fbpx
Wikipedia

Molecular biology

January 31, 2023

"Biochemical genetics" redirects here. For the scientific journal, see Biochemical Genetics (journal).
"Molecular microbiology" redirects here. For the scientific journal, see Molecular Microbiology (journal).

Molecular biology /məˈlɛkjʊlər/ is the branch of biology that seeks to understand the molecular basis of biological activity in and between cells, including biomolecular synthesis, modification, mechanisms, and interactions.[1][2][3] The study of chemical and physical structure of biological macromolecules is known as molecular biology.[4]

Molecular biology was first described as an approach focused on the underpinnings of biological phenomena - uncovering the structures of biological molecules as well as their interactions, and how these interactions explain observations of classical biology.[5]

In 1945 the term molecular biology was used by physicist William Astbury. In 1953 Francis Crick, James Watson, Rosalind Franklin, and colleagues, working at Medical Research Council unit, Cavendish laboratory, Cambridge (now the MRC Laboratory of Molecular Biology), made a double helix model of DNA which changed the entire research scenario. They proposed the DNA structure based on previous research done by Rosalind Franklin and Maurice Wilkins. This research then lead to finding DNA material in other microorganisms, plants and animals.[4]

Molecular biology is not simply the study of biological molecules and their interactions; rather, it is also a collection of techniques developed since the field's genesis which have enabled scientists to learn about molecular processes.[6] In this way it has both complemented and improved biochemistry and genetics as methods (of understanding nature) that began before its advent. One notable technique which has revolutionized the field is the polymerase chain reaction (PCR), which was developed in 1983.[6] PCR is a reaction which amplifies small quantities of DNA, and it is used in many applications across scientific disciplines.[7][8]

The central dogma of molecular biology describes the process in which DNA is transcribed into RNA, which is then translated into protein.[2][9]

Molecular biology also plays a critical role in the understanding of structures, functions, and internal controls within individual cells, all of which can be used to efficiently target new drugs, diagnose disease, and better understand cell physiology.[10] Some clinical research and medical therapies arising from molecular biology are covered under gene therapy whereas the use of molecular biology or molecular cell biology in medicine is now referred to as molecular medicine.

History of molecular biology

Main article: History of molecular biology

Molecular biology sits at the intersection of biochemistry and genetics; as these scientific disciplines emerged and evolved in the 20th century, it became clear that they both sought to determine the molecular mechanisms which underlie vital cellular functions.[11] Advances in molecular biology have been closely related to the development of new technologies and their optimization.[12] Molecular biology has been elucidated by the work of many scientists, and thus the history of the field depends on an understanding of these scientists and their experiments.

The field of genetics arose as an attempt to understand the molecular mechanisms of genetic inheritance and the structure of a gene. Gregor Mendel pioneered this work in 1866, when he first wrote the laws of genetic inheritance based on his studies of mating crosses in pea plants.[13] One such law of genetic inheritance is the law of segregation, which states that diploid individuals with two alleles for a particular gene will pass one of these alleles to their offspring.[14] Because of his critical work, the study of genetic inheritance is commonly referred to as Mendelian genetics.[15]

A major milestone in molecular biology was the discovery of the structure of DNA. This work began in 1869 by Friedrich Miescher, a Swiss biochemist who first proposed a structure called nuclein, which we now know to be (deoxyribonucleic acid), or DNA.[16] He discovered this unique substance by studying the components of pus-filled bandages, and noting the unique properties of the "phosphorus-containing substances".[17] Another notable contributor to the DNA model was Phoebus Levene, who proposed the "polynucleotide model" of DNA in 1919 as a result of his biochemical experiments on yeast.[18] In 1950, Erwin Chargaff expanded on the work of Levene and elucidated a few critical properties of nucleic acids: first, the sequence of nucleic acids varies across species.[19] Second, the total concentration of purines (adenine and guanine) is always equal to the total concentration of pyrimidines (cysteine and thymine).[16] This is now known as Chargaff's rule. In 1953, James Watson and Francis Crick published the double helical structure of DNA,[20] using the X-ray crystallography work done by Rosalind Franklin and Maurice Wilkins. Watson and Crick described the structure of DNA and conjectured about the implications of this unique structure for possible mechanisms of DNA replication.[20]

J. D. Watson and F. H. C. Crick were awarded Nobel prize in 1962, along with Maurice Wilkens, for proposing a model of the structure of DNA.[4]

In 1961, it was demonstrated that when a gene encodes a protein, three sequential bases of a gene's DNA specify each successive amino acid of the protein.[21] Thus the genetic code is a triplet code, where each triplet (called a codon) specifies a particular amino acid. Furthermore, it was shown that the codons do not overlap with each other in the DNA sequence encoding a protein, and that each sequence is read from a fixed starting point.

During 1962–1964, through the use of conditional lethal mutants of a bacterial virus,[22] fundamental advances were made in our understanding of the functions and interactions of the proteins employed in the machinery of DNA replication, DNA repair, DNA recombination, and in the assembly of molecular structures.

 
Diagrammatic representation of Watson and Crick's DNA structure
 
Angle description in DNA structure

The F.Griffith experiment

 
Diagrammatic representation of experiment
Main article: Griffith's experiment

In 1928, Fredrick Griffith, encountered a virulence property in pneumococcus bacteria, which was killing lab rats. According to Mendel, prevalent at that time, gene transfer could occur only from parent to daughter cells only. Griffith advanced another theory, stating that gene transfer occurring in member of same generation is known as horizontal gene transfer (HGT). This phenomenon is now referred to as genetic transformation.

Griffith addressed the Streptococcus pneumoniae bacteria, which had two different strains, one virulent and smooth and one avirulent and rough. The smooth strain had glistering appearance owing to the presence of a type of specific polysaccharide – a polymer of glucose and glucuronic acid capsule. Due to this polysaccharide layer of bacteria, a host's immune system cannot recognize the bacteria and it kills the host. The other, avirulent, rough strain lacks this polysaccharide capsule and has a dull, rough appearance.

Presence or absence of capsule in the  strain, is known to be genetically determined. Smooth and rough strains occur in several different type such as S-I, S-II, S-III, etc. and R-I, R-II, R-III, etc. respectively. All this subtypes of S and R bacteria differ with each other in antigen type they produce.[4]

Hershey and Chase experiment

Main article: Hershey–Chase experiment
 
Hershey and Chase experiment

Confirmation that DNA is the genetic material which is cause of infection came from Hershey and Chase experiment. They used E.coli and bacteriophage for the experiment. This experiment is also known as blender experiment, as kitchen blender was used as a major piece of apparatus. Alfred Hershey and Martha Chase demonstrated that the DNA injected by a phage particle into a bacterium contains all information required to synthesize progeny phage particles. They used radioactivity to tag the bacteriophage's protein coat with radioactive sulphur and DNA with radioactive phosphorus, into two different test tubes respectively. After mixing bacteriophage and E.coli into the test tube, the incubation period starts in which phage transforms the genetic material in the E.coli cells. Then the mixture is blended or agitated, which separates the phage from E.coli cells. The whole mixture is centrifuged and the pellet which contains E.coli cells was checked and the supernatant was discarded. The E.coli cells showed radioactive phosphorus, which indicated that the transformed material was DNA not the protein coat.

The transformed DNA gets attached to the DNA of E.coli and radioactivity is only seen onto the bacteriophage's DNA. This mutated DNA can be passed to the next generation and the theory of Transduction came into existence. Transduction is a process in which the bacterial DNA carry the fragment of bacteriophages and pass it on the next generation. This is also a type of horizontal gene transfer.[4]

Modern molecular biology

In the early 2020s, molecular biology entered a golden age defined by both vertical and horizontal technical development. Vertically, novel technologies are allowing for real-time monitoring of biological processes at the atomic level.[23] Molecular biologists today have access to increasingly affordable sequencing data at increasingly higher depths, facilitating the development of novel genetic manipulation methods in new non-model organisms. Likewise, synthetic molecular biologists will drive the industrial production of small and macro molecules through the introduction of exogenous metabolic pathways in various prokaryotic and eukaryotic cell lines.[24]

Horizontally, sequencing data is becoming more affordable and used in many different scientific fields. This will drive the development of industries in developing nations and increase accessibility to individual researchers. Likewise, CRISPR-Cas9 gene editing experiments can now be conceived and implemented by individuals for under $10,000 in novel organisms, which will drive the development of industrial and medical applications [25]

Relationship to other biological sciences

 
Schematic relationship between biochemistry, genetics and molecular biology

The following list describes a viewpoint on the interdisciplinary relationships between molecular biology and other related fields.[26]

While researchers practice techniques specific to molecular biology, it is common to combine these with methods from genetics and biochemistry. Much of molecular biology is quantitative, and recently a significant amount of work has been done using computer science techniques such as bioinformatics and computational biology. Molecular genetics, the study of gene structure and function, has been among the most prominent sub-fields of molecular biology since the early 2000s. Other branches of biology are informed by molecular biology, by either directly studying the interactions of molecules in their own right such as in cell biology and developmental biology, or indirectly, where molecular techniques are used to infer historical attributes of populations or species, as in fields in evolutionary biology such as population genetics and phylogenetics. There is also a long tradition of studying biomolecules "from the ground up", or molecularly, in biophysics.[29]

Techniques of molecular biology

 
DNA animation
For more extensive list on protein methods, see protein methods. For more extensive list on nucleic acid methods, see nucleic acid methods.

Molecular cloning

Main article: Molecular cloning
 
Transduction image

Molecular cloning is used to isolate and then transfer a DNA sequence of interest into a plasmid vector.[30] This recombinant DNA technology was first developed in the 1960s.[31] In this technique, a DNA sequence coding for a protein of interest is cloned using polymerase chain reaction (PCR), and/or restriction enzymes, into a plasmid (expression vector). The plasmid vector usually has at least 3 distinctive features: an origin of replication, a multiple cloning site (MCS), and a selective marker (usually antibiotic resistance). Additionally, upstream of the MCS are the promoter regions and the transcription start site, which regulate the expression of cloned gene.

This plasmid can be inserted into either bacterial or animal cells. Introducing DNA into bacterial cells can be done by transformation via uptake of naked DNA, conjugation via cell-cell contact or by transduction via viral vector. Introducing DNA into eukaryotic cells, such as animal cells, by physical or chemical means is called transfection. Several different transfection techniques are available, such as calcium phosphate transfection, electroporation, microinjection and liposome transfection. The plasmid may be integrated into the genome, resulting in a stable transfection, or may remain independent of the genome and expressed temporarily, called a transient transfection.[32][33]

DNA coding for a protein of interest is now inside a cell, and the protein can now be expressed. A variety of systems, such as inducible promoters and specific cell-signaling factors, are available to help express the protein of interest at high levels. Large quantities of a protein can then be extracted from the bacterial or eukaryotic cell. The protein can be tested for enzymatic activity under a variety of situations, the protein may be crystallized so its tertiary structure can be studied, or, in the pharmaceutical industry, the activity of new drugs against the protein can be studied.[34]

Polymerase chain reaction

Main article: Polymerase chain reaction

Polymerase chain reaction (PCR) is an extremely versatile technique for copying DNA. In brief, PCR allows a specific DNA sequence to be copied or modified in predetermined ways. The reaction is extremely powerful and under perfect conditions could amplify one DNA molecule to become 1.07 billion molecules in less than two hours. PCR has many applications, including the study of gene expression, the detection of pathogenic microorganisms, the detection of genetic mutations, and the introduction of mutations to DNA.[35] The PCR technique can be used to introduce restriction enzyme sites to ends of DNA molecules, or to mutate particular bases of DNA, the latter is a method referred to as site-directed mutagenesis. PCR can also be used to determine whether a particular DNA fragment is found in a cDNA library. PCR has many variations, like reverse transcription PCR (RT-PCR) for amplification of RNA, and, more recently, quantitative PCR which allow for quantitative measurement of DNA or RNA molecules.[36][37]

 
Two percent agarose gel in borate buffer cast in a gel tray.

Gel electrophoresis

 
SDS-PAGE
Main article: Gel electrophoresis

Gel electrophoresis is a technique which separates molecules by their size using an agarose or polyacrylamide gel.[38] This technique is one of the principal tools of molecular biology. The basic principle is that DNA fragments can be separated by applying an electric current across the gel - because the DNA backbone contains negatively charged phosphate groups, the DNA will migrate through the agarose gel towards the positive end of the current.[38] Proteins can also be separated on the basis of size using an SDS-PAGE gel, or on the basis of size and their electric charge by using what is known as a 2D gel electrophoresis.[39]

 
Proteins stained on a PAGE gel using Coomassie blue dye.

The Bradford Assay

Main article: The Bradford Assay

The Bradford Assay is a molecular biology technique which enables the fast, accurate quantitation of protein molecules utilizing the unique properties of a dye called Coomassie Brilliant Blue G-250.[40] Coomassie Blue undergoes a visible color shift from reddish-brown to bright blue upon binding to protein.[40] In its unstable, cationic state, Coomassie Blue has a background wavelength of 465 nm and gives off a reddish-brown color.[41] When Coomassie Blue binds to protein in an acidic solution, the background wavelength shifts to 595 nm and the dye gives off a bright blue color.[41] Proteins in the assay bind Coomassie blue in about 2 minutes, and the protein-dye complex is stable for about an hour, although it's recommended that absorbance readings are taken within 5 to 20 minutes of reaction initiation.[40] The concentration of protein in the Bradford assay can then be measured using a visible light spectrophotometer, and therefore does not require extensive equipment.[41]

This method was developed in 1975 by Marion M. Bradford, and has enabled significantly faster, more accurate protein quantitation compared to previous methods: the Lowry procedure and the biuret assay.[40] Unlike the previous methods, the Bradford assay is not susceptible to interference by several non-protein molecules, including ethanol, sodium chloride, and magnesium chloride.[40]  However, it is susceptible to influence by strong alkaline buffering agents, such as sodium dodecyl sulfate (SDS).[40]

Macromolecule blotting and probing

The terms northern, western and eastern blotting are derived from what initially was a molecular biology joke that played on the term Southern blotting, after the technique described by Edwin Southern for the hybridisation of blotted DNA. Patricia Thomas, developer of the RNA blot which then became known as the northern blot, actually didn't use the term.[42]

Southern blotting

Main article: Southern blot

Named after its inventor, biologist Edwin Southern, the Southern blot is a method for probing for the presence of a specific DNA sequence within a DNA sample. DNA samples before or after restriction enzyme (restriction endonuclease) digestion are separated by gel electrophoresis and then transferred to a membrane by blotting via capillary action. The membrane is then exposed to a labeled DNA probe that has a complement base sequence to the sequence on the DNA of interest.[43] Southern blotting is less commonly used in laboratory science due to the capacity of other techniques, such as PCR, to detect specific DNA sequences from DNA samples. These blots are still used for some applications, however, such as measuring transgene copy number in transgenic mice or in the engineering of gene knockout embryonic stem cell lines.[29]

Northern blotting

Main article: Northern blot
 
Northern blot diagram

The northern blot is used to study the presence of specific RNA molecules as relative comparison among a set of different samples of RNA. It is essentially a combination of denaturing RNA gel electrophoresis, and a blot. In this process RNA is separated based on size and is then transferred to a membrane that is then probed with a labeled complement of a sequence of interest. The results may be visualized through a variety of ways depending on the label used; however, most result in the revelation of bands representing the sizes of the RNA detected in sample. The intensity of these bands is related to the amount of the target RNA in the samples analyzed. The procedure is commonly used to study when and how much gene expression is occurring by measuring how much of that RNA is present in different samples, assuming that no post-transcriptional regulation occurs and that the levels of mRNA reflect proportional levels of the corresponding protein being produced. It is one of the most basic tools for determining at what time, and under what conditions, certain genes are expressed in living tissues.[44][45]

Western blotting

Main article: Western blot

A western blot is a technique by which specific proteins can be detected from a mixture of proteins.[46] Western blots can be used to determine the size of isolated proteins, as well as to quantify their expression.[47] In western blotting, proteins are first separated by size, in a thin gel sandwiched between two glass plates in a technique known as SDS-PAGE. The proteins in the gel are then transferred to a polyvinylidene fluoride (PVDF), nitrocellulose, nylon, or other support membrane. This membrane can then be probed with solutions of antibodies. Antibodies that specifically bind to the protein of interest can then be visualized by a variety of techniques, including colored products, chemiluminescence, or autoradiography. Often, the antibodies are labeled with enzymes. When a chemiluminescent substrate is exposed to the enzyme it allows detection. Using western blotting techniques allows not only detection but also quantitative analysis. Analogous methods to western blotting can be used to directly stain specific proteins in live cells or tissue sections.[46][48]

Eastern blotting

Main article: Eastern blot

The eastern blotting technique is used to detect post-translational modification of proteins. Proteins blotted on to the PVDF or nitrocellulose membrane are probed for modifications using specific substrates.[49]

Microarrays

Main article: DNA microarray
A DNA microarray being printed
 
Hybridization of target to probe

A DNA microarray is a collection of spots attached to a solid support such as a microscope slide where each spot contains one or more single-stranded DNA oligonucleotide fragments. Arrays make it possible to put down large quantities of very small (100 micrometre diameter) spots on a single slide. Each spot has a DNA fragment molecule that is complementary to a single DNA sequence. A variation of this technique allows the gene expression of an organism at a particular stage in development to be qualified (expression profiling). In this technique the RNA in a tissue is isolated and converted to labeled complementary DNA (cDNA). This cDNA is then hybridized to the fragments on the array and visualization of the hybridization can be done. Since multiple arrays can be made with exactly the same position of fragments, they are particularly useful for comparing the gene expression of two different tissues, such as a healthy and cancerous tissue. Also, one can measure what genes are expressed and how that expression changes with time or with other factors. There are many different ways to fabricate microarrays; the most common are silicon chips, microscope slides with spots of ~100 micrometre diameter, custom arrays, and arrays with larger spots on porous membranes (macroarrays). There can be anywhere from 100 spots to more than 10,000 on a given array. Arrays can also be made with molecules other than DNA.[50][51][52][53]

Allele-specific oligonucleotide

Main article: Allele-specific oligonucleotide

Allele-specific oligonucleotide (ASO) is a technique that allows detection of single base mutations without the need for PCR or gel electrophoresis. Short (20–25 nucleotides in length), labeled probes are exposed to the non-fragmented target DNA, hybridization occurs with high specificity due to the short length of the probes and even a single base change will hinder hybridization. The target DNA is then washed and the labeled probes that didn't hybridize are removed. The target DNA is then analyzed for the presence of the probe via radioactivity or fluorescence. In this experiment, as in most molecular biology techniques, a control must be used to ensure successful experimentation.[54][55]

In molecular biology, procedures and technologies are continually being developed and older technologies abandoned. For example, before the advent of DNA gel electrophoresis (agarose or polyacrylamide), the size of DNA molecules was typically determined by rate sedimentation in sucrose gradients, a slow and labor-intensive technique requiring expensive instrumentation; prior to sucrose gradients, viscometry was used. Aside from their historical interest, it is often worth knowing about older technology, as it is occasionally useful to solve another new problem for which the newer technique is inappropriate.[56]

See also

References

  1. ^ Alberts B, Johnson A, Lewis J, Morgan D, Raff M, Roberts K, Walter P (2014). Molecular Biology of the Cell, Sixth Edition. Garland Science. pp. 1–10. ISBN 978-1-317-56375-4.
  2. ^ a b Gannon F (February 2002). "Molecular biology--what's in a name?". EMBO Reports. 3 (2): 101. doi:10.1093/embo-reports/kvf039. PMC 1083977. PMID 11839687.
  3. ^ "Molecular biology - Latest research and news | Nature". www.nature.com. Retrieved 2021-11-07.
  4. ^ a b c d e S., Verma, P. (2004). Cell biology, genetics, molecular biology, evolution and ecology. S Chand and Company. ISBN 81-219-2442-1. OCLC 1045495545.
  5. ^ Astbury, W. T. (June 1961). "Molecular Biology or Ultrastructural Biology ?". Nature. 190 (4781): 1124. Bibcode:1961Natur.190.1124A. doi:10.1038/1901124a0. ISSN 1476-4687. PMID 13684868. S2CID 4172248.
  6. ^ a b Morange, Michel (2016-02-15), "History of Molecular Biology", eLS, Chichester, UK: John Wiley & Sons, Ltd, pp. 1–8, doi:10.1002/9780470015902.a0003079.pub3, ISBN 9780470016176, retrieved 2021-11-07
  7. ^ "Polymerase Chain Reaction (PCR)", Definitions, Qeios, 2019-11-26, doi:10.32388/167113, S2CID 94561339
  8. ^ "Smithsonian Institution Archives". siarchives.si.edu. Retrieved 2021-11-07.
  9. ^ Cox, Michael M. (2015-03-16). Molecular biology: principles and practice. Doudna, Jennifer A.,, O'Donnell, Michael (Biochemist) (Second ed.). New York. ISBN 978-1-4641-2614-7. OCLC 905380069.
  10. ^ Bello, Elizabeth A.; Schwinn, Debra A. (1996-12-01). "Molecular Biology and Medicine: A Primer for the Clinician". Anesthesiology. 85 (6): 1462–1478. doi:10.1097/00000542-199612000-00029. ISSN 0003-3022. PMID 8968195. S2CID 29581630.
  11. ^ Morange, Michel (June 2021). A history of biology. ISBN 978-0-691-18878-2. OCLC 1184123419.
  12. ^ Fields, Stanley (2001-08-28). "The interplay of biology and technology". Proceedings of the National Academy of Sciences. 98 (18): 10051–10054. doi:10.1073/pnas.191380098. ISSN 0027-8424. PMC 56913. PMID 11517346.
  13. ^ Ellis, T. H. Noel; Hofer, Julie M. I.; Timmerman-Vaughan, Gail M.; Coyne, Clarice J.; Hellens, Roger P. (2011-11-01). "Mendel, 150 years on". Trends in Plant Science. 16 (11): 590–596. doi:10.1016/j.tplants.2011.06.006. ISSN 1360-1385. PMID 21775188.
  14. ^ "12.3C: Mendel's Law of Segregation". Biology LibreTexts. 2018-07-12. Retrieved 2021-11-18.
  15. ^ "Mendelian Inheritance". Genome.gov. Retrieved 2021-11-18.
  16. ^ a b "Discovery of DNA Double Helix: Watson and Crick | Learn Science at Scitable". www.nature.com. Retrieved 2021-11-25.
  17. ^ George., Wolf (2003). Friedrich Miescher: the man who discovered DNA. OCLC 907773747.
  18. ^ Levene, P.A. (1919). "Structure of Yeast Nucleic Acid". Journal of Biological Chemistry. 43 (2): 379–382. doi:10.1016/s0021-9258(18)86289-5. ISSN 0021-9258.
  19. ^ Chargaff, Erwin (1950). "Chemical specificity of nucleic acids and mechanism of their enzymatic degradation". Experientia. 6 (6): 201–209. doi:10.1007/bf02173653. ISSN 0014-4754. PMID 15421335. S2CID 2522535.
  20. ^ a b Watson, J. D.; Crick, F. H. C. (April 1953). "Molecular Structure of Nucleic Acids: A Structure for Deoxyribose Nucleic Acid". Nature. 171 (4356): 737–738. Bibcode:1953Natur.171..737W. doi:10.1038/171737a0. ISSN 1476-4687. PMID 13054692. S2CID 4253007.
  21. ^ Crick, F. H. C.; Barnett, Leslie; Brenner, S.; Watts-Tobin, R. J. (1961). "General Nature of the Genetic Code for Proteins". Nature. Springer Science and Business Media LLC. 192 (4809): 1227–1232. Bibcode:1961Natur.192.1227C. doi:10.1038/1921227a0. ISSN 0028-0836. PMID 13882203. S2CID 4276146.
  22. ^ Epstein, R. H.; Bolle, A.; Steinberg, C. M.; Kellenberger, E.; Boy de la Tour, E.; et al. (1963-01-01). "Physiological Studies of Conditional Lethal Mutants of Bacteriophage T4D". Cold Spring Harbor Symposia on Quantitative Biology. Cold Spring Harbor Laboratory. 28: 375–394. doi:10.1101/sqb.1963.028.01.053. ISSN 0091-7451.
  23. ^ Mojiri, Soheil; Isbaner, Sebastian; Mühle, Steffen; Jang, Hongje; Bae, Albert Johann; Gregor, Ingo; Gholami, Azam; Gholami, Azam; Enderlein, Jörg (2021-06-01). "Rapid multi-plane phase-contrast microscopy reveals torsional dynamics in flagellar motion". Biomedical Optics Express. 12 (6): 3169–3180. doi:10.1364/BOE.419099. ISSN 2156-7085. PMC 8221972. PMID 34221652.
  24. ^ van Warmerdam, T. "Molecular Biology Laboratory Resource". Yourbiohelper.com.{{cite web}}: CS1 maint: url-status (link)
  25. ^ van Warmerdam, T. "Molecular biology laboratory resource". Yourbiohelper.com.{{cite web}}: CS1 maint: url-status (link)
  26. ^ Lodish H, Berk A, Zipursky SL, Matsudaira P, Baltimore D, Darnell J (2000). Molecular cell biology (4th ed.). New York: Scientific American Books. ISBN 978-0-7167-3136-8.
  27. ^ Berg, Jeremy (2002). Biochemistry. Tymoczko, John L.; Stryer, Lubert (5th ed.). New York: W.H. Freeman. ISBN 0-7167-3051-0. OCLC 48055706.
  28. ^ Reference, Genetics Home. "Help Me Understand Genetics". Genetics Home Reference. Retrieved 31 December 2016.
  29. ^ a b Tian J, ed. (2013). Molecular Imaging: Fundamentals and Applications. Springer-Verlag Berlin & Heidelberg GmbH & Co. K. p. 542. ISBN 9783642343032. Retrieved 2019-07-08.
  30. ^ "Foundations of Molecular Cloning - Past, Present and Future | NEB". www.neb.com. Retrieved 2021-11-25.
  31. ^ "Foundations of Molecular Cloning - Past, Present and Future | NEB". www.neb.com. Retrieved 2021-11-04.
  32. ^ Alberts B, Johnson A, Lewis J, Raff M, Roberts K, Walter P. Isolating, Cloning, and Sequencing DNA. Retrieved 31 December 2016.
  33. ^ Lessard, Juliane C. (1 January 2013). "Molecular cloning". Laboratory Methods in Enzymology: DNA. Methods in Enzymology. Vol. 529. pp. 85–98. doi:10.1016/B978-0-12-418687-3.00007-0. ISBN 978-0-12-418687-3. ISSN 1557-7988. PMID 24011038.
  34. ^ Kokate C, Jalalpure SS, Hurakadle PJ (2016). Textbook of Pharmaceutical Biotechnology. Expression Cloning. Elsevier. p. 125. ISBN 9788131239872. Retrieved 2019-07-08.
  35. ^ Lenstra, J. A. (July 1995). "The applications of the polymerase chain reaction in the life sciences". Cellular and Molecular Biology (Noisy-Le-Grand, France). 41 (5): 603–614. ISSN 0145-5680. PMID 7580841.
  36. ^ "Polymerase Chain Reaction (PCR)". National Center for Biotechnology Information. U.S. National Library of Medicine. Retrieved 31 December 2016.
  37. ^ "Polymerase Chain Reaction (PCR) Fact Sheet". National Human Genome Research Institute (NHGRI). Retrieved 31 December 2016.
  38. ^ a b Lee, Pei Yun; Costumbrado, John; Hsu, Chih-Yuan; Kim, Yong Hoon (2012-04-20). "Agarose Gel Electrophoresis for the Separation of DNA Fragments". Journal of Visualized Experiments (62): 3923. doi:10.3791/3923. ISSN 1940-087X. PMC 4846332. PMID 22546956.
  39. ^ Lee PY, Costumbrado J, Hsu CY, Kim YH (April 2012). "Agarose gel electrophoresis for the separation of DNA fragments". Journal of Visualized Experiments (62). doi:10.3791/3923. PMC 4846332. PMID 22546956.
  40. ^ a b c d e f Bradford, Marion M. (1976-05-07). "A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding". Analytical Biochemistry. 72 (1): 248–254. doi:10.1016/0003-2697(76)90527-3. ISSN 0003-2697. PMID 942051. S2CID 4359292.
  41. ^ a b c "Protein determination by the Bradford method". www.ruf.rice.edu. Retrieved 2021-11-08.
  42. ^ Thomas PS (September 1980). "Hybridization of denatured RNA and small DNA fragments transferred to nitrocellulose". Proceedings of the National Academy of Sciences of the United States of America. 77 (9): 5201–5. Bibcode:1980PNAS...77.5201T. doi:10.1073/pnas.77.9.5201. PMC 350025. PMID 6159641.
  43. ^ Brown T (May 2001). "Southern blotting". Current Protocols in Immunology. Chapter 10: Unit 10.6A. doi:10.1002/0471142735.im1006as06. ISBN 978-0-471-14273-7. PMID 18432697. S2CID 20686993.
  44. ^ Josefsen K, Nielsen H (2011). Nielsen H (ed.). RNA methods and protocols. Methods in Molecular Biology. Vol. 703. New York: Humana Press. pp. 87–105. doi:10.1007/978-1-59745-248-9_7. ISBN 978-1-59745-248-9. PMID 21125485.
  45. ^ He SL, Green R (1 January 2013). "Northern blotting". Methods in Enzymology. 530: 75–87. doi:10.1016/B978-0-12-420037-1.00003-8. ISBN 978-0-12-420037-1. PMC 4287216. PMID 24034315.
  46. ^ a b Mahmood T, Yang PC (September 2012). "Western blot: technique, theory, and trouble shooting". North American Journal of Medical Sciences. 4 (9): 429–34. doi:10.4103/1947-2714.100998. PMC 3456489. PMID 23050259.
  47. ^ "Western blot | Learn Science at Scitable". www.nature.com. Retrieved 2021-11-25.
  48. ^ Kurien BT, Scofield RH (April 2006). "Western blotting". Methods. 38 (4): 283–93. doi:10.1016/j.ymeth.2005.11.007. PMID 16483794. – via ScienceDirect (Subscription may be required or content may be available in libraries.)
  49. ^ Thomas S, Thirumalapura N, Crossley EC, Ismail N, Walker DH (June 2009). "Antigenic protein modifications in Ehrlichia". Parasite Immunology. 31 (6): 296–303. doi:10.1111/j.1365-3024.2009.01099.x. PMC 2731653. PMID 19493209.
  50. ^ "Microarrays". National Center for Biotechnology Information. U.S. National Library of Medicine. Retrieved 31 December 2016.
  51. ^ Bumgarner R (January 2013). Frederick M. Ausubel, et al. (eds.). "Overview of DNA microarrays: types, applications, and their future". Current Protocols in Molecular Biology. Chapter 22: Unit 22.1. doi:10.1002/0471142727.mb2201s101. ISBN 978-0-471-14272-0. PMC 4011503. PMID 23288464.
  52. ^ Govindarajan R, Duraiyan J, Kaliyappan K, Palanisamy M (August 2012). "Microarray and its applications". Journal of Pharmacy & Bioallied Sciences. 4 (Suppl 2): S310-2. doi:10.4103/0975-7406.100283. PMC 3467903. PMID 23066278.
  53. ^ Tarca AL, Romero R, Draghici S (August 2006). "Analysis of microarray experiments of gene expression profiling". American Journal of Obstetrics and Gynecology. 195 (2): 373–88. doi:10.1016/j.ajog.2006.07.001. PMC 2435252. PMID 16890548.
  54. ^ Cheng L, Zhang DY, eds. (2008). Molecular genetic pathology. Totowa, NJ: Humana. p. 96. ISBN 978-1-59745-405-6. Retrieved 31 December 2016.
  55. ^ Leonard DG (2016). Molecular Pathology in Clinical Practice. Springer. p. 31. ISBN 978-3-319-19674-9. Retrieved 31 December 2016.
  56. ^ Tian J, ed. (2013). Molecular Imaging: Fundamentals and Applications. Springer-Verlag Berlin & Heidelberg GmbH & Co.K. pp. 550, 552. ISBN 9783642343032. Retrieved 2019-07-08.

Further reading

  • Cohen SN, Chang AC, Boyer HW, Helling RB (November 1973). "Construction of biologically functional bacterial plasmids in vitro". Proceedings of the National Academy of Sciences of the United States of America. 70 (11): 3240–4. Bibcode:1973PNAS...70.3240C. doi:10.1073/pnas.70.11.3240. PMC 427208. PMID 4594039.
  • Rodgers M (June 1975). "The Pandora's box congress". Rolling Stone. Vol. 189. pp. 37–77.
  • Roberts K, Raff M, Alberts B, Walter P, Lewis J, Johnson A (2002). Molecular Biology of the Cell. Garland Science. ISBN 978-0-8153-3218-3.

External links

  •   Media related to Molecular biology at Wikimedia Commons
  • Biochemistry and Molecular Biology at Curlie

January 31, 2023
molecular, biology, biochemical, genetics, redirects, here, scientific, journal, biochemical, genetics, journal, molecular, microbiology, redirects, here, scientific, journal, molecular, microbiology, journal, branch, biology, that, seeks, understand, molecula. Biochemical genetics redirects here For the scientific journal see Biochemical Genetics journal Molecular microbiology redirects here For the scientific journal see Molecular Microbiology journal Molecular biology m e ˈ l ɛ k j ʊ l er is the branch of biology that seeks to understand the molecular basis of biological activity in and between cells including biomolecular synthesis modification mechanisms and interactions 1 2 3 The study of chemical and physical structure of biological macromolecules is known as molecular biology 4 Molecular biology was first described as an approach focused on the underpinnings of biological phenomena uncovering the structures of biological molecules as well as their interactions and how these interactions explain observations of classical biology 5 In 1945 the term molecular biology was used by physicist William Astbury In 1953 Francis Crick James Watson Rosalind Franklin and colleagues working at Medical Research Council unit Cavendish laboratory Cambridge now the MRC Laboratory of Molecular Biology made a double helix model of DNA which changed the entire research scenario They proposed the DNA structure based on previous research done by Rosalind Franklin and Maurice Wilkins This research then lead to finding DNA material in other microorganisms plants and animals 4 Molecular biology is not simply the study of biological molecules and their interactions rather it is also a collection of techniques developed since the field s genesis which have enabled scientists to learn about molecular processes 6 In this way it has both complemented and improved biochemistry and genetics as methods of understanding nature that began before its advent One notable technique which has revolutionized the field is the polymerase chain reaction PCR which was developed in 1983 6 PCR is a reaction which amplifies small quantities of DNA and it is used in many applications across scientific disciplines 7 8 The central dogma of molecular biology describes the process in which DNA is transcribed into RNA which is then translated into protein 2 9 Molecular biology also plays a critical role in the understanding of structures functions and internal controls within individual cells all of which can be used to efficiently target new drugs diagnose disease and better understand cell physiology 10 Some clinical research and medical therapies arising from molecular biology are covered under gene therapy whereas the use of molecular biology or molecular cell biology in medicine is now referred to as molecular medicine Contents 1 History of molecular biology 2 The F Griffith experiment 3 Hershey and Chase experiment 4 Modern molecular biology 5 Relationship to other biological sciences 6 Techniques of molecular biology 6 1 Molecular cloning 6 2 Polymerase chain reaction 6 3 Gel electrophoresis 6 4 The Bradford Assay 6 5 Macromolecule blotting and probing 6 5 1 Southern blotting 6 5 2 Northern blotting 6 5 3 Western blotting 6 5 4 Eastern blotting 6 6 Microarrays 6 7 Allele specific oligonucleotide 7 See also 8 References 9 Further reading 10 External linksHistory of molecular biology EditMain article History of molecular biology Molecular biology sits at the intersection of biochemistry and genetics as these scientific disciplines emerged and evolved in the 20th century it became clear that they both sought to determine the molecular mechanisms which underlie vital cellular functions 11 Advances in molecular biology have been closely related to the development of new technologies and their optimization 12 Molecular biology has been elucidated by the work of many scientists and thus the history of the field depends on an understanding of these scientists and their experiments The field of genetics arose as an attempt to understand the molecular mechanisms of genetic inheritance and the structure of a gene Gregor Mendel pioneered this work in 1866 when he first wrote the laws of genetic inheritance based on his studies of mating crosses in pea plants 13 One such law of genetic inheritance is the law of segregation which states that diploid individuals with two alleles for a particular gene will pass one of these alleles to their offspring 14 Because of his critical work the study of genetic inheritance is commonly referred to as Mendelian genetics 15 A major milestone in molecular biology was the discovery of the structure of DNA This work began in 1869 by Friedrich Miescher a Swiss biochemist who first proposed a structure called nuclein which we now know to be deoxyribonucleic acid or DNA 16 He discovered this unique substance by studying the components of pus filled bandages and noting the unique properties of the phosphorus containing substances 17 Another notable contributor to the DNA model was Phoebus Levene who proposed the polynucleotide model of DNA in 1919 as a result of his biochemical experiments on yeast 18 In 1950 Erwin Chargaff expanded on the work of Levene and elucidated a few critical properties of nucleic acids first the sequence of nucleic acids varies across species 19 Second the total concentration of purines adenine and guanine is always equal to the total concentration of pyrimidines cysteine and thymine 16 This is now known as Chargaff s rule In 1953 James Watson and Francis Crick published the double helical structure of DNA 20 using the X ray crystallography work done by Rosalind Franklin and Maurice Wilkins Watson and Crick described the structure of DNA and conjectured about the implications of this unique structure for possible mechanisms of DNA replication 20 J D Watson and F H C Crick were awarded Nobel prize in 1962 along with Maurice Wilkens for proposing a model of the structure of DNA 4 In 1961 it was demonstrated that when a gene encodes a protein three sequential bases of a gene s DNA specify each successive amino acid of the protein 21 Thus the genetic code is a triplet code where each triplet called a codon specifies a particular amino acid Furthermore it was shown that the codons do not overlap with each other in the DNA sequence encoding a protein and that each sequence is read from a fixed starting point During 1962 1964 through the use of conditional lethal mutants of a bacterial virus 22 fundamental advances were made in our understanding of the functions and interactions of the proteins employed in the machinery of DNA replication DNA repair DNA recombination and in the assembly of molecular structures Diagrammatic representation of Watson and Crick s DNA structure Angle description in DNA structureThe F Griffith experiment Edit Diagrammatic representation of experiment Main article Griffith s experiment In 1928 Fredrick Griffith encountered a virulence property in pneumococcus bacteria which was killing lab rats According to Mendel prevalent at that time gene transfer could occur only from parent to daughter cells only Griffith advanced another theory stating that gene transfer occurring in member of same generation is known as horizontal gene transfer HGT This phenomenon is now referred to as genetic transformation Griffith addressed the Streptococcus pneumoniae bacteria which had two different strains one virulent and smooth and one avirulent and rough The smooth strain had glistering appearance owing to the presence of a type of specific polysaccharide a polymer of glucose and glucuronic acid capsule Due to this polysaccharide layer of bacteria a host s immune system cannot recognize the bacteria and it kills the host The other avirulent rough strain lacks this polysaccharide capsule and has a dull rough appearance Presence or absence of capsule in the strain is known to be genetically determined Smooth and rough strains occur in several different type such as S I S II S III etc and R I R II R III etc respectively All this subtypes of S and R bacteria differ with each other in antigen type they produce 4 Hershey and Chase experiment EditMain article Hershey Chase experiment Hershey and Chase experiment Confirmation that DNA is the genetic material which is cause of infection came from Hershey and Chase experiment They used E coli and bacteriophage for the experiment This experiment is also known as blender experiment as kitchen blender was used as a major piece of apparatus Alfred Hershey and Martha Chase demonstrated that the DNA injected by a phage particle into a bacterium contains all information required to synthesize progeny phage particles They used radioactivity to tag the bacteriophage s protein coat with radioactive sulphur and DNA with radioactive phosphorus into two different test tubes respectively After mixing bacteriophage and E coli into the test tube the incubation period starts in which phage transforms the genetic material in the E coli cells Then the mixture is blended or agitated which separates the phage from E coli cells The whole mixture is centrifuged and the pellet which contains E coli cells was checked and the supernatant was discarded The E coli cells showed radioactive phosphorus which indicated that the transformed material was DNA not the protein coat The transformed DNA gets attached to the DNA of E coli and radioactivity is only seen onto the bacteriophage s DNA This mutated DNA can be passed to the next generation and the theory of Transduction came into existence Transduction is a process in which the bacterial DNA carry the fragment of bacteriophages and pass it on the next generation This is also a type of horizontal gene transfer 4 Modern molecular biology EditIn the early 2020s molecular biology entered a golden age defined by both vertical and horizontal technical development Vertically novel technologies are allowing for real time monitoring of biological processes at the atomic level 23 Molecular biologists today have access to increasingly affordable sequencing data at increasingly higher depths facilitating the development of novel genetic manipulation methods in new non model organisms Likewise synthetic molecular biologists will drive the industrial production of small and macro molecules through the introduction of exogenous metabolic pathways in various prokaryotic and eukaryotic cell lines 24 Horizontally sequencing data is becoming more affordable and used in many different scientific fields This will drive the development of industries in developing nations and increase accessibility to individual researchers Likewise CRISPR Cas9 gene editing experiments can now be conceived and implemented by individuals for under 10 000 in novel organisms which will drive the development of industrial and medical applications 25 Relationship to other biological sciences Edit Schematic relationship between biochemistry genetics and molecular biology The following list describes a viewpoint on the interdisciplinary relationships between molecular biology and other related fields 26 Molecular biology is the study of the molecular underpinnings of the biological phenomena focusing on molecular synthesis modification mechanisms and interactions Biochemistry is the study of the chemical substances and vital processes occurring in living organisms Biochemists focus heavily on the role function and structure of biomolecules such as proteins lipids carbohydrates and nucleic acids 27 Genetics is the study of how genetic differences affect organisms Genetics attempts to predict how mutations individual genes and genetic interactions can affect the expression of a phenotype 28 While researchers practice techniques specific to molecular biology it is common to combine these with methods from genetics and biochemistry Much of molecular biology is quantitative and recently a significant amount of work has been done using computer science techniques such as bioinformatics and computational biology Molecular genetics the study of gene structure and function has been among the most prominent sub fields of molecular biology since the early 2000s Other branches of biology are informed by molecular biology by either directly studying the interactions of molecules in their own right such as in cell biology and developmental biology or indirectly where molecular techniques are used to infer historical attributes of populations or species as in fields in evolutionary biology such as population genetics and phylogenetics There is also a long tradition of studying biomolecules from the ground up or molecularly in biophysics 29 Techniques of molecular biology Edit DNA animation For more extensive list on protein methods see protein methods For more extensive list on nucleic acid methods see nucleic acid methods Molecular cloning Edit Main article Molecular cloning Transduction image Molecular cloning is used to isolate and then transfer a DNA sequence of interest into a plasmid vector 30 This recombinant DNA technology was first developed in the 1960s 31 In this technique a DNA sequence coding for a protein of interest is cloned using polymerase chain reaction PCR and or restriction enzymes into a plasmid expression vector The plasmid vector usually has at least 3 distinctive features an origin of replication a multiple cloning site MCS and a selective marker usually antibiotic resistance Additionally upstream of the MCS are the promoter regions and the transcription start site which regulate the expression of cloned gene This plasmid can be inserted into either bacterial or animal cells Introducing DNA into bacterial cells can be done by transformation via uptake of naked DNA conjugation via cell cell contact or by transduction via viral vector Introducing DNA into eukaryotic cells such as animal cells by physical or chemical means is called transfection Several different transfection techniques are available such as calcium phosphate transfection electroporation microinjection and liposome transfection The plasmid may be integrated into the genome resulting in a stable transfection or may remain independent of the genome and expressed temporarily called a transient transfection 32 33 DNA coding for a protein of interest is now inside a cell and the protein can now be expressed A variety of systems such as inducible promoters and specific cell signaling factors are available to help express the protein of interest at high levels Large quantities of a protein can then be extracted from the bacterial or eukaryotic cell The protein can be tested for enzymatic activity under a variety of situations the protein may be crystallized so its tertiary structure can be studied or in the pharmaceutical industry the activity of new drugs against the protein can be studied 34 Polymerase chain reaction Edit Main article Polymerase chain reaction Polymerase chain reaction PCR is an extremely versatile technique for copying DNA In brief PCR allows a specific DNA sequence to be copied or modified in predetermined ways The reaction is extremely powerful and under perfect conditions could amplify one DNA molecule to become 1 07 billion molecules in less than two hours PCR has many applications including the study of gene expression the detection of pathogenic microorganisms the detection of genetic mutations and the introduction of mutations to DNA 35 The PCR technique can be used to introduce restriction enzyme sites to ends of DNA molecules or to mutate particular bases of DNA the latter is a method referred to as site directed mutagenesis PCR can also be used to determine whether a particular DNA fragment is found in a cDNA library PCR has many variations like reverse transcription PCR RT PCR for amplification of RNA and more recently quantitative PCR which allow for quantitative measurement of DNA or RNA molecules 36 37 Two percent agarose gel in borate buffer cast in a gel tray Gel electrophoresis Edit SDS PAGE Main article Gel electrophoresis Gel electrophoresis is a technique which separates molecules by their size using an agarose or polyacrylamide gel 38 This technique is one of the principal tools of molecular biology The basic principle is that DNA fragments can be separated by applying an electric current across the gel because the DNA backbone contains negatively charged phosphate groups the DNA will migrate through the agarose gel towards the positive end of the current 38 Proteins can also be separated on the basis of size using an SDS PAGE gel or on the basis of size and their electric charge by using what is known as a 2D gel electrophoresis 39 Proteins stained on a PAGE gel using Coomassie blue dye The Bradford Assay Edit Main article The Bradford Assay The Bradford Assay is a molecular biology technique which enables the fast accurate quantitation of protein molecules utilizing the unique properties of a dye called Coomassie Brilliant Blue G 250 40 Coomassie Blue undergoes a visible color shift from reddish brown to bright blue upon binding to protein 40 In its unstable cationic state Coomassie Blue has a background wavelength of 465 nm and gives off a reddish brown color 41 When Coomassie Blue binds to protein in an acidic solution the background wavelength shifts to 595 nm and the dye gives off a bright blue color 41 Proteins in the assay bind Coomassie blue in about 2 minutes and the protein dye complex is stable for about an hour although it s recommended that absorbance readings are taken within 5 to 20 minutes of reaction initiation 40 The concentration of protein in the Bradford assay can then be measured using a visible light spectrophotometer and therefore does not require extensive equipment 41 This method was developed in 1975 by Marion M Bradford and has enabled significantly faster more accurate protein quantitation compared to previous methods the Lowry procedure and the biuret assay 40 Unlike the previous methods the Bradford assay is not susceptible to interference by several non protein molecules including ethanol sodium chloride and magnesium chloride 40 However it is susceptible to influence by strong alkaline buffering agents such as sodium dodecyl sulfate SDS 40 Macromolecule blotting and probing Edit The terms northern western and eastern blotting are derived from what initially was a molecular biology joke that played on the term Southern blotting after the technique described by Edwin Southern for the hybridisation of blotted DNA Patricia Thomas developer of the RNA blot which then became known as the northern blot actually didn t use the term 42 Southern blotting Edit Main article Southern blot Named after its inventor biologist Edwin Southern the Southern blot is a method for probing for the presence of a specific DNA sequence within a DNA sample DNA samples before or after restriction enzyme restriction endonuclease digestion are separated by gel electrophoresis and then transferred to a membrane by blotting via capillary action The membrane is then exposed to a labeled DNA probe that has a complement base sequence to the sequence on the DNA of interest 43 Southern blotting is less commonly used in laboratory science due to the capacity of other techniques such as PCR to detect specific DNA sequences from DNA samples These blots are still used for some applications however such as measuring transgene copy number in transgenic mice or in the engineering of gene knockout embryonic stem cell lines 29 Northern blotting Edit Main article Northern blot Northern blot diagram The northern blot is used to study the presence of specific RNA molecules as relative comparison among a set of different samples of RNA It is essentially a combination of denaturing RNA gel electrophoresis and a blot In this process RNA is separated based on size and is then transferred to a membrane that is then probed with a labeled complement of a sequence of interest The results may be visualized through a variety of ways depending on the label used however most result in the revelation of bands representing the sizes of the RNA detected in sample The intensity of these bands is related to the amount of the target RNA in the samples analyzed The procedure is commonly used to study when and how much gene expression is occurring by measuring how much of that RNA is present in different samples assuming that no post transcriptional regulation occurs and that the levels of mRNA reflect proportional levels of the corresponding protein being produced It is one of the most basic tools for determining at what time and under what conditions certain genes are expressed in living tissues 44 45 Western blotting Edit Main article Western blot A western blot is a technique by which specific proteins can be detected from a mixture of proteins 46 Western blots can be used to determine the size of isolated proteins as well as to quantify their expression 47 In western blotting proteins are first separated by size in a thin gel sandwiched between two glass plates in a technique known as SDS PAGE The proteins in the gel are then transferred to a polyvinylidene fluoride PVDF nitrocellulose nylon or other support membrane This membrane can then be probed with solutions of antibodies Antibodies that specifically bind to the protein of interest can then be visualized by a variety of techniques including colored products chemiluminescence or autoradiography Often the antibodies are labeled with enzymes When a chemiluminescent substrate is exposed to the enzyme it allows detection Using western blotting techniques allows not only detection but also quantitative analysis Analogous methods to western blotting can be used to directly stain specific proteins in live cells or tissue sections 46 48 Eastern blotting Edit Main article Eastern blot The eastern blotting technique is used to detect post translational modification of proteins Proteins blotted on to the PVDF or nitrocellulose membrane are probed for modifications using specific substrates 49 Microarrays Edit Main article DNA microarray source source source source source source A DNA microarray being printed Hybridization of target to probe A DNA microarray is a collection of spots attached to a solid support such as a microscope slide where each spot contains one or more single stranded DNA oligonucleotide fragments Arrays make it possible to put down large quantities of very small 100 micrometre diameter spots on a single slide Each spot has a DNA fragment molecule that is complementary to a single DNA sequence A variation of this technique allows the gene expression of an organism at a particular stage in development to be qualified expression profiling In this technique the RNA in a tissue is isolated and converted to labeled complementary DNA cDNA This cDNA is then hybridized to the fragments on the array and visualization of the hybridization can be done Since multiple arrays can be made with exactly the same position of fragments they are particularly useful for comparing the gene expression of two different tissues such as a healthy and cancerous tissue Also one can measure what genes are expressed and how that expression changes with time or with other factors There are many different ways to fabricate microarrays the most common are silicon chips microscope slides with spots of 100 micrometre diameter custom arrays and arrays with larger spots on porous membranes macroarrays There can be anywhere from 100 spots to more than 10 000 on a given array Arrays can also be made with molecules other than DNA 50 51 52 53 Allele specific oligonucleotide Edit Main article Allele specific oligonucleotide Allele specific oligonucleotide ASO is a technique that allows detection of single base mutations without the need for PCR or gel electrophoresis Short 20 25 nucleotides in length labeled probes are exposed to the non fragmented target DNA hybridization occurs with high specificity due to the short length of the probes and even a single base change will hinder hybridization The target DNA is then washed and the labeled probes that didn t hybridize are removed The target DNA is then analyzed for the presence of the probe via radioactivity or fluorescence In this experiment as in most molecular biology techniques a control must be used to ensure successful experimentation 54 55 In molecular biology procedures and technologies are continually being developed and older technologies abandoned For example before the advent of DNA gel electrophoresis agarose or polyacrylamide the size of DNA molecules was typically determined by rate sedimentation in sucrose gradients a slow and labor intensive technique requiring expensive instrumentation prior to sucrose gradients viscometry was used Aside from their historical interest it is often worth knowing about older technology as it is occasionally useful to solve another new problem for which the newer technique is inappropriate 56 See also EditAstrobiology Central dogma of molecular biology Genetic code Geniom RT Analyzer diagnostic testing instrument Genome Molecular biology institutes Molecular engineering Molecular modeling Protein interaction prediction Protein structure prediction Proteome Cell biologyReferences Edit Alberts B Johnson A Lewis J Morgan D Raff M Roberts K Walter P 2014 Molecular Biology of the Cell Sixth Edition Garland Science pp 1 10 ISBN 978 1 317 56375 4 a b Gannon F February 2002 Molecular biology what s in a name EMBO Reports 3 2 101 doi 10 1093 embo reports kvf039 PMC 1083977 PMID 11839687 Molecular biology Latest research and news Nature www nature com Retrieved 2021 11 07 a b c d e S Verma P 2004 Cell biology genetics molecular biology evolution and ecology S Chand and Company ISBN 81 219 2442 1 OCLC 1045495545 Astbury W T June 1961 Molecular Biology or Ultrastructural Biology Nature 190 4781 1124 Bibcode 1961Natur 190 1124A doi 10 1038 1901124a0 ISSN 1476 4687 PMID 13684868 S2CID 4172248 a b Morange Michel 2016 02 15 History of Molecular Biology eLS Chichester UK John Wiley amp Sons Ltd pp 1 8 doi 10 1002 9780470015902 a0003079 pub3 ISBN 9780470016176 retrieved 2021 11 07 Polymerase Chain Reaction PCR Definitions Qeios 2019 11 26 doi 10 32388 167113 S2CID 94561339 Smithsonian Institution Archives siarchives si edu Retrieved 2021 11 07 Cox Michael M 2015 03 16 Molecular biology principles and practice Doudna Jennifer A O Donnell Michael Biochemist Second ed New York ISBN 978 1 4641 2614 7 OCLC 905380069 Bello Elizabeth A Schwinn Debra A 1996 12 01 Molecular Biology and Medicine A Primer for the Clinician Anesthesiology 85 6 1462 1478 doi 10 1097 00000542 199612000 00029 ISSN 0003 3022 PMID 8968195 S2CID 29581630 Morange Michel June 2021 A history of biology ISBN 978 0 691 18878 2 OCLC 1184123419 Fields Stanley 2001 08 28 The interplay of biology and technology Proceedings of the National Academy of Sciences 98 18 10051 10054 doi 10 1073 pnas 191380098 ISSN 0027 8424 PMC 56913 PMID 11517346 Ellis T H Noel Hofer Julie M I Timmerman Vaughan Gail M Coyne Clarice J Hellens Roger P 2011 11 01 Mendel 150 years on Trends in Plant Science 16 11 590 596 doi 10 1016 j tplants 2011 06 006 ISSN 1360 1385 PMID 21775188 12 3C Mendel s Law of Segregation Biology LibreTexts 2018 07 12 Retrieved 2021 11 18 Mendelian Inheritance Genome gov Retrieved 2021 11 18 a b Discovery of DNA Double Helix Watson and Crick Learn Science at Scitable www nature com Retrieved 2021 11 25 George Wolf 2003 Friedrich Miescher the man who discovered DNA OCLC 907773747 Levene P A 1919 Structure of Yeast Nucleic Acid Journal of Biological Chemistry 43 2 379 382 doi 10 1016 s0021 9258 18 86289 5 ISSN 0021 9258 Chargaff Erwin 1950 Chemical specificity of nucleic acids and mechanism of their enzymatic degradation Experientia 6 6 201 209 doi 10 1007 bf02173653 ISSN 0014 4754 PMID 15421335 S2CID 2522535 a b Watson J D Crick F H C April 1953 Molecular Structure of Nucleic Acids A Structure for Deoxyribose Nucleic Acid Nature 171 4356 737 738 Bibcode 1953Natur 171 737W doi 10 1038 171737a0 ISSN 1476 4687 PMID 13054692 S2CID 4253007 Crick F H C Barnett Leslie Brenner S Watts Tobin R J 1961 General Nature of the Genetic Code for Proteins Nature Springer Science and Business Media LLC 192 4809 1227 1232 Bibcode 1961Natur 192 1227C doi 10 1038 1921227a0 ISSN 0028 0836 PMID 13882203 S2CID 4276146 Epstein R H Bolle A Steinberg C M Kellenberger E Boy de la Tour E et al 1963 01 01 Physiological Studies of Conditional Lethal Mutants of Bacteriophage T4D Cold Spring Harbor Symposia on Quantitative Biology Cold Spring Harbor Laboratory 28 375 394 doi 10 1101 sqb 1963 028 01 053 ISSN 0091 7451 Mojiri Soheil Isbaner Sebastian Muhle Steffen Jang Hongje Bae Albert Johann Gregor Ingo Gholami Azam Gholami Azam Enderlein Jorg 2021 06 01 Rapid multi plane phase contrast microscopy reveals torsional dynamics in flagellar motion Biomedical Optics Express 12 6 3169 3180 doi 10 1364 BOE 419099 ISSN 2156 7085 PMC 8221972 PMID 34221652 van Warmerdam T Molecular Biology Laboratory Resource Yourbiohelper com a href Template Cite web html title Template Cite web cite web a CS1 maint url status link van Warmerdam T Molecular biology laboratory resource Yourbiohelper com a href Template Cite web html title Template Cite web cite web a CS1 maint url status link Lodish H Berk A Zipursky SL Matsudaira P Baltimore D Darnell J 2000 Molecular cell biology 4th ed New York Scientific American Books ISBN 978 0 7167 3136 8 Berg Jeremy 2002 Biochemistry Tymoczko John L Stryer Lubert 5th ed New York W H Freeman ISBN 0 7167 3051 0 OCLC 48055706 Reference Genetics Home Help Me Understand Genetics Genetics Home Reference Retrieved 31 December 2016 a b Tian J ed 2013 Molecular Imaging Fundamentals and Applications Springer Verlag Berlin amp Heidelberg GmbH amp Co K p 542 ISBN 9783642343032 Retrieved 2019 07 08 Foundations of Molecular Cloning Past Present and Future NEB www neb com Retrieved 2021 11 25 Foundations of Molecular Cloning Past Present and Future NEB www neb com Retrieved 2021 11 04 Alberts B Johnson A Lewis J Raff M Roberts K Walter P Isolating Cloning and Sequencing DNA Retrieved 31 December 2016 Lessard Juliane C 1 January 2013 Molecular cloning Laboratory Methods in Enzymology DNA Methods in Enzymology Vol 529 pp 85 98 doi 10 1016 B978 0 12 418687 3 00007 0 ISBN 978 0 12 418687 3 ISSN 1557 7988 PMID 24011038 Kokate C Jalalpure SS Hurakadle PJ 2016 Textbook of Pharmaceutical Biotechnology Expression Cloning Elsevier p 125 ISBN 9788131239872 Retrieved 2019 07 08 Lenstra J A July 1995 The applications of the polymerase chain reaction in the life sciences Cellular and Molecular Biology Noisy Le Grand France 41 5 603 614 ISSN 0145 5680 PMID 7580841 Polymerase Chain Reaction PCR National Center for Biotechnology Information U S National Library of Medicine Retrieved 31 December 2016 Polymerase Chain Reaction PCR Fact Sheet National Human Genome Research Institute NHGRI Retrieved 31 December 2016 a b Lee Pei Yun Costumbrado John Hsu Chih Yuan Kim Yong Hoon 2012 04 20 Agarose Gel Electrophoresis for the Separation of DNA Fragments Journal of Visualized Experiments 62 3923 doi 10 3791 3923 ISSN 1940 087X PMC 4846332 PMID 22546956 Lee PY Costumbrado J Hsu CY Kim YH April 2012 Agarose gel electrophoresis for the separation of DNA fragments Journal of Visualized Experiments 62 doi 10 3791 3923 PMC 4846332 PMID 22546956 a b c d e f Bradford Marion M 1976 05 07 A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein dye binding Analytical Biochemistry 72 1 248 254 doi 10 1016 0003 2697 76 90527 3 ISSN 0003 2697 PMID 942051 S2CID 4359292 a b c Protein determination by the Bradford method www ruf rice edu Retrieved 2021 11 08 Thomas PS September 1980 Hybridization of denatured RNA and small DNA fragments transferred to nitrocellulose Proceedings of the National Academy of Sciences of the United States of America 77 9 5201 5 Bibcode 1980PNAS 77 5201T doi 10 1073 pnas 77 9 5201 PMC 350025 PMID 6159641 Brown T May 2001 Southern blotting Current Protocols in Immunology Chapter 10 Unit 10 6A doi 10 1002 0471142735 im1006as06 ISBN 978 0 471 14273 7 PMID 18432697 S2CID 20686993 Josefsen K Nielsen H 2011 Nielsen H ed RNA methods and protocols Methods in Molecular Biology Vol 703 New York Humana Press pp 87 105 doi 10 1007 978 1 59745 248 9 7 ISBN 978 1 59745 248 9 PMID 21125485 He SL Green R 1 January 2013 Northern blotting Methods in Enzymology 530 75 87 doi 10 1016 B978 0 12 420037 1 00003 8 ISBN 978 0 12 420037 1 PMC 4287216 PMID 24034315 a b Mahmood T Yang PC September 2012 Western blot technique theory and trouble shooting North American Journal of Medical Sciences 4 9 429 34 doi 10 4103 1947 2714 100998 PMC 3456489 PMID 23050259 Western blot Learn Science at Scitable www nature com Retrieved 2021 11 25 Kurien BT Scofield RH April 2006 Western blotting Methods 38 4 283 93 doi 10 1016 j ymeth 2005 11 007 PMID 16483794 via ScienceDirect Subscription may be required or content may be available in libraries Thomas S Thirumalapura N Crossley EC Ismail N Walker DH June 2009 Antigenic protein modifications in Ehrlichia Parasite Immunology 31 6 296 303 doi 10 1111 j 1365 3024 2009 01099 x PMC 2731653 PMID 19493209 Microarrays National Center for Biotechnology Information U S National Library of Medicine Retrieved 31 December 2016 Bumgarner R January 2013 Frederick M Ausubel et al eds Overview of DNA microarrays types applications and their future Current Protocols in Molecular Biology Chapter 22 Unit 22 1 doi 10 1002 0471142727 mb2201s101 ISBN 978 0 471 14272 0 PMC 4011503 PMID 23288464 Govindarajan R Duraiyan J Kaliyappan K Palanisamy M August 2012 Microarray and its applications Journal of Pharmacy amp Bioallied Sciences 4 Suppl 2 S310 2 doi 10 4103 0975 7406 100283 PMC 3467903 PMID 23066278 Tarca AL Romero R Draghici S August 2006 Analysis of microarray experiments of gene expression profiling American Journal of Obstetrics and Gynecology 195 2 373 88 doi 10 1016 j ajog 2006 07 001 PMC 2435252 PMID 16890548 Cheng L Zhang DY eds 2008 Molecular genetic pathology Totowa NJ Humana p 96 ISBN 978 1 59745 405 6 Retrieved 31 December 2016 Leonard DG 2016 Molecular Pathology in Clinical Practice Springer p 31 ISBN 978 3 319 19674 9 Retrieved 31 December 2016 Tian J ed 2013 Molecular Imaging Fundamentals and Applications Springer Verlag Berlin amp Heidelberg GmbH amp Co K pp 550 552 ISBN 9783642343032 Retrieved 2019 07 08 Further reading EditCohen SN Chang AC Boyer HW Helling RB November 1973 Construction of biologically functional bacterial plasmids in vitro Proceedings of the National Academy of Sciences of the United States of America 70 11 3240 4 Bibcode 1973PNAS 70 3240C doi 10 1073 pnas 70 11 3240 PMC 427208 PMID 4594039 Rodgers M June 1975 The Pandora s box congress Rolling Stone Vol 189 pp 37 77 Roberts K Raff M Alberts B Walter P Lewis J Johnson A 2002 Molecular Biology of the Cell Garland Science ISBN 978 0 8153 3218 3 External links Edit Media related to Molecular biology at Wikimedia Commons Biochemistry and Molecular Biology at Curlie Portal Biology Retrieved from https en wikipedia org w index php title Molecular biology amp oldid 1136422102, 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.