Dominance,overdominance and epistasis in Pisum sativum L.

Summary Dominant genes are the main cause of the heterosis induced by fasciated mutants of different lines of Pisum sativum. Most of these cases were originally interpreted by different authors as examples of monogenic overdominance. Several not-closely-linked genes appear to have mutated simultaneously in most of the fasciated lines. Although fasciation itself is recessive, other mutant characters, such as lateness, increased stem length (number and length of internodes) and, in part, seed production per plant, show dominant inheritance. The latter two features are, however, to a considerable extent suppressed in the fasciated lines by unfavourable gene-interactions (epistasis). Crossing these lines with non-fasciated ones shows that the epistatic genes are recessive and the dominant genes are then no longer hindered in their action. By eliminating the epistatic genes from the genomes of fasciated lines by recombination, the heterosis phenomenon has been fixed on six independent occasions for different lines. The fasciata genes themselves were found to be the most probable cause of these cases of recessive epistasis. The question whether different kinds of fasciation affect heterosis differently is examined. Recessive epistasis and dominance explain most of the quantitative distinctions between the different hybrids. In addition, one example of heterosis between non-fasciated lines is given and the possible meaning of the overall results for plant breeding and population genetics is mentioned.     

Evidence for overdominance inDrosophila melanogaster

In artificial populations ofDrosophila melanogaster the mutantsvermilion (v) andcinnabar (cn), both interfering with eye pigment formation, appeared to be balanced against wild type, indicating that the heterozygotesv/+ andcn/+ have a selective advantage over the respective homozygotes. In a population homozygous forv, the mutantcn in competition with its wild type allele tended to be eliminated. Ifcn was homozygous,v showed a similar tendency. Thus in competion experiments it was found that the heterozygotes for one of the two recessive genes,v andcn, ceased to be heterotic when the other recessive is homozygous. These findings are considered to be evidence for the existence of overdominance.     

Levels of multiallelic overdominance fitness, heterozygote excess and heterozygote deficiency

Concepts and results on selection balance in multiallelic systems are described. These include a multidimensional concept of heterozygote excess and heterozygote deficiency, a hierarchy of means of assessment of heterozygote advantage, comparisons and contrasts of allelic versus gametic polymorphic states, and conditions defining stable equilibria of complementary gametic sets. The concepts are illustrated in the context of viability selection and behavioral models of kin selection and for two major categories of multilocus selection regimes.     

Theodosius Dobzhansky and the genetic race concept

The use of ‘race’ as a proxy for population structure in the genetic mapping of complex traits has provoked controversy about its legitimacy as a category for biomedical research, given its social and political connotations. The controversy has reignited debates among scientists and philosophers of science about whether there is a legitimate biological concept of race. This paper examines the genetic race concept as it developed historically in the work of Theodosius Dobzhansky from the 1930s to 1950s. Dobzhansky’s definitions of race changed over this time from races as ‘arrays of forms’ or ‘clusters’ in 1933–1939, to races as genetically distinct geographical populations in 1940–1946, to races as genetically distinct ‘Mendelian populations’ in 1947–1955. Dobzhansky responded to nominalist challenges by appealing to the biological reality of race as a process. This response came into tension with the object ontology of race that was implied by Dobzhansky’s increasingly holistic treatment of Mendelian populations, a tension, the paper argues, he failed to appreciate or resolve.     

Hitchhiking and associative overdominance at a microsatellite locus

The possible effects of a selected locus on a closely linked microsatellite locus are discussed and analyzed in terms of coalescent theory and models of the mutation process. Background selection caused by recurrent deleterious mutations will reduce the variance of allele size at a microsatellite locus. The occasional substitution of advantageous alleles (genetic hitchhiking) will also reduce the variance, but a high mutation rate at a microsatellite locus can restore the variance relatively rapidly. Overdominance at the selected locus will increase the variance at the microsatellite locus and create partitioning of the variation in allele size among gametes carrying one or the other of the overdominant alleles. These results suggest that neutral microsatellite loci can provide indicators of selective processes at closely linked loci.      

Timeline: Hermann Joseph Muller, evolutionist

This essay is dedicated to the proposition that Hermann Joseph Muller, widely regarded as the greatest geneticist of the first half-century of the subject, was also one of the greatest evolutionists of this period. His Nobel Prize-winning work, which showed that radiation increases the mutation rate, is in every genetics textbook, and his prescient ideas have influenced almost every aspect of the discipline. Here I emphasize his less well-known contribution to the neo-Darwinian theory of evolution.     

Muller细胞与视网膜病变

视网膜是一薄而半透明的、具有多层结构的神经组织,位于眼球后2/3部的内侧面。向前延伸达睫状体,止于不规则边界。Muller细胞是脊椎动物视网膜内最主要的神经胶质细胞,它贯穿整个视网膜。Muller细胞对于维持神经元的完整性、代谢、内环境稳态以及信号转导等均具有重要的作用。在视网膜病变时,Muller细胞参与整个过程,并且在视网膜的各种疾病中都发现伴有Muller细胞的神经胶质增生反应。Muller细胞同时也调控视网膜病变的整个过程。Muller细胞膜上的神经递质受体、谷氨酸受体、门控电压通道、所合成分泌的营养因子及自的身增殖分化都发生改变。近年来人们对Muller细胞的认识越来越多,研究的方向也从细胞的微观结构、主要功能转变成Muller细胞对不同视网膜病变过程的参与调控。本文对视网膜Muller细胞的形态和生理功能,病理状况下Muller细胞发生的改变作一综述。