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Translation (biology)

January 09, 2023

In molecular biology and genetics, translation is the process in which ribosomes in the cytoplasm or endoplasmic reticulum synthesize proteins after the process of transcription of DNA to RNA in the cell's nucleus. The entire process is called gene expression.

Overview of the translation of eukaryotic messenger RNA
Diagram showing the translation of mRNA and the synthesis of proteins by a ribosome
Initiation and elongation stages of translation as seen through zooming in on the nitrogenous bases in RNA, the ribosome, the tRNA, and amino acids, with short explanations.
The three phases of translation initiation polymerase binds to the DNA strand and moves along until the small ribosomal subunit binds to the DNA. Elongation is initiated when the large subunit attaches and termination end the process of elongation.

In translation, messenger RNA (mRNA) is decoded in a ribosome, outside the nucleus, to produce a specific amino acid chain, or polypeptide. The polypeptide later folds into an active protein and performs its functions in the cell. The ribosome facilitates decoding by inducing the binding of complementary tRNA anticodon sequences to mRNA codons. The tRNAs carry specific amino acids that are chained together into a polypeptide as the mRNA passes through and is "read" by the ribosome.

Translation proceeds in three phases:

  1. Initiation: The ribosome assembles around the target mRNA. The first tRNA is attached at the start codon.
  2. Elongation: The last tRNA validated by the small ribosomal subunit (accommodation) transfers the amino acid it carries to the large ribosomal subunit which binds it to the one of the precedingly admitted tRNA (transpeptidation). The ribosome then moves to the next mRNA codon to continue the process (translocation), creating an amino acid chain.
  3. Termination: When a stop codon is reached, the ribosome releases the polypeptide. The ribosomal complex remains intact and moves on to the next mRNA to be translated.

In prokaryotes (bacteria and archaea), translation occurs in the cytosol, where the large and small subunits of the ribosome bind to the mRNA. In eukaryotes, translation occurs in the cytoplasm or across the membrane of the endoplasmic reticulum in a process called co-translational translocation. In co-translational translocation, the entire ribosome/mRNA complex binds to the outer membrane of the rough endoplasmic reticulum (ER) and the new protein is synthesized and released into the ER; the newly created polypeptide can be stored inside the ER for future vesicle transport and secretion outside the cell, or immediately secreted.

Many types of transcribed RNA, such as transfer RNA, ribosomal RNA, and small nuclear RNA, do not undergo translation into proteins.

A number of antibiotics act by inhibiting translation. These include anisomycin, cycloheximide, chloramphenicol, tetracycline, streptomycin, erythromycin, and puromycin. Prokaryotic ribosomes have a different structure from that of eukaryotic ribosomes, and thus antibiotics can specifically target bacterial infections without any harm to a eukaryotic host's cells.

Basic mechanisms

Further information: Bacterial translation, Archaeal translation, and Eukaryotic translation
 
A ribosome translating a protein that is secreted into the endoplasmic reticulum. tRNAs are colored dark blue.
 
Tertiary structure of tRNA. CCA tail in yellow, Acceptor stem in purple, Variable loop in orange, D arm in red, Anticodon arm in blue with Anticodon in black, T arm in green.

The basic process of protein production is addition of one amino acid at a time to the end of a protein. This operation is performed by a ribosome.[1] A ribosome is made up of two subunits, a small subunit and a large subunit. These subunits come together before translation of mRNA into a protein to provide a location for translation to be carried out and a polypeptide to be produced.[2] The choice of amino acid type to add is determined by an mRNA molecule. Each amino acid added is matched to a three nucleotide subsequence of the mRNA. For each such triplet possible, the corresponding amino acid is accepted. The successive amino acids added to the chain are matched to successive nucleotide triplets in the mRNA. In this way the sequence of nucleotides in the template mRNA chain determines the sequence of amino acids in the generated amino acid chain.[3] Addition of an amino acid occurs at the C-terminus of the peptide and thus translation is said to be amine-to-carboxyl directed.[4]

The mRNA carries genetic information encoded as a ribonucleotide sequence from the chromosomes to the ribosomes. The ribonucleotides are "read" by translational machinery in a sequence of nucleotide triplets called codons. Each of those triplets codes for a specific amino acid.

The ribosome molecules translate this code to a specific sequence of amino acids. The ribosome is a multisubunit structure containing rRNA and proteins. It is the "factory" where amino acids are assembled into proteins. tRNAs are small noncoding RNA chains (74–93 nucleotides) that transport amino acids to the ribosome. The repertoire of tRNA genes varies widely between species, with some Bacteria having between 20 and 30 genes while complex eukaryotes could have thousands[5]. tRNAs have a site for amino acid attachment, and a site called an anticodon. The anticodon is an RNA triplet complementary to the mRNA triplet that codes for their cargo amino acid.

Aminoacyl tRNA synthetases (enzymes) catalyze the bonding between specific tRNAs and the amino acids that their anticodon sequences call for. The product of this reaction is an aminoacyl-tRNA. In bacteria, this aminoacyl-tRNA is carried to the ribosome by EF-Tu, where mRNA codons are matched through complementary base pairing to specific tRNA anticodons. Aminoacyl-tRNA synthetases that mispair tRNAs with the wrong amino acids can produce mischarged aminoacyl-tRNAs, which can result in inappropriate amino acids at the respective position in protein. This "mistranslation"[6] of the genetic code naturally occurs at low levels in most organisms, but certain cellular environments cause an increase in permissive mRNA decoding, sometimes to the benefit of the cell.

The ribosome has two binding sites for tRNA. They are the aminoacyl site (abbreviated A), the peptidyl site/ exit site (abbreviated P/E). With respect to the mRNA, the three sites are oriented 5’ to 3’ E-P-A, because ribosomes move toward the 3' end of mRNA. The A-site binds the incoming tRNA with the complementary codon on the mRNA. The P/E-site holds the tRNA with the growing polypeptide chain. When an aminoacyl-tRNA initially binds to its corresponding codon on the mRNA, it is in the A site. Then, a peptide bond forms between the amino acid of the tRNA in the A site and the amino acid of the charged tRNA in the P/E site. The growing polypeptide chain is transferred to the tRNA in the A site. Translocation occurs, moving the tRNA in the P/E site, now without an amino acid; the tRNA that was in the A site, now charged with the polypeptide chain, is moved to the P/E site and the tRNA leaves and another aminoacyl-tRNA enters the A site to repeat the process.[7]

After the new amino acid is added to the chain, and after the tRNA is released out of the ribosome and into the cytosol, the energy provided by the hydrolysis of a GTP bound to the translocase EF-G (in bacteria) and a/eEF-2 (in eukaryotes and archaea) moves the ribosome down one codon towards the 3' end. The energy required for translation of proteins is significant. For a protein containing n amino acids, the number of high-energy phosphate bonds required to translate it is 4n-1.[8] The rate of translation varies; it is significantly higher in prokaryotic cells (up to 17–21 amino acid residues per second) than in eukaryotic cells (up to 6–9 amino acid residues per second).[9]

Even though the ribosomes are usually considered accurate and processive machines, the translation process is subject to errors that can lead either to the synthesis of erroneous proteins or to the premature abandonment of translation, either because a tRNA couples to a wrong codon or because a tRNA is coupled to the wrong amino acid. [10] The rate of error in synthesizing proteins has been estimated to be between 1 in 105 and 1 in 103 misincorporated amino acids, depending on the experimental conditions.[11] The rate of premature translation abandonment, instead, has been estimated to be of the order of magnitude of 10−4 events per translated codon.[12] The correct amino acid is covalently bonded to the correct transfer RNA (tRNA) by amino acyl transferases. The amino acid is joined by its carboxyl group to the 3' OH of the tRNA by an ester bond. When the tRNA has an amino acid linked to it, the tRNA is termed "charged". Initiation involves the small subunit of the ribosome binding to the 5' end of mRNA with the help of initiation factors (IF). In bacteria and a minority of archaea, initiation of protein synthesis involves the recognition of a purine-rich initiation sequence on the mRNA called the Shine-Dalgarno sequence. The Shine-Dalgarno sequence binds to a complementary pyrimidine-rich sequence on the 3' end of the 16S rRNA part of the 30S ribosomal subunit. The binding of these complementary sequences ensures that the 30S ribosomal subunit is bound to the mRNA and is aligned such that the initiation codon is placed in the 30S portion of the P-site. Once the mRNA and 30S subunit are properly bound, an initiation factor brings the initiator tRNA-amino acid complex, f-Met-tRNA, to the 30S P site. The initiation phase is completed once a 50S subunit joins the 30 subunit, forming an active 70S ribosome.[13] Termination of the polypeptide occurs when the A site of the ribosome is occupied by a stop codon (UAA, UAG, or UGA) on the mRNA, creating the primary structure of a protein. tRNA usually cannot recognize or bind to stop codons. Instead, the stop codon induces the binding of a release factor protein[14] (RF1 & RF2) that prompts the disassembly of the entire ribosome/mRNA complex by the hydrolysis of the polypeptide chain from the peptidyl transferase center [1] of the ribosome.[15] Drugs or special sequence motifs on the mRNA can change the ribosomal structure so that near-cognate tRNAs are bound to the stop codon instead of the release factors. In such cases of 'translational readthrough', translation continues until the ribosome encounters the next stop codon.[16]

The process of translation is highly regulated in both eukaryotic and prokaryotic organisms. Regulation of translation can impact the global rate of protein synthesis which is closely coupled to the metabolic and proliferative state of a cell. In addition, recent work has revealed that genetic differences and their subsequent expression as mRNAs can also impact translation rate in an RNA-specific manner.[17]

Clinical significance

Translational control is critical for the development and survival of cancer. Cancer cells must frequently regulate the translation phase of gene expression, though it is not fully understood why translation is targeted over steps like transcription. While cancer cells often have genetically altered translation factors, it is much more common for cancer cells to modify the levels of existing translation factors.[18] Several major oncogenic signaling pathways, including the RAS–MAPK, PI3K/AKT/mTOR, MYC, and WNT–β-catenin pathways, ultimately reprogram the genome via translation.[19] Cancer cells also control translation to adapt to cellular stress. During stress, the cell translates mRNAs that can mitigate the stress and promote survival. An example of this is the expression of AMPK in various cancers; its activation triggers a cascade that can ultimately allow the cancer to escape apoptosis (programmed cell death) triggered by nutrition deprivation. Future cancer therapies may involve disrupting the translation machinery of the cell to counter the downstream effects of cancer.[18]

Mathematical modeling of translation

 
Figure M0. Basic and the simplest model M0 of protein synthesis. Here, *M – amount of mRNA with translation initiation site not occupied by assembling ribosome, *F – amount of mRNA with translation initiation site occupied by assembling ribosome, *R – amount of ribosomes sitting on mRNA synthesizing proteins, *P – amount of synthesized proteins.[20]
 
Figure M1'. The extended model of protein synthesis M1 with explicit presentation of 40S, 60S and initiation factors (IF) binding.[20]

The transcription-translation process description, mentioning only the most basic ”elementary” processes, consists of:

  1. production of mRNA molecules (including splicing),
  2. initiation of these molecules with help of initiation factors (e.g., the initiation can include the circularization step though it is not universally required),
  3. initiation of translation, recruiting the small ribosomal subunit,
  4. assembly of full ribosomes,
  5. elongation, (i.e. movement of ribosomes along mRNA with production of protein),
  6. termination of translation,
  7. degradation of mRNA molecules,
  8. degradation of proteins.

The process of amino acid building to create protein in translation is a subject of various physic models for a long time starting from the first detailed kinetic models such as[21] or others taking into account stochastic aspects of translation and using computer simulations. Many chemical kinetics-based models of protein synthesis have been developed and analyzed in the last four decades.[22][23] Beyond chemical kinetics, various modeling formalisms such as Totally Asymmetric Simple Exclusion Process (TASEP),[23]Probabilistic Boolean Networks (PBN), Petri Nets and max-plus algebra have been applied to model the detailed kinetics of protein synthesis or some of its stages. A basic model of protein synthesis that takes into account all eight 'elementary' processes has been developed,[20] following the paradigm that "useful models are simple and extendable".[24] The simplest model M0 is represented by the reaction kinetic mechanism (Figure M0). It was generalised to include 40S, 60S and initiation factors (IF) binding (Figure M1'). It was extended further to include effect of microRNA on protein synthesis.[25] Most of models in this hierarchy can be solved analytically. These solutions were used to extract 'kinetic signatures' of different specific mechanisms of synthesis regulation.

Genetic code

Main article: Genetic code

It is also possible to translate either by hand (for short sequences) or by computer (after first programming one appropriately, see section below); this allows biologists and chemists to draw out the chemical structure of the encoded protein on paper.

First, convert each template DNA base to its RNA complement (note that the complement of A is now U), as shown below. Note that the template strand of the DNA is the one the RNA is polymerized against; the other DNA strand would be the same as the RNA, but with thymine instead of uracil. 

DNA -> RNA A -> U T -> A C -> G G -> C A=T-> A=U

Then split the RNA into triplets (groups of three bases). Note that there are 3 translation "windows", or reading frames, depending on where you start reading the code. Finally, use the table at Genetic code to translate the above into a structural formula as used in chemistry.

This will give you the primary structure of the protein. However, proteins tend to fold, depending in part on hydrophilic and hydrophobic segments along the chain. Secondary structure can often still be guessed at, but the proper tertiary structure is often very hard to determine.

Whereas other aspects such as the 3D structure, called tertiary structure, of protein can only be predicted using sophisticated algorithms, the amino acid sequence, called primary structure, can be determined solely from the nucleic acid sequence with the aid of a translation table.

This approach may not give the correct amino acid composition of the protein, in particular if unconventional amino acids such as selenocysteine are incorporated into the protein, which is coded for by a conventional stop codon in combination with a downstream hairpin (SElenoCysteine Insertion Sequence, or SECIS).

There are many computer programs capable of translating a DNA/RNA sequence into a protein sequence. Normally this is performed using the Standard Genetic Code, however, few programs can handle all the "special" cases, such as the use of the alternative initiation codons which are biologically significant. For instance, the rare alternative start codon CTG codes for Methionine when used as a start codon, and for Leucine in all other positions.

Example: Condensed translation table for the Standard Genetic Code (from the NCBI Taxonomy webpage).[26]

 AAs = FFLLSSSSYY**CC*WLLLLPPPPHHQQRRRRIIIMTTTTNNKKSSRRVVVVAAAADDEEGGGG Starts = ---M---------------M---------------M---------------------------- Base1 = TTTTTTTTTTTTTTTTCCCCCCCCCCCCCCCCAAAAAAAAAAAAAAAAGGGGGGGGGGGGGGGG Base2 = TTTTCCCCAAAAGGGGTTTTCCCCAAAAGGGGTTTTCCCCAAAAGGGGTTTTCCCCAAAAGGGG Base3 = TCAGTCAGTCAGTCAGTCAGTCAGTCAGTCAGTCAGTCAGTCAGTCAGTCAGTCAGTCAGTCAG

The "Starts" row indicate three start codons, UUG, CUG, and the very common AUG. It also indicates the first amino acid residue when interpreted as a start: in this case it is all methionine.

Translation tables

Main articles: List of genetic codes and Genetic code § List of alternative codons

Even when working with ordinary eukaryotic sequences such as the Yeast genome, it is often desired to be able to use alternative translation tables—namely for translation of the mitochondrial genes. Currently the following translation tables are defined by the NCBI Taxonomy Group for the translation of the sequences in GenBank:[26]

  1. The standard code
  2. The vertebrate mitochondrial code
  3. The yeast mitochondrial code
  4. The mold, protozoan, and coelenterate mitochondrial code and the mycoplasma/spiroplasma code
  5. The invertebrate mitochondrial code
  6. The ciliate, dasycladacean and hexamita nuclear code
  7. The kinetoplast code
  9. The echinoderm and flatworm mitochondrial code
  10. The euplotid nuclear code
  11. The bacterial, archaeal and plant plastid code
  12. The alternative yeast nuclear code
  13. The ascidian mitochondrial code
  14. The alternative flatworm mitochondrial code
  15. The Blepharisma nuclear code
  16. The chlorophycean mitochondrial code
  18. The trematode mitochondrial code
  19. The Scenedesmus obliquus mitochondrial code
  20. The Thraustochytrium mitochondrial code
  21. The Pterobranchia mitochondrial code
  22. The candidate division SR1 and gracilibacteria code
  23. The Pachysolen tannophilus nuclear code
  24. The karyorelict nuclear code
  25. The Condylostoma nuclear code
  26. The Mesodinium nuclear code
  27. The peritrich nuclear code
  28. The Blastocrithidia nuclear code
  30. The Cephalodiscidae mitochondrial code

See also

References

  1. ^ a b 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.
  2. ^ Brooker RJ, Widmaier EP, Graham LE, Stiling PD (2014). Biology (Third international student ed.). New York, NY: McGraw Hill Education. p. 249. ISBN 978-981-4581-85-1.
  3. ^ Neill C (1996). Biology (Fourth ed.). The Benjamin/Cummings Publishing Company. pp. 309–310. ISBN 0-8053-1940-9.
  4. ^ Stryer L (2002). Biochemistry (Fifth ed.). W. H. Freeman and Company. p. 826. ISBN 0-7167-4684-0.
  5. ^ Santos, Fenícia Brito; Del-Bem, Luiz-Eduardo (2023). "The Evolution of tRNA Copy Number and Repertoire in Cellular Life". Genes. 14 (1): 27. doi:10.3390/genes14010027. ISSN 2073-4425.
  6. ^ Moghal A, Mohler K, Ibba M (November 2014). "Mistranslation of the genetic code". FEBS Letters. 588 (23): 4305–10. doi:10.1016/j.febslet.2014.08.035. PMC 4254111. PMID 25220850.
  7. ^ Griffiths A (2008). "9". Introduction to Genetic Analysis (9th ed.). New York: W.H. Freeman and Company. pp. 335–339. ISBN 978-0-7167-6887-6.
  8. ^ "Computational Analysis of Genomic Sequences utilizing Machine Learning". scholar.googleusercontent.com. Retrieved 2022-01-12.
  9. ^ Ross JF, Orlowski M (February 1982). "Growth-rate-dependent adjustment of ribosome function in chemostat-grown cells of the fungus Mucor racemosus". Journal of Bacteriology. 149 (2): 650–3. doi:10.1128/JB.149.2.650-653.1982. PMC 216554. PMID 6799491.
  10. ^ Ou X, Cao J, Cheng A, Peppelenbosch MP, Pan Q (March 2019). "Errors in translational decoding: tRNA wobbling or misincorporation?". PLOS Genetics. 15 (3): 2979–2986. doi:10.1371/journal.pgen.1008017. PMC 3158919. PMID 21930591.
  11. ^ Wohlgemuth I, Pohl C, Mittelstaet J, Konevega AL, Rodnina MV (October 2011). "Evolutionary optimization of speed and accuracy of decoding on the ribosome". Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences. 366 (1580): 2979–86. doi:10.1098/rstb.2011.0138. PMC 6438450. PMID 30921315.
  12. ^ Sin C, Chiarugi D, Valleriani A (April 2016). "Quantitative assessment of ribosome drop-off in E. coli". Nucleic Acids Research. 44 (6): 2528–37. doi:10.1093/nar/gkw137. PMC 4824120. PMID 26935582.
  13. ^ Nakamoto T (February 2011). "Mechanisms of the initiation of protein synthesis: in reading frame binding of ribosomes to mRNA". Molecular Biology Reports. 38 (2): 847–55. doi:10.1007/s11033-010-0176-1. PMID 20467902. S2CID 22038744.
  14. ^ Baggett NE, Zhang Y, Gross CA (March 2017). Ibba M (ed.). "Global analysis of translation termination in E. coli". PLOS Genetics. 13 (3): e1006676. doi:10.1371/journal.pgen.1006676. PMC 5373646. PMID 28301469.
  15. ^ Mora L, Zavialov A, Ehrenberg M, Buckingham RH (December 2003). "Stop codon recognition and interactions with peptide release factor RF3 of truncated and chimeric RF1 and RF2 from Escherichia coli". Molecular Microbiology. 50 (5): 1467–76. doi:10.1046/j.1365-2958.2003.03799.x. PMID 14651631.
  16. ^ Schueren F, Thoms S (August 2016). "Functional Translational Readthrough: A Systems Biology Perspective". PLOS Genetics. 12 (8): e1006196. doi:10.1371/JOURNAL.PGEN.1006196. PMC 4973966. PMID 27490485.
  17. ^ Cenik C, Cenik ES, Byeon GW, Grubert F, Candille SI, Spacek D, et al. (November 2015). "Integrative analysis of RNA, translation, and protein levels reveals distinct regulatory variation across humans". Genome Research. 25 (11): 1610–21. doi:10.1101/gr.193342.115. PMC 4617958. PMID 26297486.
  18. ^ a b Xu Y, Ruggero D (March 2020). "The Role of Translation Control in Tumorigenesis and Its Therapeutic Implications". Annual Review of Cancer Biology. 4 (1): 437–457. doi:10.1146/annurev-cancerbio-030419-033420.
  19. ^ Truitt ML, Ruggero D (April 2016). "New frontiers in translational control of the cancer genome". Nature Reviews. Cancer. 16 (5): 288–304. doi:10.1038/nrc.2016.27. PMC 5491099. PMID 27112207.
  20. ^ a b c Gorban AN, Harel-Bellan A, Morozova N, Zinovyev A (July 2019). "Basic, simple and extendable kinetic model of protein synthesis". Mathematical Biosciences and Engineering. 16 (6): 6602–6622. doi:10.3934/mbe.2019329. PMID 31698578.
  21. ^ MacDonald CT, Gibbs JH, Pipkin AC (1968). "Kinetics of biopolymerization on nucleic acid templates". Biopolymers. 6 (1): 1–5. doi:10.1002/bip.1968.360060102. PMID 5641411. S2CID 27559249.
  22. ^ Heinrich R, Rapoport TA (September 1980). "Mathematical modelling of translation of mRNA in eucaryotes; steady state, time-dependent processes and application to reticulocytes". Journal of Theoretical Biology. 86 (2): 279–313. Bibcode:1980JThBi..86..279H. doi:10.1016/0022-5193(80)90008-9. PMID 7442295.
  23. ^ a b Skjøndal-Bar N, Morris DR (January 2007). "Dynamic model of the process of protein synthesis in eukaryotic cells". Bulletin of Mathematical Biology. 69 (1): 361–93. doi:10.1007/s11538-006-9128-2. PMID 17031456. S2CID 83701439.
  24. ^ Coyte KZ, Tabuteau H, Gaffney EA, Foster KR, Durham WM (April 2017). "Reply to Baveye and Darnault: Useful models are simple and extendable". Proceedings of the National Academy of Sciences of the United States of America. 114 (14): E2804–E2805. Bibcode:2017PNAS..114E2804C. doi:10.1073/pnas.1702303114. PMC 5389313. PMID 28341710.
  25. ^ Morozova N, Zinovyev A, Nonne N, Pritchard LL, Gorban AN, Harel-Bellan A (September 2012). "Kinetic signatures of microRNA modes of action". RNA. 18 (9): 1635–55. doi:10.1261/rna.032284.112. PMC 3425779. PMID 22850425.
  26. ^ a b Elzanowski, Andrzej; Ostell, Jim (January 2019). "The Genetic Codes". National Center for Biotechnology Information (NCBI). Retrieved 31 May 2022.{{cite web}}: CS1 maint: url-status (link)

Further reading

  • Champe PC, Harvey RA, Ferrier DR (2004). Lippincott's Illustrated Reviews: Biochemistry (3rd ed.). Hagerstwon, MD: Lippincott Williams & Wilkins. ISBN 0-7817-2265-9.
  • Cox M, Nelson DR, Lehninger AL (2005). Lehninger principles of biochemistry (4th ed.). San Francisco...: W.H. Freeman. ISBN 0-7167-4339-6.
  • Malys N, McCarthy JE (March 2011). "Translation initiation: variations in the mechanism can be anticipated". Cellular and Molecular Life Sciences. 68 (6): 991–1003. doi:10.1007/s00018-010-0588-z. PMID 21076851. S2CID 31720000.

External links

 
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  • Translate tool (from DNA or RNA sequence)

January 09, 2023
translation, biology, molecular, biology, genetics, translation, process, which, ribosomes, cytoplasm, endoplasmic, reticulum, synthesize, proteins, after, process, transcription, cell, nucleus, entire, process, called, gene, expression, overview, translation,. In molecular biology and genetics translation is the process in which ribosomes in the cytoplasm or endoplasmic reticulum synthesize proteins after the process of transcription of DNA to RNA in the cell s nucleus The entire process is called gene expression Overview of the translation of eukaryotic messenger RNA Diagram showing the translation of mRNA and the synthesis of proteins by a ribosome Initiation and elongation stages of translation as seen through zooming in on the nitrogenous bases in RNA the ribosome the tRNA and amino acids with short explanations The three phases of translation initiation polymerase binds to the DNA strand and moves along until the small ribosomal subunit binds to the DNA Elongation is initiated when the large subunit attaches and termination end the process of elongation In translation messenger RNA mRNA is decoded in a ribosome outside the nucleus to produce a specific amino acid chain or polypeptide The polypeptide later folds into an active protein and performs its functions in the cell The ribosome facilitates decoding by inducing the binding of complementary tRNA anticodon sequences to mRNA codons The tRNAs carry specific amino acids that are chained together into a polypeptide as the mRNA passes through and is read by the ribosome Translation proceeds in three phases Initiation The ribosome assembles around the target mRNA The first tRNA is attached at the start codon Elongation The last tRNA validated by the small ribosomal subunit accommodation transfers the amino acid it carries to the large ribosomal subunit which binds it to the one of the precedingly admitted tRNA transpeptidation The ribosome then moves to the next mRNA codon to continue the process translocation creating an amino acid chain Termination When a stop codon is reached the ribosome releases the polypeptide The ribosomal complex remains intact and moves on to the next mRNA to be translated In prokaryotes bacteria and archaea translation occurs in the cytosol where the large and small subunits of the ribosome bind to the mRNA In eukaryotes translation occurs in the cytoplasm or across the membrane of the endoplasmic reticulum in a process called co translational translocation In co translational translocation the entire ribosome mRNA complex binds to the outer membrane of the rough endoplasmic reticulum ER and the new protein is synthesized and released into the ER the newly created polypeptide can be stored inside the ER for future vesicle transport and secretion outside the cell or immediately secreted Many types of transcribed RNA such as transfer RNA ribosomal RNA and small nuclear RNA do not undergo translation into proteins A number of antibiotics act by inhibiting translation These include anisomycin cycloheximide chloramphenicol tetracycline streptomycin erythromycin and puromycin Prokaryotic ribosomes have a different structure from that of eukaryotic ribosomes and thus antibiotics can specifically target bacterial infections without any harm to a eukaryotic host s cells Contents 1 Basic mechanisms 2 Clinical significance 3 Mathematical modeling of translation 4 Genetic code 4 1 Translation tables 5 See also 6 References 7 Further reading 8 External linksBasic mechanisms EditFurther information Bacterial translation Archaeal translation and Eukaryotic translation A ribosome translating a protein that is secreted into the endoplasmic reticulum tRNAs are colored dark blue Tertiary structure of tRNA CCA tail in yellow Acceptor stem in purple Variable loop in orange D arm in red Anticodon arm in blue with Anticodon in black T arm in green The basic process of protein production is addition of one amino acid at a time to the end of a protein This operation is performed by a ribosome 1 A ribosome is made up of two subunits a small subunit and a large subunit These subunits come together before translation of mRNA into a protein to provide a location for translation to be carried out and a polypeptide to be produced 2 The choice of amino acid type to add is determined by an mRNA molecule Each amino acid added is matched to a three nucleotide subsequence of the mRNA For each such triplet possible the corresponding amino acid is accepted The successive amino acids added to the chain are matched to successive nucleotide triplets in the mRNA In this way the sequence of nucleotides in the template mRNA chain determines the sequence of amino acids in the generated amino acid chain 3 Addition of an amino acid occurs at the C terminus of the peptide and thus translation is said to be amine to carboxyl directed 4 The mRNA carries genetic information encoded as a ribonucleotide sequence from the chromosomes to the ribosomes The ribonucleotides are read by translational machinery in a sequence of nucleotide triplets called codons Each of those triplets codes for a specific amino acid The ribosome molecules translate this code to a specific sequence of amino acids The ribosome is a multisubunit structure containing rRNA and proteins It is the factory where amino acids are assembled into proteins tRNAs are small noncoding RNA chains 74 93 nucleotides that transport amino acids to the ribosome The repertoire of tRNA genes varies widely between species with some Bacteria having between 20 and 30 genes while complex eukaryotes could have thousands 5 tRNAs have a site for amino acid attachment and a site called an anticodon The anticodon is an RNA triplet complementary to the mRNA triplet that codes for their cargo amino acid Aminoacyl tRNA synthetases enzymes catalyze the bonding between specific tRNAs and the amino acids that their anticodon sequences call for The product of this reaction is an aminoacyl tRNA In bacteria this aminoacyl tRNA is carried to the ribosome by EF Tu where mRNA codons are matched through complementary base pairing to specific tRNA anticodons Aminoacyl tRNA synthetases that mispair tRNAs with the wrong amino acids can produce mischarged aminoacyl tRNAs which can result in inappropriate amino acids at the respective position in protein This mistranslation 6 of the genetic code naturally occurs at low levels in most organisms but certain cellular environments cause an increase in permissive mRNA decoding sometimes to the benefit of the cell The ribosome has two binding sites for tRNA They are the aminoacyl site abbreviated A the peptidyl site exit site abbreviated P E With respect to the mRNA the three sites are oriented 5 to 3 E P A because ribosomes move toward the 3 end of mRNA The A site binds the incoming tRNA with the complementary codon on the mRNA The P E site holds the tRNA with the growing polypeptide chain When an aminoacyl tRNA initially binds to its corresponding codon on the mRNA it is in the A site Then a peptide bond forms between the amino acid of the tRNA in the A site and the amino acid of the charged tRNA in the P E site The growing polypeptide chain is transferred to the tRNA in the A site Translocation occurs moving the tRNA in the P E site now without an amino acid the tRNA that was in the A site now charged with the polypeptide chain is moved to the P E site and the tRNA leaves and another aminoacyl tRNA enters the A site to repeat the process 7 After the new amino acid is added to the chain and after the tRNA is released out of the ribosome and into the cytosol the energy provided by the hydrolysis of a GTP bound to the translocase EF G in bacteria and a eEF 2 in eukaryotes and archaea moves the ribosome down one codon towards the 3 end The energy required for translation of proteins is significant For a protein containing n amino acids the number of high energy phosphate bonds required to translate it is 4n 1 8 The rate of translation varies it is significantly higher in prokaryotic cells up to 17 21 amino acid residues per second than in eukaryotic cells up to 6 9 amino acid residues per second 9 Even though the ribosomes are usually considered accurate and processive machines the translation process is subject to errors that can lead either to the synthesis of erroneous proteins or to the premature abandonment of translation either because a tRNA couples to a wrong codon or because a tRNA is coupled to the wrong amino acid 10 The rate of error in synthesizing proteins has been estimated to be between 1 in 105 and 1 in 103 misincorporated amino acids depending on the experimental conditions 11 The rate of premature translation abandonment instead has been estimated to be of the order of magnitude of 10 4 events per translated codon 12 The correct amino acid is covalently bonded to the correct transfer RNA tRNA by amino acyl transferases The amino acid is joined by its carboxyl group to the 3 OH of the tRNA by an ester bond When the tRNA has an amino acid linked to it the tRNA is termed charged Initiation involves the small subunit of the ribosome binding to the 5 end of mRNA with the help of initiation factors IF In bacteria and a minority of archaea initiation of protein synthesis involves the recognition of a purine rich initiation sequence on the mRNA called the Shine Dalgarno sequence The Shine Dalgarno sequence binds to a complementary pyrimidine rich sequence on the 3 end of the 16S rRNA part of the 30S ribosomal subunit The binding of these complementary sequences ensures that the 30S ribosomal subunit is bound to the mRNA and is aligned such that the initiation codon is placed in the 30S portion of the P site Once the mRNA and 30S subunit are properly bound an initiation factor brings the initiator tRNA amino acid complex f Met tRNA to the 30S P site The initiation phase is completed once a 50S subunit joins the 30 subunit forming an active 70S ribosome 13 Termination of the polypeptide occurs when the A site of the ribosome is occupied by a stop codon UAA UAG or UGA on the mRNA creating the primary structure of a protein tRNA usually cannot recognize or bind to stop codons Instead the stop codon induces the binding of a release factor protein 14 RF1 amp RF2 that prompts the disassembly of the entire ribosome mRNA complex by the hydrolysis of the polypeptide chain from the peptidyl transferase center 1 of the ribosome 15 Drugs or special sequence motifs on the mRNA can change the ribosomal structure so that near cognate tRNAs are bound to the stop codon instead of the release factors In such cases of translational readthrough translation continues until the ribosome encounters the next stop codon 16 The process of translation is highly regulated in both eukaryotic and prokaryotic organisms Regulation of translation can impact the global rate of protein synthesis which is closely coupled to the metabolic and proliferative state of a cell In addition recent work has revealed that genetic differences and their subsequent expression as mRNAs can also impact translation rate in an RNA specific manner 17 Clinical significance EditTranslational control is critical for the development and survival of cancer Cancer cells must frequently regulate the translation phase of gene expression though it is not fully understood why translation is targeted over steps like transcription While cancer cells often have genetically altered translation factors it is much more common for cancer cells to modify the levels of existing translation factors 18 Several major oncogenic signaling pathways including the RAS MAPK PI3K AKT mTOR MYC and WNT b catenin pathways ultimately reprogram the genome via translation 19 Cancer cells also control translation to adapt to cellular stress During stress the cell translates mRNAs that can mitigate the stress and promote survival An example of this is the expression of AMPK in various cancers its activation triggers a cascade that can ultimately allow the cancer to escape apoptosis programmed cell death triggered by nutrition deprivation Future cancer therapies may involve disrupting the translation machinery of the cell to counter the downstream effects of cancer 18 Mathematical modeling of translation Edit Figure M0 Basic and the simplest model M0 of protein synthesis Here M amount of mRNA with translation initiation site not occupied by assembling ribosome F amount of mRNA with translation initiation site occupied by assembling ribosome R amount of ribosomes sitting on mRNA synthesizing proteins P amount of synthesized proteins 20 Figure M1 The extended model of protein synthesis M1 with explicit presentation of 40S 60S and initiation factors IF binding 20 The transcription translation process description mentioning only the most basic elementary processes consists of production of mRNA molecules including splicing initiation of these molecules with help of initiation factors e g the initiation can include the circularization step though it is not universally required initiation of translation recruiting the small ribosomal subunit assembly of full ribosomes elongation i e movement of ribosomes along mRNA with production of protein termination of translation degradation of mRNA molecules degradation of proteins The process of amino acid building to create protein in translation is a subject of various physic models for a long time starting from the first detailed kinetic models such as 21 or others taking into account stochastic aspects of translation and using computer simulations Many chemical kinetics based models of protein synthesis have been developed and analyzed in the last four decades 22 23 Beyond chemical kinetics various modeling formalisms such as Totally Asymmetric Simple Exclusion Process TASEP 23 Probabilistic Boolean Networks PBN Petri Nets and max plus algebra have been applied to model the detailed kinetics of protein synthesis or some of its stages A basic model of protein synthesis that takes into account all eight elementary processes has been developed 20 following the paradigm that useful models are simple and extendable 24 The simplest model M0 is represented by the reaction kinetic mechanism Figure M0 It was generalised to include 40S 60S and initiation factors IF binding Figure M1 It was extended further to include effect of microRNA on protein synthesis 25 Most of models in this hierarchy can be solved analytically These solutions were used to extract kinetic signatures of different specific mechanisms of synthesis regulation Genetic code EditMain article Genetic code It is also possible to translate either by hand for short sequences or by computer after first programming one appropriately see section below this allows biologists and chemists to draw out the chemical structure of the encoded protein on paper First convert each template DNA base to its RNA complement note that the complement of A is now U as shown below Note that the template strand of the DNA is the one the RNA is polymerized against the other DNA strand would be the same as the RNA but with thymine instead of uracil DNA gt RNA A gt U T gt A C gt G G gt C A T gt A U Then split the RNA into triplets groups of three bases Note that there are 3 translation windows or reading frames depending on where you start reading the code Finally use the table at Genetic code to translate the above into a structural formula as used in chemistry This will give you the primary structure of the protein However proteins tend to fold depending in part on hydrophilic and hydrophobic segments along the chain Secondary structure can often still be guessed at but the proper tertiary structure is often very hard to determine Whereas other aspects such as the 3D structure called tertiary structure of protein can only be predicted using sophisticated algorithms the amino acid sequence called primary structure can be determined solely from the nucleic acid sequence with the aid of a translation table This approach may not give the correct amino acid composition of the protein in particular if unconventional amino acids such as selenocysteine are incorporated into the protein which is coded for by a conventional stop codon in combination with a downstream hairpin SElenoCysteine Insertion Sequence or SECIS There are many computer programs capable of translating a DNA RNA sequence into a protein sequence Normally this is performed using the Standard Genetic Code however few programs can handle all the special cases such as the use of the alternative initiation codons which are biologically significant For instance the rare alternative start codon CTG codes for Methionine when used as a start codon and for Leucine in all other positions Example Condensed translation table for the Standard Genetic Code from the NCBI Taxonomy webpage 26 AAs FFLLSSSSYY CC WLLLLPPPPHHQQRRRRIIIMTTTTNNKKSSRRVVVVAAAADDEEGGGG Starts M M M Base1 TTTTTTTTTTTTTTTTCCCCCCCCCCCCCCCCAAAAAAAAAAAAAAAAGGGGGGGGGGGGGGGG Base2 TTTTCCCCAAAAGGGGTTTTCCCCAAAAGGGGTTTTCCCCAAAAGGGGTTTTCCCCAAAAGGGG Base3 TCAGTCAGTCAGTCAGTCAGTCAGTCAGTCAGTCAGTCAGTCAGTCAGTCAGTCAGTCAGTCAG The Starts row indicate three start codons UUG CUG and the very common AUG It also indicates the first amino acid residue when interpreted as a start in this case it is all methionine Translation tables Edit Main articles List of genetic codes and Genetic code List of alternative codons Even when working with ordinary eukaryotic sequences such as the Yeast genome it is often desired to be able to use alternative translation tables namely for translation of the mitochondrial genes Currently the following translation tables are defined by the NCBI Taxonomy Group for the translation of the sequences in GenBank 26 The standard code The vertebrate mitochondrial code The yeast mitochondrial code The mold protozoan and coelenterate mitochondrial code and the mycoplasma spiroplasma code The invertebrate mitochondrial code The ciliate dasycladacean and hexamita nuclear code The kinetoplast code The echinoderm and flatworm mitochondrial code The euplotid nuclear code The bacterial archaeal and plant plastid code The alternative yeast nuclear code The ascidian mitochondrial code The alternative flatworm mitochondrial code The Blepharisma nuclear code The chlorophycean mitochondrial code The trematode mitochondrial code The Scenedesmus obliquus mitochondrial code The Thraustochytrium mitochondrial code The Pterobranchia mitochondrial code The candidate division SR1 and gracilibacteria code The Pachysolen tannophilus nuclear code The karyorelict nuclear code The Condylostoma nuclear code The Mesodinium nuclear code The peritrich nuclear code The Blastocrithidia nuclear code The Cephalodiscidae mitochondrial codeSee also EditCell biology Cell division DNA codon table Epigenetics Expanded genetic code Gene expression Gene regulation Gene Genome Life Protein methods Start codonReferences Edit a b 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 Brooker RJ Widmaier EP Graham LE Stiling PD 2014 Biology Third international student ed New York NY McGraw Hill Education p 249 ISBN 978 981 4581 85 1 Neill C 1996 Biology Fourth ed The Benjamin Cummings Publishing Company pp 309 310 ISBN 0 8053 1940 9 Stryer L 2002 Biochemistry Fifth ed W H Freeman and Company p 826 ISBN 0 7167 4684 0 Santos Fenicia Brito Del Bem Luiz Eduardo 2023 The Evolution of tRNA Copy Number and Repertoire in Cellular Life Genes 14 1 27 doi 10 3390 genes14010027 ISSN 2073 4425 Moghal A Mohler K Ibba M November 2014 Mistranslation of the genetic code FEBS Letters 588 23 4305 10 doi 10 1016 j febslet 2014 08 035 PMC 4254111 PMID 25220850 Griffiths A 2008 9 Introduction to Genetic Analysis 9th ed New York W H Freeman and Company pp 335 339 ISBN 978 0 7167 6887 6 Computational Analysis of Genomic Sequences utilizing Machine Learning scholar googleusercontent com Retrieved 2022 01 12 Ross JF Orlowski M February 1982 Growth rate dependent adjustment of ribosome function in chemostat grown cells of the fungus Mucor racemosus Journal of Bacteriology 149 2 650 3 doi 10 1128 JB 149 2 650 653 1982 PMC 216554 PMID 6799491 Ou X Cao J Cheng A Peppelenbosch MP Pan Q March 2019 Errors in translational decoding tRNA wobbling or misincorporation PLOS Genetics 15 3 2979 2986 doi 10 1371 journal pgen 1008017 PMC 3158919 PMID 21930591 Wohlgemuth I Pohl C Mittelstaet J Konevega AL Rodnina MV October 2011 Evolutionary optimization of speed and accuracy of decoding on the ribosome Philosophical Transactions of the Royal Society of London Series B Biological Sciences 366 1580 2979 86 doi 10 1098 rstb 2011 0138 PMC 6438450 PMID 30921315 Sin C Chiarugi D Valleriani A April 2016 Quantitative assessment of ribosome drop off in E coli Nucleic Acids Research 44 6 2528 37 doi 10 1093 nar gkw137 PMC 4824120 PMID 26935582 Nakamoto T February 2011 Mechanisms of the initiation of protein synthesis in reading frame binding of ribosomes to mRNA Molecular Biology Reports 38 2 847 55 doi 10 1007 s11033 010 0176 1 PMID 20467902 S2CID 22038744 Baggett NE Zhang Y Gross CA March 2017 Ibba M ed Global analysis of translation termination in E coli PLOS Genetics 13 3 e1006676 doi 10 1371 journal pgen 1006676 PMC 5373646 PMID 28301469 Mora L Zavialov A Ehrenberg M Buckingham RH December 2003 Stop codon recognition and interactions with peptide release factor RF3 of truncated and chimeric RF1 and RF2 from Escherichia coli Molecular Microbiology 50 5 1467 76 doi 10 1046 j 1365 2958 2003 03799 x PMID 14651631 Schueren F Thoms S August 2016 Functional Translational Readthrough A Systems Biology Perspective PLOS Genetics 12 8 e1006196 doi 10 1371 JOURNAL PGEN 1006196 PMC 4973966 PMID 27490485 Cenik C Cenik ES Byeon GW Grubert F Candille SI Spacek D et al November 2015 Integrative analysis of RNA translation and protein levels reveals distinct regulatory variation across humans Genome Research 25 11 1610 21 doi 10 1101 gr 193342 115 PMC 4617958 PMID 26297486 a b Xu Y Ruggero D March 2020 The Role of Translation Control in Tumorigenesis and Its Therapeutic Implications Annual Review of Cancer Biology 4 1 437 457 doi 10 1146 annurev cancerbio 030419 033420 Truitt ML Ruggero D April 2016 New frontiers in translational control of the cancer genome Nature Reviews Cancer 16 5 288 304 doi 10 1038 nrc 2016 27 PMC 5491099 PMID 27112207 a b c Gorban AN Harel Bellan A Morozova N Zinovyev A July 2019 Basic simple and extendable kinetic model of protein synthesis Mathematical Biosciences and Engineering 16 6 6602 6622 doi 10 3934 mbe 2019329 PMID 31698578 MacDonald CT Gibbs JH Pipkin AC 1968 Kinetics of biopolymerization on nucleic acid templates Biopolymers 6 1 1 5 doi 10 1002 bip 1968 360060102 PMID 5641411 S2CID 27559249 Heinrich R Rapoport TA September 1980 Mathematical modelling of translation of mRNA in eucaryotes steady state time dependent processes and application to reticulocytes Journal of Theoretical Biology 86 2 279 313 Bibcode 1980JThBi 86 279H doi 10 1016 0022 5193 80 90008 9 PMID 7442295 a b Skjondal Bar N Morris DR January 2007 Dynamic model of the process of protein synthesis in eukaryotic cells Bulletin of Mathematical Biology 69 1 361 93 doi 10 1007 s11538 006 9128 2 PMID 17031456 S2CID 83701439 Coyte KZ Tabuteau H Gaffney EA Foster KR Durham WM April 2017 Reply to Baveye and Darnault Useful models are simple and extendable Proceedings of the National Academy of Sciences of the United States of America 114 14 E2804 E2805 Bibcode 2017PNAS 114E2804C doi 10 1073 pnas 1702303114 PMC 5389313 PMID 28341710 Morozova N Zinovyev A Nonne N Pritchard LL Gorban AN Harel Bellan A September 2012 Kinetic signatures of microRNA modes of action RNA 18 9 1635 55 doi 10 1261 rna 032284 112 PMC 3425779 PMID 22850425 a b Elzanowski Andrzej Ostell Jim January 2019 The Genetic Codes National Center for Biotechnology Information NCBI Retrieved 31 May 2022 a href Template Cite web html title Template Cite web cite web a CS1 maint url status link Further reading EditChampe PC Harvey RA Ferrier DR 2004 Lippincott s Illustrated Reviews Biochemistry 3rd ed Hagerstwon MD Lippincott Williams amp Wilkins ISBN 0 7817 2265 9 Cox M Nelson DR Lehninger AL 2005 Lehninger principles of biochemistry 4th ed San Francisco W H Freeman ISBN 0 7167 4339 6 Malys N McCarthy JE March 2011 Translation initiation variations in the mechanism can be anticipated Cellular and Molecular Life Sciences 68 6 991 1003 doi 10 1007 s00018 010 0588 z PMID 21076851 S2CID 31720000 External links Edit Wikimedia Commons has media related to Translation biology Virtual Cell Animation Collection Introducing Translation Translate tool from DNA or RNA sequence Portals Biology Astronomy Retrieved from https en wikipedia org w index php title Translation biology amp oldid 1129900502, wikipedia, wiki, book, books, library,

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