Inheritance and population structure of the white-phased "Kermode" black bear

We report that a single nucleotide replacement in the melanocortin 1 receptor gene [1] (mc1r) is responsible for the white coat color of the "Kermode" bear [2], a color phase of the black bear (Ursus americanus Pallus) found in the rainforests along the north coast of British Columbia. In a sample of 220 bears, of which 22 were white, there was complete association of a recessive Tyr-to-Cys replacement at codon 298 with the white phase. This variant has not been yet been reported in other mammals, and it also is the lightest-colored variant yet found at mc1r. Also, we found that heterozygotes, which act as a hidden reservoir for the allele among black bears, were infrequent outside of the three islands where Kermodes are common and that, within these three islands, heterozygotes were less frequent than expected under random mating. Immigration of black bears into Kermode populations can depress the occurrence of the white phase, and management practices should be designed to avoid facilitating higher immigration rates.     

Pathogen resistance and genetic variation at MHC loci

Abstract.— Balancing selection in the form of heterozygote advantage, frequency-dependent selection, or selection that varies in time and/or space, has been proposed to explain the high variation at major histocompatibility complex (MHC) genes. Here the effect of variation of the presence and absence of pathogens over time on genetic variation at multiallelic loci is examined. In the basic model, resistance to each pathogen is conferred by a given allele, and this allele is assumed to be dominant. Given that s is the selective disadvantage for homozygotes (and heterozygotes) without the resistance allele and the proportion of generations, which a pathogen is present, is e , fitnesses for homozygotes become (1 — s )^(n-1)e and the fitnesses for heterozygotes become (1 — s )^(n-2)e, where n is the number of alleles. In this situation, the conditions for a stable, multiallelic polymorphism are met even though there is no intrinsic heterozygote advantage. The distribution of allele frequencies and consequently heterozygosity are a function of the autocorrelation of the presence of the pathogen in subsequent generations. When there is a positive autocorrelation over generations, the observed heterozygosity is reduced. In addition, the effects of lower levels of selection and dominance and the influence of genetic drift were examined. These effects were compared to the observed heterozygosity for two MHC genes in several South American Indian samples. Overall, resistance conferred by specific alleles to temporally variable pathogens may contribute to the observed polymorphism at MHC genes and other similar host defense loci.     

Effects of a Locus Affecting Floral Pigmentation in Ipomoea Purpurea on Female Fitness Components

A locus influencing floral pigment intensity in the morning glory, Ipomoea purpurea, is polymorphic throughout the southeastern United States. Previous work has suggested that the white allele at this locus has a transmission advantage during mating because of the effect of flower color on pollinator behavior. The experiment described here was designed to determine whether other effects of the W locus may contribute an opposing selective advantage to the dark allele. Dark homozygotes were vegetatively smaller and produced fewer flowers, seed capsules and seeds than either light heterozygotes or white homozygotes. In addition, dark homozygotes produced smaller seeds than heterozygotes, and there is some indication that white homozygotes also produced smaller seeds than heterozygotes. Pleiotropic effects on seed number thus do not seem to contribute to selection opposing the mating advantage associated with the white allele. However, pleiotropic effects on seed size might contribute to overdominance that could stabilize the W locus polymorphism.     

Connection of HindIII-polymorphism in the lipoprotein lipase gene with myocardial infarct and life span in elderly ischemic heart disease patients

Allele and genotype frequencies of the HindIII polymorphism of the lipoprotein lipase (LPL) gene were studied in patients with myocardial infarction (MI) and stable angina of effort (SAE), including long-lived people (over 90). The polymorphism proved to be associated with MI and with the life span, genotype H+/H+ being predisposing to MI and allele H- being protective. The allele and genotype frequencies of long-lived people differed significantly from the Hardy-Weinberg proportions and from those of SAE patients aged up to 90. An excess of heterozygotes in this group suggests a selective pressure which eliminates homozygotes. Possibly, heterozygotes H+/H- have an adaptive advantage, which provides for their longevity.     

Association of the HindIII Polymorphism of the Lipoprotein Lipase Gene with Myocardial Infarction and the Life Span in Elderly Patients with Coronary Heart Disease

Allele and genotype frequencies of the HindIII polymorphism of the lipoprotein lipase (LPL) gene were studied in patients with myocardial infarction (MI) and stable angina of effort (SAE), including long-lived people (over 90). The polymorphism proved to be associated with MI and with the life span, genotype H+/H+ being predisposing to MI and allele H– being protective. The allele and genotype frequencies of long-lived people differed significantly from the Hardy–Weinberg proportions and from those of SAE patients aged up to 90. An excess of heterozygotes in this group suggests a selective pressure which eliminates homozygotes. Possibly, heterozygotes H+/H– have an adaptive advantage, which provides for their longevity.     

Multiple mutations in a specific gene in a small population

Hereditary diseases have been reported with relatively high frequency in some small populations. Founder effect and genetic drift, associated or not with selective advantage of heterozygotes in case of recessive diseases, are the main explanations. Therefore, if we consider one population and one particular disease, only one deleterious allele should be observed.Determination of mutations has shown that in most cases the situation is more complex; more than one mutation is found among the patients. This finding can be explained by a multiple founder effect, with genetic drift and new mutations.     

HLA DNA sequence variation among human populations: molecular signatures of demographic and selective events

Molecular differences between HLA alleles vary up to 57 nucleotides within the peptide binding coding region of human Major Histocompatibility Complex (MHC) genes, but it is still unclear whether this variation results from a stochastic process or from selective constraints related to functional differences among HLA molecules. Although HLA alleles are generally treated as equidistant molecular units in population genetic studies, DNA sequence diversity among populations is also crucial to interpret the observed HLA polymorphism. In this study, we used a large dataset of 2,062 DNA sequences defined for the different HLA alleles to analyze nucleotide diversity of seven HLA genes in 23,500 individuals of about 200 populations spread worldwide. We first analyzed the HLA molecular structure and diversity of these populations in relation to geographic variation and we further investigated possible departures from selective neutrality through Tajima's tests and mismatch distributions. All results were compared to those obtained by classical approaches applied to HLA allele frequencies.Our study shows that the global patterns of HLA nucleotide diversity among populations are significantly correlated to geography, although in some specific cases the molecular information reveals unexpected genetic relationships. At all loci except HLA-DPB1, populations have accumulated a high proportion of very divergent alleles, suggesting an advantage of heterozygotes expressing molecularly distant HLA molecules (asymmetric overdominant selection model). However, both different intensities of selection and unequal levels of gene conversion may explain the heterogeneous mismatch distributions observed among the loci. Also, distinctive patterns of sequence divergence observed at the HLA-DPB1 locus suggest current neutrality but old selective pressures on this gene. We conclude that HLA DNA sequences advantageously complement HLA allele frequencies as a source of data used to explore the genetic history of human populations, and that their analysis allows a more thorough investigation of human MHC molecular evolution.     

Molecular evidence for selection on female color polymorphism in the damselfly Ischnura graellsii

The significance of female color polymorphism in Odonata remains controversial despite many field studies. The importance of random factors (founder effects, genetic drift and migration) versus selective forces for the maintenance of this polymorphism is still discussed. In this study, we specifically test whether the female color polymorphism of Ischnura graellsii (Odonata, Coenagrionidae) is under selection in the wild. We compared the degree of genetic differentiation based on RAPD markers (assumed to be neutral) with the degree of differentiation based on color alleles. Weir and Cockerham's theta values showed a significant degree of population differentiation for both sets of loci (RAPD and color alleles) but the estimated degree of population differentiation (theta) was significantly greater for the set of RAPD loci. This result shows that some sort of selection contributes to the maintenance of similar color morph frequencies across the studied populations. Our results combined with those of previous field studies suggest that at least in some I. graellsii populations, density-dependent mechanisms might help to prevent the loss of this polymorphism but cannot explain the similarity in morph frequencies among populations.     

Selection with two alleles and complete dominance

For a plant selection model with frequency-independent viabilities, fertilities and selfing rates, it is shown that apart from global fixation, for certain parameter combinations a protected polymorphism and facultative fixation (either allele may become fixed according to initial frequencies) may both occur. Facultative fixation requires different selling rates for the dominant and recessive type. Protection of the polymorphism requires resource allocation for male and female function. In this connection the problem of purely genetically caused population extinction is discussed.
For general frequency dependence and regular segregation, the chances for establishment of a completely recessive gene are compared to those of a completely dominant gene. It is proven that the process of establishment of the recessive gene, despite a fitness advantage, may be considerably endangered by drift effects if random mating prevails. The recessive gene may reach the same effectivity in establishment as a dominant gene, only if the recessive homozygote mates exclusively with its own type during the period of establishment.     

The molecular basis of glucose-6-phosphate dehydrogenase deficiency.

With more than 300 different variants reported, the human enzyme glucose-6-phosphate dehydrogenase (G6PD; EC 1.1.1.49) is one of the most polymorphic proteins known. An estimated 400 million people throughout the world are deficient in G6PD; numerous lines of evidence indicate that this is because female heterozygotes have a selective advantage in malaria infections. The cloning of the G6PD gene has made it possible to clarify the molecular basis underlying this enzyme deficiency and polymorphism.     

Neutral drift and polymorphism in gene-for-gene systems

Pathogens are a main driving force of the evolution of plants and animals. Being resistant to diseases confers a high selective advantage to hosts, yet many host–pathogen systems show a remarkable degree of polymorphism of host resistance and pathogen virulence. The most common explanation of this phenomenon is that both resistance and virulence genes are costly and that there is selection against those genes when they are unnecessary. Here, we use stochastic multi‐locus simulations to show that the origin and the maintenance of genetic polymorphism in plant–pathogen systems can be explained without costs. In multi‐locus gene‐for‐gene systems, temporal domination of a super pathogen can cause polymorphism in resistance through neutral drift. With an increasing number of susceptible alleles in the host population, pathogen types other than the super race are able to cause infections and invade the population, leading to higher pathogen diversity and in turn to higher host diversity.     

虹鳟mc1r基因的克隆、序列分析及在 不同发育阶段和组织的表达分析

黑素皮质素1受体基因(mc1r)是控制动物色素合成的重要基因,为探讨mc1r基因与虹鳟(Oncorhynchus mykiss)体色变异的关系,本研究利用cDNA末端快速扩增(RACE)技术获得虹鳟mc1r基因的cDNA全长序列,并对其编码的蛋白进行了生物信息学分析,同时利用实时荧光定量PCR(qRT-PCR)分析该基因在野生型虹鳟(虹鳟)和黄色突变型虹鳟(金鳟)体色发生不同时期(从受精期至12月龄)及成鱼背部皮肤、腹部皮肤、背部肌肉、腹部肌肉、眼、脑、鳃、中肾、头肾、肠、肝、脾和心13种组织中的表达差异。结果显示,mc1r基因序列全长为4 518 bp,开放阅读框1 017 bp,编码338个氨基酸。氨基酸序列分析发现,虹鳟Mc1r蛋白具有7TM_GPCR_Srsx结构域。通过氨基酸序列同源比对与系统进化分析表明,Mc1r蛋白序列在鱼类间具有较高的保守性。qRT-PCR结果表明,mc1r基因在虹鳟与金鳟的受精期就开始表达,且在受精期至桑葚期胚胎的表达量高于胚胎后期;mc1r基因在虹鳟与金鳟相同时期表达比较结果显示,该基因在受精期、4细胞期、16细胞期、囊胚期、原肠期、神经期、体节期、1日龄、3日龄、7日龄胚胎或个体以及1月龄、2月龄、3月龄和6月龄背部皮肤中的表达均差异显著(P 0.05);mc1r基因在12月龄虹鳟和金鳟的13种组织中均有表达,其中,该基因在虹鳟与金鳟的背部皮肤、腹部皮肤和脑中的表达量较高,显著高于其他组织(P 0.05),且虹鳟背部皮肤中该基因的表达量高于金鳟背部皮肤(P 0.05)。以上结果表明,mc1r基因可能与虹鳟体色变异密切相关。本研究可为后期进一步深入阐明虹鳟体色变异的分子机制提供基础资料。     

Perspective: Evolution of flower color in the desert annual Linanthus parryae: Wright revisited

Linanthus parryae, a diminutive desert annual with white or blue flowers, has been the focus of a long-standing debate among evolutionary biologists. At issue is whether the flower color polymorphism in this species is the product of random genetic drift, as Sewall Wright argued, or of natural selection, as proposed by Carl Epling and his colleagues. Our long-term studies of three polymorphic populations in the Mojave Desert demonstrate that flower color is subject to selection that varies in both time and space in its direction and magnitude. For all sites taken together, blue-flowered plants produced more seeds than white-flowered plants in years of relatively low seed production, whereas white-flowered plants had higher fitness in years of high seed production. Evidence of selection on flower color was found in two of the three study sites. Differences in fitness between the color morphs were sometimes large, with selection coefficients as high as 0.60 in some years. Our longest period of observations was at Pearblossom site 1, where plants reached appreciable densities in seven of the 11 years of study. Here we found significant differences in the seed production of the color morphs in six years, with three years of blue advantage and three years of white advantage. For all sites taken together, total spring precipitation (March and April) was positively correlated with both absolute and relative seed production of the color morphs. At Pearblossom site 1, blue-flowered plants typically had a fitness advantage in years of low spring precipitation, whereas white-flowered plants had a fitness advantage in years of high spring precipitation. This temporal variation in selection may contribute to the maintenance of the flower-color polymorphism at Pearblossom site 1, whereas gene flow from neighboring populations is proposed as the principal factor maintaining the polymorphism at the other study sites. We found no significant differences between the color morphs in pollinator visitation rate or in their carbon isotope ratio, a measure of water-use efficiency. Although the mechanism of selection remains elusive, our results refute Wright's conclusion that the flower color polymorphism in L. parryae is an example of isolation by distance, a key component of his shifting balance theory of evolution.     

Roles of maternal effects in maintaining genetic variation: Maternal storage effect

Understanding the maintenance of genetic variation remains a central challenge in evolutionary biology. Recent empirical studies suggest the importance of temporally varying selection, as allele frequencies have been found to fluctuate substantially in the wild. However, previous theory suggests that the conditions for the maintenance of genetic variation under temporally fluctuating selection are quite restrictive. Using mathematical models, we demonstrate that maternal genetic effects, whereby maternal genotypes affect offspring phenotypes, can facilitate the maintenance of polymorphism in temporally varying environments. Maternal effects result in mismatches between genotypes and phenotypes, thereby buffering the influence of selection on allele frequency. This decreases the magnitude of allele‐frequency fluctuations and creates conditions for the maintenance of variation when selection causes fluctuations. Therefore, maternal effects may result in a temporal storage effect (“maternal storage effect”). On the other hand, when selection does not cause fluctuations (e.g., linear negative frequency‐dependent selection), maternal genetic effects moderate the relative importance of selection compared to genetic drift and promote stochastic allele extinction in finite populations. Thus, maternal effects can play an important role in the maintenance of polymorphism, but the direction of the effect depends on the nature of selection.     

High frequency of CYP1A1*2C allele in Brazilian populations

The genetic variability of the CYP1A1 I462V polymorphism (CYP1A1*2C) was investigated in four Brazilian populations: three groups of African descent and one group of European descent. The CYP1A1 polymorphism was analyzed by two different procedures, first by the allele-specific polymerase chain reaction (PCR) method and then by the PCR-restricted fragment length polymorphism (PCR-RFLP) method before digestion with BsrDI. The frequency of CYP1A1 *2C was 11% in Brazilians of European descent, a frequency that is slightly higher but not statistically different from that observed in European populations. In Brazilians of African ancestry this value was very high (12% to 15%). This allele was not observed in the only two African populations investigated thus far. By themselves, the two factors of interethnic admixture (with populations of European descent and/or Amerindian populations) and genetic drift cannot explain the high values observed here. Our findings suggest that the CYP1A1 *2C allele may possibly be present in Africa, but restricted to some ethnic groups not yet investigated. Environmental factors in South America might also have acted as selective factors increasing the CYP1A1 *2C gene frequency. Our data also suggest that the CYP1A1 *2C allele might possibly have originated in Africa.     

Correlation between the Asp298Asn polymorphism of mc4r gene and back fat width in pigs of large white bred

Asp298Asn correlation between the mc4r gene polymorphism and development of such trait as back fat width in Large White pigs belonging to AF "Orzhitska" population was studied. The tendency of forming thinner back fat layer in animals possessing AG genotype was detected. Any reliable differences in back fat width between animal groups with various mc4r genotypes caused by the Asp298Asn polymorphism were not detected. A possible reason for the absence of statistically reliable difference may be heterogeneous origin of the studied animals. Using Asp298Asn polymorphism of mc4r gene in selecting the Large White AF "Orzhitska" pig population is unreasonable.     

Loss‐of‐function mutations in the melanocortin 1 receptor cause disruption of dorso‐ventral countershading in teleost fish

The melanocortin 1 receptor (MC1R) is the central melanocortin receptor involved in vertebrate pigmentation. Mutations in this gene cause variations in coat coloration in amniotes. Additionally, in mammals MC1R is the main receptor for agouti‐signaling protein (ASIP), making it the critical receptor for the establishment of dorsal‐ventral countershading. In fish, Mc1r is also involved in pigmentation, but it has been almost exclusively studied in relation to melanosome dispersion activity and as a putative genetic factor involved in dark/light adaptation. However, its role as the crucial component for the Asip1‐dependent control of dorsal‐ventral pigmentation remains unexplored. Using CRISPR/Cas9, we created mc1r homozygous knockout zebrafish and found that loss‐of‐function of mc1r causes a reduction of countershading and a general paling of the animals. We find ectopic development of melanophores and xanthophores, accompanied by a decrease in iridophore numbers in the ventral region of mc1r mutants. We also reveal subtle differences in the role of mc1r in repressing pigment cell development between the skin and scale niches in ventral regions.     

Ecological genetics of adaptive color polymorphism in pocket mice: geographic variation in selected and neutral genes

Patterns of geographic variation in phenotype or genotype may provide evidence for natural selection. Here, we compare phenotypic variation in color, allele frequencies of a pigmentation gene (the melanocortin-1 receptor, Mc1r), and patterns of neutral mitochondrial DNA (mtDNA) variation in rock pocket mice (Chaetodipus intermedius) across a habitat gradient in southern Arizona. Pocket mice inhabiting volcanic lava have dark coats with unbanded, uniformly melanic hairs, whereas mice from nearby light-colored granitic rocks have light coats with banded hairs. This color polymorphism is a presumed adaptation to avoid predation. Previous work has demonstrated that two Mc1r alleles, D and d, differ by four amino acids, and are responsible for the color polymorphism: DD and Dd genotypes are melanic whereas dd genotypes are light colored. To determine the frequency of the two Mc1r allelic classes across the dark-colored lava and neighboring light-colored granite, we sequenced the Mc1r gene in 175 individuals from a 35-km transect in the Pinacate lava region. We also sequenced two neutral mtDNA genes, COIII and ND3, in the same individuals. We found a strong correlation between Mc1r allele frequency and habitat color and no correlation between mtDNA markers and habitat color. Using estimates of migration from mtDNA haplotypes between dark- and light-colored sampling sites and Mc1r allele frequencies at each site, we estimated selection coefficients against mismatched Mc1r alleles, assuming a simple model of migration-selection balance. Habitat-dependent selection appears strong but asymmetric: selection is stronger against light mice on dark rock than against melanic mice on light rock. Together these results suggest that natural selection acts to match pocket mouse coat color to substrate color, despite high levels of gene flow between light and melanic populations.     

Ogt-dependent X-chromosome-linked protein glycosylation is a requisite modification in somatic cell function and embryo viability

The Ogt gene encodes a glycosyltransferase that links N-acetylglucosamine to serine and threonine residues (O-GlcNAc) on nuclear and cytosolic proteins. Efforts to study a mammalian model of Ogt deficiency have been hindered by the requirement for this X-linked gene in embryonic stem cell viability, necessitating the use of conditional mutagenesis in vivo. We have extended these observations by segregating Ogt mutation to distinct somatic cell types, including neurons, thymocytes, and fibroblasts, the latter by an approach developed for inducible Ogt mutagenesis. We show that Ogt mutation results in the loss of O-GlcNAc and causes T-cell apoptosis, neuronal tau hyperphosphorylation, and fibroblast growth arrest with altered expression of c-Fos, c-Jun, c-Myc, Sp1, and p27. We further segregated the mutant Ogt allele to parental gametes by oocyte- and spermatid-specific Cre-loxP mutagenesis. By this we established an in vivo genetic approach that supports the ontogeny of female heterozygotes bearing mutant X-linked genes required during embryogenesis. Successful production and characterization of such female heterozygotes further indicates that mammalian cells commonly require a functional Ogt allele. We find that O-GlcNAc modulates protein phosphorylation and expression among essential and conserved cell signaling pathways.