Natural selection and the molecular basis of electrophoretic variation at the coagulation F13B locus

Pig domestication was initiated some 10,000 years ago. Thus, within a fairly short period of time, from an evolutionary perspective, a remarkable change in phenotype has taken place. Until recently (the last few hundred years), the selection intensity was weak but selection on traits such as behaviour and disease resistance must have occurred early. Docile animals resistant to stress were likely to be kept by the early farmers. Less obviously, coat colour is a trait that also was altered early during domestication. New coat colour variants occur by spontaneous mutations, but in nature there is a strong purifying selection eliminating such mutations because they provide less efficient camouflage or fail to attract mates. In contrast, such mutations have accumulated in domestic animals—why? One reason is of course relaxed purifying selection, but this is not the only reason. A less efficient camouflage of the domestic stock could be advantageous for the farmer and maybe it was used to distinguish improved domestic forms from their wild counterparts. Today, coat colour is often used as a breed-specific marker. For instance, a Large White pig should be white and a Piétrain pig should be spotted. Furthermore, there is strong selection for white colour in some breeds because of consumer demand for pork meat without any pigmented spots in the remaining skin. Charles Darwin was the first to realize that the phenotypic change in domestic animals resulting from selective breeding is an excellent model for phenotypic evolution due to natural selection (Darwin 1859). In fact, he became a pigeon breeder himself and used domestic animals as a proof-of-principle for his revolutionary theory on natural selection as a driving force for evolution. The first chapter of The Origin of Species (Darwin 1859) concerns observations on domestic animals, and nine years later he published two volumes on The Variation of Animals and Plants under Domestication (Darwin 1868). In the latter book he describes the phenotypic changes that have occurred in the pig and other domestic animals as a consequence of domestication. As a result of the development of molecular tools in the form of well-developed genetic maps and large number of genetic markers we are now in position to start unravelling the molecular basis for phenotypic changes in the pig and other domestic animals.

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Laboratory Activities to Support Student Understanding of the Molecular Mechanisms of Mutation & Natural Selection

The American Biology Teacher ◽

10.1525/abt.2015.77.2.7 ◽

2015 ◽

Vol 77 (2) ◽

pp. 118-125

Author(s):

Tina Hubler ◽

Patti Adams ◽

Jonathan Scammell

Keyword(s):

Natural Selection ◽

Molecular Biology ◽

Undergraduate Students ◽

Molecular Basis ◽

Molecular Mechanisms ◽

Student Understanding ◽

Previous Article ◽

Laboratory Activities ◽

Molecular Events ◽

Student Laboratory

The molecular basis of evolution is an important and challenging concept for students to understand. In a previous article, we provided some of the scientific background necessary to teach this topic. This article features a series of laboratory activities demonstrating that molecular events can alter the genomes of organisms. These activities are most appropriate for undergraduate students in Honors Biology, Genetics, or Molecular Biology courses. Student laboratory instructions are included to allow students to conduct the activities, make observations, interpret the results, and draw conclusions.

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Natural selection and the genetics of adaptation in threespine stickleback

Philosophical Transactions of the Royal Society B Biological Sciences ◽

10.1098/rstb.2010.0036 ◽

2010 ◽

Vol 365 (1552) ◽

pp. 2479-2486 ◽

Cited By ~ 54

Author(s):

Dolph Schluter ◽

Kerry B. Marchinko ◽

R. D. H. Barrett ◽

Sean M. Rogers

Keyword(s):

Natural Selection ◽

Molecular Basis ◽

Threespine Stickleback ◽

Ice Age ◽

Disruptive Selection ◽

Phenotypic Effect ◽

Adaptive Peak ◽

Last Ice Age ◽

Genetics Of Adaptation ◽

Frequency Changes

Growing knowledge of the molecular basis of adaptation in wild populations is expanding the study of natural selection. We summarize ongoing efforts to infer three aspects of natural selection—mechanism, form and history—from the genetics of adaptive evolution in threespine stickleback that colonized freshwater after the last ice age. We tested a mechanism of selection for reduced bony armour in freshwater by tracking genotype and allele frequency changes at an underlying major locus ( Ectodysplasin ) in transplanted stickleback populations. We inferred disruptive selection on genotypes at the same locus in a population polymorphic for bony armour. Finally, we compared the distribution of phenotypic effect sizes of genes underlying changes in body shape with that predicted by models of adaptive peak shifts following colonization of freshwater. Studies of the effects of selection on genes complement efforts to identify the molecular basis of adaptive differences, and improve our understanding of phenotypic evolution.

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Detecting ancient positive selection in humans using extended lineage sorting

10.1101/092999 ◽

2016 ◽

Cited By ~ 1

Author(s):

Stéphane Peyrégne ◽

Michael James Boyle ◽

Michael Dannemann ◽

Kay Prüfer

Keyword(s):

Natural Selection ◽

Positive Selection ◽

Molecular Basis ◽

Neutral Evolution ◽

Selective Sweeps ◽

Lineage Sorting ◽

1000 Genomes ◽

Regulatory Changes ◽

Genomic Regions ◽

Human Specific

ABSTRACTNatural selection that affected modern humans early in their evolution has likely shaped some of the traits that set present-day humans apart from their closest extinct and living relatives. The ability to detect ancient natural selection in the human genome could provide insights into the molecular basis for these human-specific traits. Here, we introduce a method for detecting ancient selective sweeps by scanning for extended genomic regions where our closest extinct relatives, Neandertals and Denisovans, fall outside of the present-day human variation. Regions that are unusually long indicate the presence of lineages that reached fixation in the human population faster than expected under neutral evolution. Using simulations we show that the method is able to detect ancient events of positive selection and that it can differentiate those from background selection. Applying our method to the 1000 Genomes dataset, we find evidence for ancient selective sweeps favoring regulatory changes and present a list of genomic regions that are predicted to underlie positively selected human specific traits.

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Renilla Bioluminescence: A Morphologic Approach to the Location of Photocytes

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100051050 ◽

1974 ◽

Vol 32 ◽

pp. 208-209

Author(s):

Ben O. Spurlock ◽

Milton J. Cormier

Keyword(s):

Excited State ◽

Ground State ◽

Molecular Basis ◽

Light Emission ◽

Chemical Basis ◽

Electronic Excited State ◽

Colonial Form ◽

The Common ◽

Eighteenth And Nineteenth Centuries ◽

Catalyzed Oxidation

The phenomenon of bioluminescence has fascinated layman and scientist alike for many centuries. During the eighteenth and nineteenth centuries a number of observations were reported on the physiology of bioluminescence in Renilla, the common sea pansy. More recently biochemists have directed their attention to the molecular basis of luminosity in this colonial form. These studies have centered primarily on defining the chemical basis for bioluminescence and its control. It is now established that bioluminescence in Renilla arises due to the luciferase-catalyzed oxidation of luciferin. This results in the creation of a product (oxyluciferin) in an electronic excited state. The transition of oxyluciferin from its excited state to the ground state leads to light emission.

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Androgen-induced plasticity at a “vocal” neuromuscular synapse

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100167895 ◽

1994 ◽

Vol 52 ◽

pp. 32-33

Author(s):

Darcy B. Kelley ◽

Martha L. Tobias ◽

Mark Ellisman

Keyword(s):

Xenopus Laevis ◽

Motor Neurons ◽

Sexual Differentiation ◽

Molecular Basis ◽

Neuromuscular Synapse ◽

Sexually Dimorphic ◽

Intracellular Protein ◽

Developmental Program ◽

Androgen Action ◽

Clawed Frog

Brain and muscle are sexually differentiated tissues in which masculinization is controlled by the secretion of androgens from the testes. Sensitivity to androgen is conferred by the expression of an intracellular protein, the androgen receptor. A central problem of sexual differentiation is thus to understand the cellular and molecular basis of androgen action. We do not understand how hormone occupancy of a receptor translates into an alteration in the developmental program of the target cell. Our studies on sexual differentiation of brain and muscle in Xenopus laevis are designed to explore the molecular basis of androgen induced sexual differentiation by examining how this hormone controls the masculinization of brain and muscle targets.Our approach to this problem has focused on a highly androgen sensitive, sexually dimorphic neuromuscular system: laryngeal muscles and motor neurons of the clawed frog, Xenopus laevis. We have been studying sex differences at a synapse, the laryngeal neuromuscular junction, which mediates sexually dimorphic vocal behavior in Xenopus laevis frogs.

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