The genetic code is the set of rules by which information encoded within genetic material (DNA or mRNA sequences) is translated into proteins by living cells. Translation is accomplished by the ribosome, which links amino acids in an order specified by mRNA, using transfer RNA (tRNA) molecules to carry amino acids and to read the mRNA three nucleotides at a time. The genetic code is highly similar among all organisms and can be expressed in a simple table with 64 entries.
The code defines how sequences of nucleotide triplets, called codons, specify which amino acid will be added next during protein synthesis. With some exceptions, a three-nucleotide codon in a nucleic acid sequence specifies a single amino acid. The vast majority of genes are encoded with a single scheme (see the RNA codon table). That scheme is often referred to as the canonical or standard genetic code, or simply the genetic code, though variant codes (such as in human mitochondria) exist.
While the "genetic code" determines a protein's amino acid sequence, other genomic regions determine when and where these proteins are produced according to various "gene regulatory codes".
- 1 History
- 2 Features
- 3 Standard codon tables
- 4 Alternative genetic codes
- 5 Origin
- 6 References
- 7 Further reading
- 8 External links
Efforts to understand how proteins are encoded began after DNA's structure was discovered in 1953. George Gamow postulated that sets of three bases must be employed to encode the 20 standard amino acids used by living cells to build proteins, which would allow a maximum of 43 = 64 amino acids.
They used a cell-free system to translate a poly-uracil RNA sequence (i.e., UUUUU...) and discovered that the polypeptide that they had synthesized consisted of only the amino acid phenylalanine. They thereby deduced that the codon UUU specified the amino acid phenylalanine.
This was followed by experiments in Severo Ochoa's laboratory that demonstrated that the poly-adenine RNA sequence (AAAAA...) coded for the polypeptide poly-lysine and that the poly-cytosine RNA sequence (CCCCC...) coded for the polypeptide poly-proline. Therefore, the codon AAA specified the amino acid lysine, and the codon CCC specified the amino acid proline. Using various copolymers most of the remaining codons were then determined.
Subsequent work by Har Gobind Khorana identified the rest of the genetic code. Shortly thereafter, Robert W. Holley determined the structure of transfer RNA (tRNA), the adapter molecule that facilitates the process of translating RNA into protein. This work was based upon Ochoa's earlier studies, yielding the latter the Nobel Prize in Physiology or Medicine in 1959 for work on the enzymology of RNA synthesis.
Extending this work, Nirenberg and Philip Leder revealed the code's triplet nature and deciphered its codons. In these experiments, various combinations of mRNA were passed through a filter that contained ribosomes, the components of cells that translate RNA into protein. Unique triplets promoted the binding of specific tRNAs to the ribosome. Leder and Nirenberg were able to determine the sequences of 54 out of 64 codons in their experiments. Khorana, Holley and Nirenberg received the 1968 Nobel for their work.
The three stop codons were named by discoverers Richard Epstein and Charles Steinberg. "Amber" was named after their friend Harris Bernstein, whose last name means "amber" in German. The other two stop codons were named "ochre" and "opal" in order to keep the "color names" theme.
Expanded genetic codes (synthetic biology)
Since 2001, 40 non-natural amino acids have been added into protein by creating a unique codon (recoding) and a corresponding transfer-RNA:aminoacyl – tRNA-synthetase pair to encode it with diverse physicochemical and biological properties in order to be used as a tool to exploring protein structure and function or to create novel or enhanced proteins. 
In 2015 N. Budisa, D. Söll and co-workers reported the full substitution of all 20,899 tryptophan residues (UGG codons) with unnatural thienopyrrole-alanine in the genetic code of the bacterium Escherichia coli.
In 2017 a mouse engineered with an extended genetic code that can produce proteins with unnatural amino acids was reported.
A codon is defined by the initial nucleotide from which translation starts and sets the frame for a run of successive triplets, which is known as an "open reading frame" (ORF). For example, the string GGGAAACCC, if read from the first position, contains the codons GGG, AAA, and CCC; if read from the second position, it contains the codons GGA and AAC; and if read from the third position, GAA and ACC. Every sequence can, thus, be read in its 5' → 3' direction in three reading frames, each producing a possibly distinct amino acid sequence (in the given example, Gly-Lys-Pro, Gly-Asn, or Glu-Thr, respectively). DNA is double-stranded defining six possible reading frames, three in the forward orientation on one strand and three reverse on the opposite strand.:330 Protein-coding frames are defined by a start codon, usually the first AUG codon in the sequence.
Translation starts with a chain-initiation codon or start codon. The start codon alone is not sufficient to begin the process. Nearby sequences such as the Shine-Dalgarno sequence in E. coli and initiation factors are also required to start translation. The most common start codon is AUG, which is read as methionine or, in bacteria, as formylmethionine. Alternative start codons depending on the organism include "GUG" or "UUG"; these codons normally represent valine and leucine, respectively, but as start codons they are translated as methionine or formylmethionine.
The three stop codons have names: UAG is amber, UGA is opal (sometimes also called umber), and UAA is ochre. Stop codons are also called "termination" or "nonsense" codons. They signal release of the nascent polypeptide from the ribosome because no cognate tRNA has anticodons complementary to these stop signals, allowing a release factor to bind to the ribosome instead.
Effect of mutations
During the process of DNA replication, errors occasionally occur in the polymerization of the second strand. These errors, mutations, can affect an organism's phenotype, especially if they occur within the protein coding sequence of a gene. Error rates are typically 1 error in every 10–100 million bases—due to the "proofreading" ability of DNA polymerases.
Missense mutations and nonsense mutations are examples of point mutations that can cause genetic diseases such as sickle-cell disease and thalassemia respectively. Clinically important missense mutations generally change the properties of the coded amino acid residue among basic, acidic, polar or non-polar states, whereas nonsense mutations result in a stop codon.:266
Mutations that disrupt the reading frame sequence by indels (insertions or deletions) of a non-multiple of 3 nucleotide bases are known as frameshift mutations. These mutations usually result in a completely different translation from the original, and likely cause a stop codon to be read, which truncates the protein. These mutations may impair the protein's function and are thus rare in in vivo protein-coding sequences. One reason inheritance of frameshift mutations is rare is that, if the protein being translated is essential for growth under the selective pressures the organism faces, absence of a functional protein may cause death before the organism becomes viable. Frameshift mutations may result in severe genetic diseases such as Tay-Sachs disease.
Although most mutations that change protein sequences are harmful or neutral, some mutations have benefits. These mutations may enable the mutant organism to withstand particular environmental stresses better than wild type organisms, or reproduce more quickly. In these cases a mutation will tend to become more common in a population through natural selection. Viruses that use RNA as their genetic material have rapid mutation rates, which can be an advantage, since these viruses thereby evolve rapidly, and thus evade the immune system defensive responses. In large populations of asexually reproducing organisms, for example, E. coli, multiple beneficial mutations may co-occur. This phenomenon is called clonal interference and causes competition among the mutations.
Degeneracy is the redundancy of the genetic code. This term was given by Bernfield and Nirenberg. The genetic code has redundancy but no ambiguity (see the codon tables below for the full correlation). For example, although codons GAA and GAG both specify glutamic acid (redundancy), neither specifies another amino acid (no ambiguity). The codons encoding one amino acid may differ in any of their three positions. For example, the amino acid leucine is specified by YUR or CUN (UUA, UUG, CUU, CUC, CUA, or CUG) codons (difference in the first or third position indicated using IUPAC notation), while the amino acid serine is specified by UCN or AGY (UCA, UCG, UCC, UCU, AGU, or AGC) codons (difference in the first, second, or third position).:102–117 :521–522 A practical consequence of redundancy is that errors in the third position of the triplet codon cause only a silent mutation or an error that would not affect the protein because the hydrophilicity or hydrophobicity is maintained by equivalent substitution of amino acids; for example, a codon of NUN (where N = any nucleotide) tends to code for hydrophobic amino acids. NCN yields amino acid residues that are small in size and moderate in hydropathy; NAN encodes average size hydrophilic residues. The genetic code is so well-structured for hydropathy that a mathematical analysis (Singular Value Decomposition) of 12 variables (4 nucleotides x 3 positions) yields a remarkable correlation (C = 0.95) for predicting the hydropathy of the encoded amino acid directly from the triplet nucleotide sequence, without translation. Note in the table, below, eight amino acids are not affected at all by mutations at the third position of the codon, whereas in the figure above, a mutation at the second position is likely to cause a radical change in the physicochemical properties of the encoded amino acid.
Codon usage bias
The frequency of codons, also known as codon usage bias, can vary from species to species with functional implications for the control of translation. The following codon usage table is for the human genome.
|Human genome codon frequency table|
A Amino acid. B Fraction of each codon among all those specifying a given amino acid. C Frequency among 40,662,582 codons of 93,487 coding sequences. D Number.
Standard codon tables
RNA codon table
|Amino acids biochemical properties||nonpolar||polar||basic||acidic||Termination: stop codon|
|U||UUU||(Phe/F) Phenylalanine||UCU||(Ser/S) Serine||UAU||(Tyr/Y) Tyrosine||UGU||(Cys/C) Cysteine||U|
|UUA||(Leu/L) Leucine||UCA||UAA[B]||Stop (Ochre)||UGA[B]||Stop (Opal)||A|
|UUG||UCG||UAG[B]||Stop (Amber)||UGG||(Trp/W) Tryptophan||G|
|C||CUU||CCU||(Pro/P) Proline||CAU||(His/H) Histidine||CGU||(Arg/R) Arginine||U|
|A||AUU||(Ile/I) Isoleucine||ACU||(Thr/T) Threonine||AAU||(Asn/N) Asparagine||AGU||(Ser/S) Serine||U|
|AUA||ACA||AAA||(Lys/K) Lysine||AGA||(Arg/R) Arginine||A|
|G||GUU||(Val/V) Valine||GCU||(Ala/A) Alanine||GAU||(Asp/D) Aspartic acid||GGU||(Gly/G) Glycine||U|
|GUA||GCA||GAA||(Glu/E) Glutamic acid||GGA||A|
- A The codon AUG both codes for methionine and serves as an initiation site: the first AUG in an mRNA's coding region is where translation into protein begins.
- B ^ ^ ^ The historical basis for designating the stop codons as amber, ochre and opal is described in an autobiography by Sydney Brenner and in a historical article by Bob Edgar.
|Amino acid||Codons||Compressed||Amino acid||Codons||Compressed|
|Ala / A||GCU, GCC, GCA, GCG||GCN||Leu / L||UUA, UUG, CUU, CUC, CUA, CUG||YUR, CUN|
|Arg / R||CGU, CGC, CGA, CGG, AGA, AGG||CGN, MGR||Lys / K||AAA, AAG||AAR|
|Asn / N||AAU, AAC||AAY||Met / M||AUG|
|Asp / D||GAU, GAC||GAY||Phe / F||UUU, UUC||UUY|
|Cys / C||UGU, UGC||UGY||Pro / P||CCU, CCC, CCA, CCG||CCN|
|Gln / Q||CAA, CAG||CAR||Ser / S||UCU, UCC, UCA, UCG, AGU, AGC||UCN, AGY|
|Glu / E||GAA, GAG||GAR||Thr / T||ACU, ACC, ACA, ACG||ACN|
|Gly / G||GGU, GGC, GGA, GGG||GGN||Trp / W||UGG|
|His / H||CAU, CAC||CAY||Tyr / Y||UAU, UAC||UAY|
|Ile / I||AUU, AUC, AUA||AUH||Val / V||GUU, GUC, GUA, GUG||GUN|
|START||AUG||STOP||UAA, UGA, UAG||UAR, URA|
DNA codon table
Alternative genetic codes
Non-standard amino acids
In some proteins, non-standard amino acids are substituted for standard stop codons, depending on associated signal sequences in the messenger RNA. For example, UGA can code for selenocysteine and UAG can code for pyrrolysine. Selenocysteine became to be seen as the 21st amino acid, and pyrrolysine as the 22nd. Unlike selenocysteine, pyrrolysine-encoded UAG is translated with the participation of a dedicated aminoacyl-tRNA synthetase. Both selenocysteine and pyrrolysine may be present in the same organism. Although the genetic code is normally fixed in an organism, the achaeal prokaryote Acetohalobium arabaticum can expand its genetic code from 20 to 21 amino acids (by including pyrrolysine) under different conditions of growth.
Variations on the standard code were predicted in the 1970s. The first was discovered in 1979, by researchers studying human mitochondrial genes. Many slight variants were discovered thereafter, including various alternative mitochondrial codes. Small variants such as translation of the codon UGA as tryptophan in Mycoplasma species, and translation of CUG as a serine rather than leucine in yeasts of the "CTG clade" (such as Candida albicans). Because viruses must use the same genetic code as their hosts, modifications to the standard genetic code could interfere with viral protein synthesis or functioning. However, viruses such as totiviruses adapted to the host's genetic code modification. In bacteria and archaea, GUG and UUG are common start codons. In rare cases, certain proteins may use alternative start codons. Surprisingly, variations in the interpretation of the genetic code exist also in human nuclear-encoded genes: In 2016, researchers studying the translation of malate dehydrogenase found that in about 4% of the mRNAs encoding this enzyme the stop codon is naturally used to encode the amino acids tryptophan and arginine. This type of recoding is induced by a high-readthrough stop codon context and it is referred to as functional translational readthrough.
Variant genetic codes used by an organism can be inferred by identifying highly conserved genes encoded in that genome, and comparing its codon usage to the amino acids in homologous proteins of other organisms. For example, the program FACIL infers a genetic code by searching which amino acids in homologous protein domains are most often aligned to every codon. The resulting amino acid probabilities for each codon are displayed in a genetic code logo, that also shows the support for a stop codon.
Despite these differences, all known naturally occurring codes are very similar. The coding mechanism is the same for all organisms: three-base codons, tRNA, ribosomes, single direction reading and translating single codons into single amino acids.
List of alternative codons
|List of alternative codons|
The genetic code is a key part of the story of life. The main hypothesis for life's origin is the RNA world hypothesis. Any model for the emergence of genetic code is intimately related to a model of the transfer from ribozymes (RNA enzymes) to proteins as the principal enzymes in cells. In line with the RNA world hypothesis, transfer RNA molecules appear to have evolved before modern aminoacyl-tRNA synthetases, so the latter cannot be part of the explanation of its patterns.
A hypothetical randomly evolved genetic code further motivates a biochemical or evolutionary model for its origin. If amino acids were randomly assigned to triplet codons, there would be 1.5 × 1084 possible genetic codes.:163 This number is found by calculating the number of ways that 21 items (20 amino acids plus one stop) can be placed in 64 bins, wherein each item is used at least once. However, the distribution of codon assignments in the genetic code is nonrandom. In particular, the genetic code clusters certain amino acid assignments.
Amino acids that share the same biosynthetic pathway tend to have the same first base in their codons. This could be an evolutionary relic of an early, simpler genetic code with fewer amino acids that later evolved to code a larger set of amino acids. It could also reflect steric and chemical properties that had another effect on the codon during its evolution. Amino acids with similar physical properties also tend to have similar codons, reducing the problems caused by point mutations and mistranslations.
Given the non-random genetic triplet coding scheme, a tenable hypothesis for the origin of genetic code could address multiple aspects of the codon table, such as absence of codons for D-amino acids, secondary codon patterns for some amino acids, confinement of synonymous positions to third position, the small set of only 20 amino acids (instead of a number approaching 64), and the relation of stop codon patterns to amino acid coding patterns.
Three main hypotheses address the origin of the genetic code. Many models belong to one of them or to a hybrid:
- Random freeze: the genetic code was randomly created. For example, early tRNA-like ribozymes may have had different affinities for amino acids, with codons emerging from another part of the ribozyme that exhibited random variability. Once enough peptides were coded for, any major random change in the genetic code would have been lethal; hence it became "frozen".
- Stereochemical affinity: the genetic code is a result of a high affinity between each amino acid and its codon or anti-codon; the latter option implies that pre-tRNA molecules matched their corresponding amino acids by this affinity. Later during evolution, this matching was gradually replaced with matching by aminoacyl-tRNA synthetases.
- Optimality: the genetic code continued to evolve after its initial creation, so that the current code maximizes some fitness function, usually some kind of error minimization.
Hypotheses have addressed a variety of scenarios:
- Chemical principles govern specific RNA interaction with amino acids. Experiments with aptamers showed that some amino acids have a selective chemical affinity for their codons. Experiments showed that of 8 amino acids tested, 6 show some RNA triplet-amino acid association.
- Biosynthetic expansion. The genetic code grew from a simpler earlier code through a process of "biosynthetic expansion". Primordial life "discovered" new amino acids (for example, as by-products of metabolism) and later incorporated some of these into the machinery of genetic coding. Although much circumstantial evidence has been found to suggest that fewer amino acid types were used in the past, precise and detailed hypotheses about which amino acids entered the code in what order are controversial.
- Natural selection has led to codon assignments of the genetic code that minimize the effects of mutations. A recent hypothesis suggests that the triplet code was derived from codes that used longer than triplet codons (such as quadruplet codons). Longer than triplet decoding would greater codon redundancy and would be more error resistant. This feature could allow accurate decoding absent complex translational machinery such as the ribosome, such as before cells began making ribosomes.
- Information channels: Information-theoretic approaches model the process of translating the genetic code into corresponding amino acids as an error-prone information channel. The inherent noise (that is, the error) in the channel poses the organism with a fundamental question: how can a genetic code be constructed to withstand noise while accurately and efficiently translating information? These "rate-distortion" models suggest that the genetic code originated as a result of the interplay of the three conflicting evolutionary forces: the needs for diverse amino acids, for error-tolerance and for minimal resource cost. The code emerges at a transition when the mapping of codons to amino acids becomes nonrandom. The code's emergence is governed by the topology defined by the probable errors and is related to the map coloring problem.
- Game theory: Models based on signaling games combine elements of game theory, natural selection and information channels. Such models have been used to suggest that the first polypeptides were likely short and had non-enzymatic function. Game theoretic models suggested that the organization of RNA strings into cells may have been necessary to prevent "deceptive" use of the genetic code, i.e. preventing the ancient equivalent of viruses from overwhelming the RNA world.
- Stop codons: Codons for translational stops are also an interesting aspect to the problem of the origin of the genetic code. As an example for addressing stop codon evolution, it has been suggested that the stop codons are such that they are most likely to terminate translation early in the case of a frame shift error. In contrast, some stereochemical molecular models explain the origin of stop codons as "unassignable".
- Shu, Jian-Jun (2017). "A new integrated symmetrical table for genetic codes". BioSystems. 151: 21–26. doi:10.1016/j.biosystems.2016.11.004.
- Turanov AA, Lobanov AV, Fomenko DE, Morrison HG, Sogin ML, Klobutcher LA, Hatfield DL, Gladyshev VN (Jan 2009). "Genetic code supports targeted insertion of two amino acids by one codon". Science. 323 (5911): 259–61. PMC . PMID 19131629. doi:10.1126/science.1164748.
- Crick, Francis (10 July 1990). "Chapter 8: The genetic code". What Mad Pursuit: A Personal View of Scientific Discovery. Basic Books. pp. 89–101. ISBN 0-465-09138-5.
- Nirenberg MW, Matthaei JH (Oct 1961). "The dependence of cell-free protein synthesis in E. coli upon naturally occurring or synthetic polyribonucleotides". Proceedings of the National Academy of Sciences of the United States of America. 47 (10): 1588–602. Bibcode:1961PNAS...47.1588N. PMC . PMID 14479932. doi:10.1073/pnas.47.10.1588.
- Gardner RS, Wahba AJ, Basilio C, Miller RS, Lengyel P, Speyer JF (Dec 1962). "Synthetic polynucleotides and the amino acid code. VII". Proceedings of the National Academy of Sciences of the United States of America. 48 (12): 2087–94. Bibcode:1962PNAS...48.2087G. PMC . PMID 13946552. doi:10.1073/pnas.48.12.2087.
- Wahba AJ, Gardner RS, Basilio C, Miller RS, Speyer JF, Lengyel P (Jan 1963). "Synthetic polynucleotides and the amino acid code. VIII". Proceedings of the National Academy of Sciences of the United States of America. 49 (1): 116–22. Bibcode:1963PNAS...49..116W. PMC . PMID 13998282. doi:10.1073/pnas.49.1.116.
- "The Nobel Prize in Physiology or Medicine 1959" (Press release). The Royal Swedish Academy of Science. 1959. Retrieved 2010-02-27.
The Nobel Prize in Physiology or Medicine 1959 was awarded jointly to Severo Ochoa and Arthur Kornberg 'for their discovery of the mechanisms in the biological synthesis of ribonucleic acid and deoxyribonucleic acid'.
- Nirenberg M, Leder P, Bernfield M, Brimacombe R, Trupin J, Rottman F, O'Neal C (May 1965). "RNA codewords and protein synthesis, VII. On the general nature of the RNA code". Proceedings of the National Academy of Sciences of the United States of America. 53 (5): 1161–8. Bibcode:1965PNAS...53.1161N. PMC . PMID 5330357. doi:10.1073/pnas.53.5.1161.
- "The Nobel Prize in Physiology or Medicine 1968" (Press release). The Royal Swedish Academy of Science. 1968. Retrieved 2010-02-27.
The Nobel Prize in Physiology or Medicine 1968 was awarded jointly to Robert W. Holley, Har Gobind Khorana and Marshall W. Nirenberg 'for their interpretation of the genetic code and its function in protein synthesis'.
- Edgar B (Oct 2004). "The genome of bacteriophage T4: an archeological dig". Genetics. 168 (2): 575–82. PMC . PMID 15514035.
- Xie J, Schultz PG (December 2005). "Adding amino acids to the genetic repertoire". Current Opinion in Chemical Biology. 9 (6): 548–54. PMID 16260173. doi:10.1016/j.cbpa.2005.10.011.
- Wang Q, Parrish AR, Wang L (March 2009). "Expanding the genetic code for biological studies". Chemistry & Biology. 16 (3): 323–36. PMC . PMID 19318213. doi:10.1016/j.chembiol.2009.03.001.
- Simon M (7 January 2005). Emergent Computation: Emphasizing Bioinformatics. Springer Science & Business Media. pp. 105–106. ISBN 978-0-387-22046-8.
- Hoesl, M. G.; Oehm, S.; Durkin, P.; Darmon, E.; Peil, L.; Aerni, H.-R.; Rappsilber, J.; Rinehart, J.; Leach, D.; Söll, D.; Budisa, N. (2015). "Chemical evolution of a bacterial proteome". Angewandte Chemie International Edition. 54: 10030–10034. PMC . doi:10.1002/anie.201502868. NIHMSID: NIHMS711205
- "First stable semisynthetic organism created | KurzweilAI". www.kurzweilai.net. February 3, 2017. Retrieved 2017-02-09.
- Zhang Y, Lamb BM, Feldman AW, Zhou AX, Lavergne T, Li L, Romesberg FE (February 2017). "A semisynthetic organism engineered for the stable expansion of the genetic alphabet". Proceedings of the National Academy of Sciences of the United States of America. 114 (6): 1317–1322. PMC . PMID 28115716. doi:10.1073/pnas.1616443114.
- Han S, Yang A, Lee S, Lee HW, Park CB, Park HS (February 2017). "Expanding the genetic code of Mus musculus". Nature Communications. 8: 14568. PMC . PMID 28220771. doi:10.1038/ncomms14568.
- King RC, Mulligan P, Stansfield W (10 January 2013). A Dictionary of Genetics. OUP USA. p. 608. ISBN 978-0-19-976644-4.
- Touriol C, Bornes S, Bonnal S, Audigier S, Prats H, Prats AC, Vagner S (2003). "Generation of protein isoform diversity by alternative initiation of translation at non-AUG codons". Biology of the Cell / Under the Auspices of the European Cell Biology Organization. 95 (3–4): 169–78. PMID 12867081. doi:10.1016/S0248-4900(03)00033-9.
- Maloy S (2003-11-29). "How nonsense mutations got their names". Microbial Genetics Course. San Diego State University. Retrieved 2010-03-10.
- References for the image are found in Wikimedia Commons page at: Commons:File:Notable mutations.svg#References.
- Griffiths AJ, Miller JH, Suzuki DT, Lewontin RC, et al., eds. (2000). "Spontaneous mutations". An Introduction to Genetic Analysis (7th ed.). New York: W. H. Freeman. ISBN 0-7167-3520-2.
- Freisinger E, Grollman AP, Miller H, Kisker C (Apr 2004). "Lesion (in)tolerance reveals insights into DNA replication fidelity". The EMBO Journal. 23 (7): 1494–505. PMC . PMID 15057282. doi:10.1038/sj.emboj.7600158.
- (Boillée 2006, p. 39)
- Chang JC, Kan YW (Jun 1979). "beta 0 thalassemia, a nonsense mutation in man". Proceedings of the National Academy of Sciences of the United States of America. 76 (6): 2886–9. Bibcode:1979PNAS...76.2886C. PMC . PMID 88735. doi:10.1073/pnas.76.6.2886.
- Boillée S, Vande Velde C, Cleveland DW (Oct 2006). "ALS: a disease of motor neurons and their nonneuronal neighbors". Neuron. 52 (1): 39–59. PMID 17015226. doi:10.1016/j.neuron.2006.09.018.
- Isbrandt D, Hopwood JJ, von Figura K, Peters C (1996). "Two novel frameshift mutations causing premature stop codons in a patient with the severe form of Maroteaux-Lamy syndrome". Human Mutation. 7 (4): 361–3. PMID 8723688. doi:10.1002/(SICI)1098-1004(1996)7:4<361::AID-HUMU12>3.0.CO;2-0.
- Crow JF (1993). "How much do we know about spontaneous human mutation rates?". Environmental and Molecular Mutagenesis. 21 (2): 122–9. PMID 8444142. doi:10.1002/em.2850210205.
- Lewis R (2005). Human Genetics: Concepts and Applications (6th ed.). Boston, Mass: McGraw Hill. pp. 227–228. ISBN 0-07-111156-5.
- Sawyer SA, Parsch J, Zhang Z, Hartl DL (Apr 2007). "Prevalence of positive selection among nearly neutral amino acid replacements in Drosophila". Proceedings of the National Academy of Sciences of the United States of America. 104 (16): 6504–10. Bibcode:2007PNAS..104.6504S. PMC . PMID 17409186. doi:10.1073/pnas.0701572104.
- Bridges KR (2002). "Malaria and the Red Cell". Harvard. Archived from the original on 27 November 2011.
- Drake JW, Holland JJ (Nov 1999). "Mutation rates among RNA viruses". Proceedings of the National Academy of Sciences of the United States of America. 96 (24): 13910–3. Bibcode:1999PNAS...9613910D. PMC . PMID 10570172. doi:10.1073/pnas.96.24.13910.
- Holland J, Spindler K, Horodyski F, Grabau E, Nichol S, VandePol S (Mar 1982). "Rapid evolution of RNA genomes". Science. 215 (4540): 1577–85. Bibcode:1982Sci...215.1577H. PMID 7041255. doi:10.1126/science.7041255.
- de Visser JA, Rozen DE (Apr 2006). "Clonal interference and the periodic selection of new beneficial mutations in Escherichia coli". Genetics. 172 (4): 2093–100. PMC . PMID 16489229. doi:10.1534/genetics.105.052373.
- Watson, James D. (2008). Molecular Biology of the Gene. Pearson/Benjamin Cummings. ISBN 978-0-8053-9592-1.
- Michel-Beyerle, Maria Elisabeth (1990). Reaction centers of photosynthetic bacteria: Feldafing-II-Meeting. Springer-Verlag. ISBN 978-3-540-53420-4.
- Füllen G, Youvan DC (1994). "Genetic Algorithms and Recursive Ensemble Mutagenesis in Protein Engineering". Complexity International 1.
- "Codon usage table".
- Nakamoto T (March 2009). "Evolution and the universality of the mechanism of initiation of protein synthesis". Gene. 432 (1–2): 1–6. PMID 19056476. doi:10.1016/j.gene.2008.11.001.
- Brenner S. A Life in Science (2001) Published by Biomed Central Limited ISBN 0-9540278-0-9 see pages 101-104
- Edgar B (2004). "The genome of bacteriophage T4: an archeological dig". Genetics. 168 (2): 575–82. PMC . PMID 15514035. see pages 580-581
- Elzanowski A, Ostell J (2008-04-07). "The Genetic Codes". National Center for Biotechnology Information (NCBI). Retrieved 2010-03-10.
- Krzycki JA (Dec 2005). "The direct genetic encoding of pyrrolysine". Current Opinion in Microbiology. 8 (6): 706–12. PMID 16256420. doi:10.1016/j.mib.2005.10.009.
- Zhang Y, Baranov PV, Atkins JF, Gladyshev VN (May 2005). "Pyrrolysine and selenocysteine use dissimilar decoding strategies". The Journal of Biological Chemistry. 280 (21): 20740–51. PMID 15788401. doi:10.1074/jbc.M501458200.
- Prat L, Heinemann IU, Aerni HR, Rinehart J, O'Donoghue P, Söll D (Dec 2012). "Carbon source-dependent expansion of the genetic code in bacteria". Proceedings of the National Academy of Sciences of the United States of America. 109 (51): 21070–5. Bibcode:2012PNAS..10921070P. PMC . PMID 23185002. doi:10.1073/pnas.1218613110.
- Crick FH, Orgel LE (1973). "Directed panspermia". Icarus. 19 (3): 341–6, 344. Bibcode:1973Icar...19..341C. doi:10.1016/0019-1035(73)90110-3.
It is a little surprising that organisms with somewhat different codes do not coexist.(Further discussion)
- Barrell BG, Bankier AT, Drouin J (1979). "A different genetic code in human mitochondria". Nature. 282 (5735): 189–194. PMID 226894. doi:10.1038/282189a0. ()
- Jukes TH, Osawa S (Dec 1990). "The genetic code in mitochondria and chloroplasts". Experientia. 46 (11–12): 1117–26. PMID 2253709. doi:10.1007/BF01936921.
- Fitzpatrick DA, Logue ME, Stajich JE, Butler G (1 January 2006). "A fungal phylogeny based on 42 complete genomes derived from supertree and combined gene analysis". BMC Evolutionary Biology. 6: 99. PMC . PMID 17121679. doi:10.1186/1471-2148-6-99.
- Santos MA, Tuite MF (May 1995). "The CUG codon is decoded in vivo as serine and not leucine in Candida albicans". Nucleic Acids Research. 23 (9): 1481–6. PMC . PMID 7784200. doi:10.1093/nar/23.9.1481.
- Butler G, Rasmussen MD, Lin MF, et al. (Jun 2009). "Evolution of pathogenicity and sexual reproduction in eight Candida genomes". Nature. 459 (7247): 657–62. Bibcode:2009Natur.459..657B. PMC . PMID 19465905. doi:10.1038/nature08064.
- Witzany G (2016). "Crucial steps to life: From chemical reactions to code using agents". Biosystems. 140: 49–57. PMID 26723230. doi:10.1016/j.biosystems.2015.12.007.
- Taylor DJ, Ballinger MJ, Bowman SM, Bruenn JA (2013). "Virus-host co-evolution under a modified nuclear genetic code". PeerJ. 1: e50. PMC . PMID 23638388. doi:10.7717/peerj.50.
- Hofhuis J, Schueren F, Nötzel C, Lingner T, Gärtner J, Jahn O, Thoms S (2016). "The functional readthrough extension of malate dehydrogenase reveals a modification of the genetic code". Open Biol. 6 (11): 160246. PMC . PMID 27881739. doi:10.1098/rsob.160246.
- Schueren F, Lingner T, George R, Hofhuis J, Gartner J, Thoms S (2014). "Peroxisomal lactate dehydrogenase is generated by translational readthrough in mammals". eLife. 3: e03640. PMC . PMID 25247702. doi:10.7554/eLife.03640.
- F. Schueren und S. Thoms (2016). "Functional Translational Readthrough: A Systems Biology Perspective". PLOS Genetics. 12 (8): e1006196. PMC . PMID 27490485. doi:10.1371/journal.pgen.1006196.
- Dutilh BE, Jurgelenaite R, Szklarczyk R, van Hijum SA, Harhangi HR, Schmid M, de Wild B, Françoijs KJ, Stunnenberg HG, Strous M, Jetten MS, Op den Camp HJ, Huynen MA (Jul 2011). "FACIL: Fast and Accurate Genetic Code Inference and Logo". Bioinformatics. 27 (14): 1929–33. PMC . PMID 21653513. doi:10.1093/bioinformatics/btr316.
- Ribas de Pouplana L, Turner RJ, Steer BA, Schimmel P (Sep 1998). "Genetic code origins: tRNAs older than their synthetases?". Proceedings of the National Academy of Sciences of the United States of America. 95 (19): 11295–300. Bibcode:1998PNAS...9511295D. PMC . PMID 9736730. doi:10.1073/pnas.95.19.11295.
- Yarus, Michael (2010). Life from an RNA World: The Ancestor Within. Harvard University Press. ISBN 978-0-674-05075-4.
- "Mathematica function for # possible arrangements of items in bins? - Online Technical Discussion Groups—Wolfram Community". community.wolfram.com. Retrieved 2017-02-03.
- Freeland SJ, Hurst LD (Sep 1998). "The genetic code is one in a million". Journal of Molecular Evolution. 47 (3): 238–48. PMID 9732450. doi:10.1007/PL00006381.
- Taylor FJ, Coates D (1989). "The code within the codons". Bio Systems. 22 (3): 177–87. PMID 2650752. doi:10.1016/0303-2647(89)90059-2.
- Di Giulio M (Oct 1989). "The extension reached by the minimization of the polarity distances during the evolution of the genetic code". Journal of Molecular Evolution. 29 (4): 288–93. PMID 2514270. doi:10.1007/BF02103616.
- Wong JT (Feb 1980). "Role of minimization of chemical distances between amino acids in the evolution of the genetic code". Proceedings of the National Academy of Sciences of the United States of America. 77 (2): 1083–6. Bibcode:1980PNAS...77.1083W. PMC . PMID 6928661. doi:10.1073/pnas.77.2.1083.
- Erives A (Aug 2011). "A model of proto-anti-codon RNA enzymes requiring L-amino acid homochirality". Journal of Molecular Evolution. 73 (1–2): 10–22. PMC . PMID 21779963. doi:10.1007/s00239-011-9453-4.
- Freeland SJ, Knight RD, Landweber LF, Hurst LD (Apr 2000). "Early fixation of an optimal genetic code". Molecular Biology and Evolution. 17 (4): 511–18. PMID 10742043. doi:10.1093/oxfordjournals.molbev.a026331.
- Crick FH (Dec 1968). "The origin of the genetic code". Journal of Molecular Evolution. 38 (3): 367–79. PMID 4887876. doi:10.1016/0022-2836(68)90392-6.
- Hopfield JJ (1978). "Origin of the genetic code: a testable hypothesis based on tRNA structure, sequence, and kinetic proofreading". PNAS. 75 (9): 4334–4338. PMC . PMID 279919. doi:10.1073/pnas.75.9.4334.
- Yarus M, Widmann JJ, Knight R (Nov 2009). "RNA-amino acid binding: a stereochemical era for the genetic code". Journal of Molecular Evolution. 69 (5): 406–29. PMID 19795157. doi:10.1007/s00239-009-9270-1.
- Knight RD, Freeland SJ, Landweber LF (Jun 1999). "Selection, history and chemistry: the three faces of the genetic code". Trends in Biochemical Sciences. 24 (6): 241–7. PMID 10366854. doi:10.1016/S0968-0004(99)01392-4.
- Knight RD, Landweber LF (Sep 1998). "Rhyme or reason: RNA-arginine interactions and the genetic code". Chemistry & Biology. 5 (9): R215–20. PMID 9751648. doi:10.1016/S1074-5521(98)90001-1.
- Sengupta S, Higgs PG (2015). "Pathways of genetic code evolution in ancient and modern organisms". Journal of Molecular Evolution. 80 (5–6): 229–243. PMID 26054480. doi:10.1007/s00239-015-9686-8.
- Brooks DJ, Fresco JR, Lesk AM, Singh M (Oct 2002). "Evolution of amino acid frequencies in proteins over deep time: inferred order of introduction of amino acids into the genetic code". Molecular Biology and Evolution. 19 (10): 1645–55. PMID 12270892. doi:10.1093/oxfordjournals.molbev.a003988.
- Amirnovin R (May 1997). "An analysis of the metabolic theory of the origin of the genetic code". Journal of Molecular Evolution. 44 (5): 473–6. PMID 9115171. doi:10.1007/PL00006170.
- Ronneberg TA, Landweber LF, Freeland SJ (Dec 2000). "Testing a biosynthetic theory of the genetic code: fact or artifact?". Proceedings of the National Academy of Sciences of the United States of America. 97 (25): 13690–5. Bibcode:2000PNAS...9713690R. PMC . PMID 11087835. doi:10.1073/pnas.250403097.
- Freeland SJ, Wu T, Keulmann N (Oct 2003). "The case for an error minimizing standard genetic code". Origins of Life and Evolution of the Biosphere. 33 (4–5): 457–77. PMID 14604186. doi:10.1023/A:1025771327614.
- Baranov PV, Venin M, Provan G (2009). Gemmell NJ, ed. "Codon size reduction as the origin of the triplet genetic code". PLOS ONE. 4 (5): e5708. Bibcode:2009PLoSO...4.5708B. PMC . PMID 19479032. doi:10.1371/journal.pone.0005708.
- Tlusty T (Nov 2007). "A model for the emergence of the genetic code as a transition in a noisy information channel". Journal of Theoretical Biology. 249 (2): 331–42. PMID 17826800. doi:10.1016/j.jtbi.2007.07.029.
- Sonneborn TM (1965). Bryson V, Vogel H, eds. Evolving genes and proteins. New York: Academic Press. pp. 377–397.
- Tlusty T (Feb 2008). "Rate-distortion scenario for the emergence and evolution of noisy molecular codes". Physical Review Letters. 100 (4): 048101. Bibcode:2008PhRvL.100d8101T. PMID 18352335. arXiv: . doi:10.1103/PhysRevLett.100.048101.
- Sella G, Ardell DH (Sep 2006). "The coevolution of genes and genetic codes: Crick's frozen accident revisited". Journal of Molecular Evolution. 63 (3): 297–313. PMID 16838217. doi:10.1007/s00239-004-0176-7.
- Tlusty T (Sep 2010). "A colorful origin for the genetic code: information theory, statistical mechanics and the emergence of molecular codes". Physics of Life Reviews. 7 (3): 362–76. Bibcode:2010PhLRv...7..362T. PMID 20558115. arXiv: . doi:10.1016/j.plrev.2010.06.002.
- Jee J, Sundstrom A, Massey SE, Mishra B (Nov 2013). "What can information-asymmetric games tell us about the context of Crick's 'frozen accident'?". Journal of the Royal Society, Interface / the Royal Society. 10 (88): 20130614. PMC . PMID 23985735. doi:10.1098/rsif.2013.0614.
- Itzkovitz S, Alon U (2007). "The genetic code is nearly optimal for allowing additional information within protein-coding sequences". Genome Research. 17 (4): 405–412. PMC . PMID 17293451. doi:10.1101/gr.5987307.
- Griffiths AJ, Miller JH, Suzuki DT, Lewontin RC, Gilbert WM (1999). An Introduction to genetic analysis (7th ed.). San Francisco: W.H. Freeman. ISBN 0-7167-3771-X.
- Alberts B, Johnson A, Lewis J, Raff M, Roberts K, Walter P (2002). Molecular biology of the cell (4th ed.). New York: Garland Science. ISBN 0-8153-3218-1.
- Lodish HF, Berk A, Zipursky SL, Matsudaira P, Baltimore D, Darnell JE (2000). Molecular cell biology (4th ed.). San Francisco: W.H. Freeman. ISBN 0-7167-3706-X.
- Caskey CT, Leder P (Apr 2014). "The RNA code: nature's Rosetta Stone". Proceedings of the National Academy of Sciences of the United States of America. 111 (16): 5758–9. Bibcode:2014PNAS..111.5758C. PMC . PMID 24756939. doi:10.1073/pnas.1404819111.
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