribosome Nature 444 7117 391 4 Bibcode 2006Natur 444 391Y doi 10 1038 nature05281 PMID 17051149 S2CID 4419198 a b Specialized Internal Structures of Prokaryotes courses lumenlearning com Boundless Microbiology Retrieved 2018 09 27 Lafontaine D Tollervey D 2001 The function and synthesis of ribosomes Nat Rev Mol Cell Biol 2 7 514 520 doi 10 1038 35080045 hdl 1842 729 PMID 11433365 S2CID 2637106 Savir Y Tlusty T April 2013 The ribosome as an optimal decoder A lesson in molecular recognition Cell 153 2 471 479 Bibcode 2013APS MARY46006T doi 10 1016 j cell 2013 03 032 PMID 23582332 Korkmaz G Sanyal S September 2017 Escherichia coli The Journal of Biological Chemistry 292 36 15134 15142 doi 10 1074 jbc M117 785238 PMC 5592688 PMID 28743745 Konevega AL Soboleva NG Makhno VI Semenkov YP Wintermeyer W Rodnina MV Katunin VI January 2004 Purine bases at position 37 of tRNA stabilize codon anticodon interaction in the ribosomal A site by stacking and Mg2 dependent interactions RNA 10 1 90 101 doi 10 1261 rna 5142404 PMC 1370521 PMID 14681588 Rodnina MV Beringer M Wintermeyer W January 2007 How ribosomes make peptide bonds Trends in Biochemical Sciences 32 1 20 26 doi 10 1016 j tibs 2006 11 007 PMID 17157507 Cech T R August 2000 Structural biology The ribosome is a ribozyme Science 289 5481 878 879 doi 10 1126 science 289 5481 878 PMID 10960319 S2CID 24172338 Banerjee D Sanyal S October 2014 Protein folding activity of the ribosome PFAR a target for antiprion compounds Viruses 6 10 3907 3924 doi 10 3390 v6103907 PMC 4213570 PMID 25341659 Fedorov AN Baldwin TO December 1997 Cotranslational protein folding The Journal of Biological Chemistry 272 52 32715 32718 doi 10 1074 jbc 272 52 32715 PMID 9407040 Baldwin RL June 1975 Intermediates in protein folding reactions and the mechanism of protein folding Annual Review of Biochemistry 44 1 453 475 doi 10 1146 annurev bi 44 070175 002321 PMID 1094916 Das D Das A Samanta D Ghosh J Dasgupta S Bhattacharya A Basu A Sanyal S Das Gupta C August 2008 Role of the ribosome in protein folding PDF Biotechnology Journal 3 8 999 1009 doi 10 1002 biot 200800098 PMID 18702035 Dabrowski Tumanski P Piejko M Niewieczerzal S Stasiak A Sulkowska JI December 2018 Protein knotting by active threading of nascent polypeptide chain exiting from the ribosome exit channel The Journal of Physical Chemistry B 122 49 11616 11625 doi 10 1021 acs jpcb 8b07634 PMID 30198720 S2CID 52176392 Brandman O Stewart Ornstein J Wong D Larson A Williams CC Li GW Zhou S King D Shen PS Weibezahn J Dunn JG Rouskin S Inada T Frost A Weissman JS November 2012 A ribosome bound quality control complex triggers degradation of nascent peptides and signals translation stress Cell 151 5 1042 1054 doi 10 1016 j cell 2012 10 044 PMC 3534965 PMID 23178123 Defenouillere Q Yao Y Mouaikel J Namane A Galopier A Decourty L Doyen A Malabat C Saveanu C Jacquier A Fromont Racine M March 2013 Cdc48 associated complex bound to 60S particles is required for the clearance of aberrant translation products Proceedings of the National Academy of Sciences of the United States of America 110 13 5046 5051 Bibcode 2013PNAS 110 5046D doi 10 1073 pnas 1221724110 PMC 3612664 PMID 23479637 Shen PS Park J Qin Y Li X Parsawar K Larson MH Cox J Cheng Y Lambowitz AM Weissman JS Brandman O Frost A January 2015 Protein synthesis Rqc2p and 60S ribosomal subunits mediate mRNA independent elongation of nascent chains Science 347 6217 75 78 Bibcode 2015Sci 347 75S doi 10 1126 science 1259724 PMC 4451101 PMID 25554787 Keeley J Gutnikoff R 2 January 2015 Ribosome studies turn up new mechanism of protein synthesis Press release Howard Hughes Medical Institute Archived from the original on 12 January 2015 Retrieved 16 January 2015 Alberts B Johnson A Lewis J Raff M Roberts K Walter P 2002 Membrane bound Ribosomes Define the Rough ER Molecular Biology of the Cell 4th ed New York Garland Science ISBN 978 0 8153 4072 0 Kressler Dieter Hurt Ed Babler Jochen 2009 Driving ribosome assembly PDF Biochimica et Biophysica Acta BBA Molecular Cell Research 1803 6 673 683 doi 10 1016 j bbamcr 2009 10 009 PMID 19879902 Dance Amber 28 February 2023 How did life begin One key ingredient is coming into view A Nobel prizewinning scientist s team has taken a big step forward in its quest to reconstruct an early Earth RNA capable of building proteins Nature 615 7950 22 25 doi 10 1038 d41586 023 00574 4 PMID 36854922 a b Noller HF April 2012 Evolution of protein synthesis from an RNA world Cold Spring Harbor Perspectives in Biology 4 4 a003681 doi 10 1101 cshperspect a003681 PMC 3312679 PMID 20610545 Dabbs ER 1986 Mutant studies on the prokaryotic ribosome New York Springer Verlag Noller HF Hoffarth V Zimniak L June 1992 Unusual resistance of peptidyl transferase to protein extraction procedures Science 256 5062 1416 9 Bibcode 1992Sci 256 1416N doi 10 1126 science 1604315 PMID 1604315 Nomura M Mizushima S Ozaki M Traub P Lowry CV 1969 Structure and function of ribosomes and their molecular components Cold Spring Harbor Symposia on Quantitative Biology 34 49 61 doi 10 1101 sqb 1969 034 01 009 PMID 4909519 Krupkin M Matzov D Tang H Metz M Kalaora R Belousoff MJ Zimmerman E Bashan A Yonath A Oct 2011 A vestige of a prebiotic bonding machine is functioning within the contemporary ribosome Phil Trans R Soc B 366 1580 2972 8 doi 10 1098 rstb 2011 0146 PMC 3158926 PMID 21930590 Bose T Fridkin G Davidovich C Krupkin M Dinger N Falkovich AH Peleg Y Agmon I Bashan A Yonat A Feb 2022 Origin of life protoribosome forms peptide bonds and links RNA and protein dominated worlds Nucleic Acids Res 50 4 1815 1828 doi 10 1093 nar gkac052 PMC 8886871 PMID 35137169 a b Root Bernstein M Root Bernstein R February 2015 The ribosome as a missing link in the evolution of life Journal of Theoretical Biology 367 130 158 doi 10 1016 j jtbi 2014 11 025 PMID 25500179 Yarus M 2002 Primordial genetics phenotype of the ribocyte Annual Review of Genetics 36 125 51 doi 10 1146 annurev genet 36 031902 105056 PMID 12429689 Forterre P Krupovic M 2012 The Origin of Virions and Virocells The Escape Hypothesis Revisited Viruses Essential Agents of Life pp 43 60 doi 10 1007 978 94 007 4899 6 3 ISBN 978 94 007 4898 9 Caetano Anolles G Seufferheld MJ 2013 The coevolutionary roots of biochemistry and cellular organization challenge the RNA world paradigm Journal of Molecular Microbiology and Biotechnology 23 1 2 152 77 doi 10 1159 000346551 PMID 23615203 S2CID 41725226 Saladino R Botta G Pino S Costanzo G Di Mauro E August 2012 Genetics first or metabolism first The formamide clue Chemical Society Reviews 41 16 5526 65 doi 10 1039 c2cs35066a hdl 11573 494138 PMID 22684046 Fox GE September 2010 Origin and Evolution of the Ribosome Cold Spring Harb Perspect Biol 2 9 a003483 doi 10 1101 cshperspect a003483 PMC 2926754 PMID 20534711 Fox GE 2016 Origins and early evolution of the ribosome In Hernandez G Jagus R eds Evolution of the Protein Synthesis Machinery and Its Regulation Switzerland Springer Cham pp 31 60 doi 10 1007 978 3 319 39468 8 ISBN 978 3 319 39468 8 S2CID 27493054 Shi Z Fujii K Kovary KM Genuth NR Rost HL Teruel MN Barna M July 2017 Heterogeneous Ribosomes Preferentially Translate Distinct Subpools of mRNAs Genome wide Molecular Cell Elsevier BV 67 1 71 83 e7 doi 10 1016 j molcel 2017 05 021 PMC 5548184 PMID 28625553 Xue S Barna M May 2012 Specialized ribosomes a new frontier in gene regulation and organismal biology Nature Reviews Molecular Cell Biology Springer Science and Business Media LLC 13 6 355 369 doi 10 1038 nrm3359 PMC 4039366 PMID 22617470 Ferretti MB Karbstein K May 2019 Does functional specialization of ribosomes really exist RNA Cold Spring Harbor Laboratory 25 5 521 538 doi 10 1261 rna 069823 118 PMC 6467006 PMID 30733326 Farley Barnes KI Ogawa LM Baserga SJ October 2019 Ribosomopathies Old Concepts New Controversies Trends in Genetics Elsevier BV 35 10 754 767 doi 10 1016 j tig 2019 07 004 PMC 6852887 PMID 31376929 Mauro VP Edelman GM September 2002 The ribosome filter hypothesis Proceedings of the National Academy of Sciences of the United States of America 99 19 12031 6 Bibcode 2002PNAS 9912031M doi 10 1073 pnas 192442499 PMC 129393 PMID 12221294 Xue S Barna M May 2012 Specialized ribosomes a new frontier in gene regulation and organismal biology Nature Reviews Molecular Cell Biology 13 6 355 69 doi 10 1038 nrm3359 PMC 4039366 PMID 22617470 Mathis AD Naylor BC Carson RH Evans E Harwell J Knecht J Hexem E Peelor FF Miller BF Hamilton KL Transtrum MK Bikman BT Price JC February 2017 Mechanisms of In Vivo Ribosome Maintenance Change in Response to Nutrient Signals Molecular amp Cellular Proteomics 16 2 243 254 doi 10 1074 mcp M116 063255 PMC 5294211 PMID 27932527 Steffen KK McCormick MA Pham KM MacKay VL Delaney JR Murakami CJ et al May 2012 Ribosome deficiency protects against ER stress in Saccharomyces cerevisiae Genetics Genetics Society of America 191 1 107 118 doi 10 1534 genetics 111 136549 PMC 3338253 PMID 22377630 Lee SW Berger SJ Martinovic S Pasa Tolic L Anderson GA Shen Y et al April 2002 Direct mass spectrometric analysis of intact proteins of the yeast large ribosomal subunit using capillary LC FTICR Proceedings of the National Academy of Sciences of the United States of America 99 9 5942 5947 Bibcode 2002PNAS 99 5942L doi 10 1073 pnas 082119899 PMC 122881 PMID 11983894 Carroll AJ Heazlewood JL Ito J Millar AH February 2008 Analysis of the Arabidopsis cytosolic ribosome proteome provides detailed insights into its components and their post translational modification Molecular amp Cellular Proteomics 7 2 347 369 doi 10 1074 mcp m700052 mcp200 PMID 17934214 Odintsova TI Muller EC Ivanov AV Egorov TA Bienert R Vladimirov SN et al April 2003 Characterization and analysis of posttranslational modifications of the human large cytoplasmic ribosomal subunit proteins by mass spectrometry and Edman sequencing Journal of Protein Chemistry 22 3 249 258 doi 10 1023 a 1025068419698 PMID 12962325 S2CID 10710245 Yu Y Ji H Doudna JA Leary JA June 2005 Mass spectrometric analysis of the human 40S ribosomal subunit native and HCV IRES bound complexes Protein Science 14 6 1438 1446 doi 10 1110 ps 041293005 PMC 2253395 PMID 15883184 Zeidan Q Wang Z De Maio A Hart GW June 2010 O GlcNAc cycling enzymes associate with the translational machinery and modify core ribosomal proteins Molecular Biology of the Cell 21 12 1922 1936 doi 10 1091 mbc e09 11 0941 PMC 2883937 PMID 20410138 Landry DM Hertz MI Thompson SR December 2009 RPS25 is essential for translation initiation by the Dicistroviridae and hepatitis C viral IRESs Genes amp Development 23 23 2753 2764 doi 10 1101 gad 1832209 PMC 2788332 PMID 19952110 Decatur WA Fournier MJ July 2002 rRNA modifications and ribosome function Trends in Biochemical Sciences 27 7 344 51 doi 10 1016 s0968 0004 02 02109 6 PMID 12114023 Natchiar SK Myasnikov AG Kratzat H Hazemann I Klaholz BP November 2017 Visualization of chemical modifications in the human 80S ribosome structure Nature 551 7681 472 477 Bibcode 2017Natur 551 472N doi 10 1038 nature24482 PMID 29143818 S2CID 4465175 Guo H August 2018 Specialized ribosomes and the control of translation Biochemical Society Transactions 46 4 855 869 doi 10 1042 BST20160426 PMID 29986937 S2CID 51609077 External links edit nbsp Wikimedia Commons has media related to Ribosomes Lab computer simulates ribosome in motion Role of the Ribosome Gwen V Childs copied here Ribosome in Proteopedia The free collaborative 3D encyclopedia of proteins amp other molecules Ribosomal proteins families in ExPASy Archived 2011 04 30 at the Wayback Machine Molecule of the Month Archived 2009 10 27 at the Wayback Machine c RCSB Protein Data Bank Ribosome Archived 2010 11 14 at the Wayback Machine Elongation Factors Archived 2011 03 16 at the Wayback Machine Palade 3D electron microscopy structures of ribosomes at the EM Data Bank EMDB nbsp This article incorporates public domain material from Science Primer NCBI Archived from the original on 2009 12 08 Retrieved from https en wikipedia org w index php title Ribosome amp oldid 1207126709, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.