Molecular Clock

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Information about Molecular Clock

Part of the Biology series on

Evolution

Mechanisms and processes

Adaptation
Genetic drift
Gene flow
Mutation
Natural selection
Speciation

Research and history

Evidence
History
Modern synthesis
Social effect / Objections

Evolutionary biology fields

Ecological genetics
Evolutionary development
Human evolution
Molecular evolution
Evolutionary history of life
Phylogenetics
Population genetics

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The molecular clock (based on the molecular clock hypothesis (MCH)) is a technique in genetics to date when two species diverged. Elapsed time is deduced by applying a time scale to the number of differences measured between the species' DNA sequences or proteins. It is sometimes called a gene clock or evolutionary clock.

Early discovery

The notion of the existence of a so-called "molecular clock" was first attributed to Emile Zuckerkandl and Linus Pauling who, in 1962, noticed that the number of amino acid differences in hemoglobin between lineages scales roughly with divergence times, as estimated from fossil evidence^[1]. They generalized this observation to assert that the rate of evolutionary change of any specified protein was approximately constant over time and over different lineages.

Later Allan Wilson and Vincent Sarich built upon this work and the work of Motoo Kimura observed and formalized that rare spontaneous errors in DNA replication cause the mutations that drive molecular evolution, and that the accumulation of evolutionarily "neutral" differences between two sequences could be used to measure time, if the error rate of DNA replication could be calibrated.^[2]^[3] One method of calibrating the error rate was to use as references pairs of groups of living species whose date of speciation was already known from the fossil record.

Calibration

Originally, it was assumed that the DNA replication error rate was constant – not just over time, but across all species and every part of a genome that you might want to compare. Because the enzymes that replicate DNA differ only very slightly between species, the assumption might have seemed reasonable a priori. It is fundamentally flawed logically however, because the strength of natural selection is not uniform in time, space, and across taxa. Had either Pauling or Zuckerkandl been evolutionary biologists rather than in vitro biologists (or in Pauling's case, not a biologist at all), this error would probably have caught their attention. But there was simply insufficient overlap between the fields of evolutionary and molecular biology in their day to bring this problem to widespread notice. Thus only as molecular evidence accumulated, the constant-rate assumption has proven false. Without the constant-rate assumption, the long-held molecular clock explanation of the molecular equidistance phenomenon becomes untenable. While the MCH cannot be blindly assumed to be true, individual molecular clocks can be tested for accuracy and utilized in many cases. In general terms, they need to be calibrated against material evidence such as fossils before firm conclusions can be based on them (see also Lovette^[4]).

Since at least the early 1990s, examples of non-uniform rates of molecular evolution have been described. It is known for many taxa that there is no uniform rate of molecular evolution^[5] , not even over comparatively short periods of evolutionary time (for example mockingbirds^[6] ). Tube-nosed seabirds apparently have a molecular clock that on average runs at half speed compared to many other birds^[7] , possibly due to long generation times, whereas many turtles have a molecular clock running at one-eighth the speed it does in small mammals or even slower^[8]. Effects of small population size are also likely to confound molecular clock analyses; cheetahs for example, having gone through at least 2 population bottlenecks, could not be adequately studied based on a molecular clock model alone. Researchers like Ayala and the anthropologist Jeffrey H. Schwartz in 2006 have more fundamentally challenged the molecular clock hypothesis.^[9]^[10] According to Ayala's 1999 study, 5 factors combine to invalidate the standard molecular clock model:

Changing generation times (A mutation generally becomes fixed only from one generation to another. The shorter this timespan is, the more mutations can become fixed)
Population size (Apart from effects of small population size, genetic diversity will "bottom out" as populations become larger as the fitness advantage of any one mutation becomes smaller)
Species-specific differences (due to differing metabolism, ecology, evolutionary history,...)
Evolving functions of the encoded protein (can be ameliorated by utilizing non-coding DNA sequences or emphasizing silent mutations)
Changes in the intensity of natural selection

Molecular clock users have developed workaround solutions using a number of statistical approaches including maximum likelihood techniques and later Bayesian modeling. In particular, models that take into account rate variation across lineages have been proposed in order to obtain better estimates of divergence times (and other parameters that may be estimated from substitution rates, such as effective population size.) These models are called relaxed molecular clocks^[11] because they represent an intermediate position between the 'strict' molecular clock hypothesis and Felsenstein's many-rates model and are made possible through MCMC techniques that explore a weighted range of tree topologies and simultaneously estimate parameters of the chosen substitution model. It must be remembered that these are still based on statistical inference and not on direct evidence and that therefore, strictly speaking even a relaxed molecular clock can only support but never prove a scientific hypothesis. This problem is approached by using the fossil record, which quite often is good and well-documented enough to provide hard evidence, to calibrate the molecular clock accordingly. Alternatively, for viral phylogenetics and ancient DNA studies, two areas of evolutionary biology where it is possible to sample sequences over an evolutionary timescale, the dates of the sequence themselves can be used to calibrate the molecular clock.

Uses

The molecular clock technique is an important tool in molecular systematics, the use of molecular genetics information to determine the correct scientific classification of organisms.

Knowledge of approximately-constant rate of molecular evolution in particular sets of lineages also facilitates establishing the dates of phylogenetic events not documented by fossils, such as the divergence of living taxa and the formation of the phylogenetic tree. But in these cases - especially over long stretches of time - the MCH can be considered null and void for practical purposes; such estimates are inevitably very crude and may be off by 50% or more.

External links

References

1. ^ Zuckerkandl, E. and Pauling, L.B. (1962). "Molecular disease, evolution, and genetic heterogeneity", in Kasha, M. and Pullman, B (editors): Horizons in Biochemistry. Academic Press, New York, 189–225.
2. ^ Kimura, Motoo (1968). "Evolutionary rate at the molecular level". Nature 217: 624-626.
3. ^ Sarich, V.M. and Wilson, A.C. (1967). "Immunological time scale for hominid evolution". Science 158 (3805): 1200-1203.
4. ^ Lovette, I.J. (2004). "Mitochondrial dating and mixed support for the "2% Rule" in birds". Auk 121 (1): 1-6.
5. ^ Douzery, E.J.P., Delsuc, F., Stanhope, M.J. and Huchon, D. (2003). "Local molecular clocks in three nuclear genes: divergence times for rodents and other mammals, and incompatibility among fossil calibrations". Journal of Molecular Evolution 57: S201-S213.
6. ^ Hunt, J.S., Bermingham, E., and Ricklefs, R.E. (2001). "Molecular systematics and biogeography of Antillean thrashers, tremblers, and mockingbirds (Aves: Mimidae)". Auk 118 (1): 35–55.
7. ^ Rheindt, F. E. and Austin, J. (2005). "Major analytical and conceptual shortcomings in a recent taxonomic revision of the Procellariiformes - A reply to Penhallurick and Wink (2004)". Emu 105 (2): 181-186.
8. ^ Avise, J.C., Bowen, W., Lamb, T., Meylan, A.B. and Bermingham, E. (1992). "Mitochondrial DNA Evolution at a Turtle's Pace: Evidence for Low Genetic Variability and Reduced Microevolutionary Rate in the Testudines". Molecular Biology and Evolution 9 (3): 457-473.
9. ^ Ayala, F.J. (1999). "Molecular clock mirages". BioEssays 21 (1): 71-75.BioEssays&rft.date=1999&rft.volume=21&rft.issue=1&rft.au=Ayala,%20F.J.&rft.pages=71-75&rft_id=http%3A%2F%2Fwww3.interscience.wiley.com%2Fcgi-bin%2Fabstract%2F60000186%2FABSTRACT%3FCRETRY%3D1%26SRETRY%3D0">
10. ^ Schwartz, J. H. and Maresca, B. (2006). "Do Molecular Clocks Run at All? A Critique of Molecular Systematics". Biological Theory 1: 357-371.
11. ^ Drummond, A.J., Ho, S.Y.W., Phillips, M.J. and Rambaut A. (2006). "". PLoS Biology 4 (5): e88.

Biology (from Greek: βίος, bio, "life"; and λόγος, logos, "knowledge"), also referred to as the biological sciences, is the scientific study of life.
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An adaptation is a positive characteristic of an organism that has been favored by natural selection.^[1] The concept is central to biology, particularly in evolutionary biology.
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In population genetics, genetic drift (or more precisely allelic drift) is the statistical effect that results from the influence that chance has on the survival of alleles (variants of a gene).
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In population genetics, gene flow (also known as gene migration) is the transfer of alleles of genes from one population to another.
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mutations are changes to the base pair sequence of the genetic material of an organism. Mutations can be caused by copying errors in the genetic material during cell division, by exposure to ultraviolet or ionizing radiation, chemical mutagens, or viruses, or can occur deliberately
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Natural selection is the process by which favorable traits that are heritable become more common in successive generations of a population of reproducing organisms, and unfavorable traits that are heritable become less
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Speciation is the evolutionary process by which new biological species arise. There are four modes of natural speciation, based on the extent to which speciating populations are geographically isolated from one another:
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evidence of the theory of evolution provides a wealth of information on the natural processes by which the variety of life on Earth developed.

Fossils are important for estimating when various lineages developed.
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Evolutionary thought has roots in antiquity as philosophical ideas known to the Greeks, Romans, Indians, Chinese and Muslims. Until the 18th century, however, Western biological thought was dominated by essentialism, the idea that living forms are static and unchanging in time.
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The modern evolutionary synthesis refers to a set of ideas from several biological specialities that were brought together to form a unified theory of evolution accepted by the great majority of working biologists.
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The social effects of evolutionary thought have been considerable. As the scientific explanation of life's diversity has developed, it has often displaced alternative, sometimes very widely held, explanations.
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There have been numerous objections to evolution since alternative evolutionary ideas came to be hotly debated around the start of the nineteenth century.
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Evolutionary biology is a sub-field of biology concerned with the origin and descent of species, as well as their change, multiplication, and diversity over time.
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For the book see Ecological Genetics (book)

Ecological genetics is the study of genetics in the context of the interactions among organisms and between the organisms and their environment.
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Evolutionary developmental biology (evolution of development or informally, evo-devo) is a field of biology that compares the developmental processes of different animals and plants in an attempt to determine the ancestral relationship between organisms and how
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Human evolution is the part of biological evolution concerning the emergence of humans as a distinct species from other apes. It is the subject of a broad scientific inquiry that seeks to understand and describe how this change and development occurred.
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Molecular evolution is the process of evolution at the scale of DNA, RNA, and proteins. Molecular evolution emerged as a scientific field in the 1960s as researchers from molecular biology, evolutionary biology and population genetics sought to understand recent discoveries on the
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The evolutionary history of life and the origin of life are fields of ongoing geological and biological research. Although it is not necessary to understand the origin of life on earth to accept evolution by natural
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phylogenetics (Greek: phyle = tribe, race and genetikos = relative to birth, from genesis = birth) is the study of evolutionary relatedness among various groups of organisms (e.g., species, populations).
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Population genetics is the study of the allele frequency distribution and change under the influence of the four evolutionary forces: natural selection, genetic drift, mutation and gene flow. It also takes account of population subdivision and population structure in space.
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Genetics is the science of heredity and variation in living organisms.^[1]^[2] Knowledge of the inheritance of characteristics has been implicitly used since prehistoric times for improving crop plants and animals through selective breeding.
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species is one of the basic units of biological classification. A species is often defined as a group of organisms capable of interbreeding and producing fertile offspring.
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DNA sequence or genetic sequence is a succession of letters representing the primary structure of a real or hypothetical DNA molecule or strand, with the capacity to carry information.
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For the anatomist and surgeon, see Emil Zuckerkandl.

Emile Zuckerkandl (b. July 4, 1922) is an Austrian-American biologist considered one of the founders of the field of molecular evolution.
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Linus Pauling

Linus Pauling in 1954
Born January 28 1901
Oswego, Oregon, U.S.
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amino acid is a molecule that contains both amine and carboxyl functional groups. In biochemistry, this term refers to alpha-amino acids with the general formula H₂NCHRCOOH, where R is an organic substituent.
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Hemoglobin, also spelled haemoglobin and abbreviated Hb, is the iron-containing oxygen-transport metalloprotein in the red blood cells of the blood in vertebrates and other animals.
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