The genetic mucolipidoses

Summary This review is an attempt to define a group of storage diseases which exhibit signs and symptoms of both the mucopolysaccharidoses and sphingolipidoses. Lacking some of the characteristics of the mucopolysaccharidoses while resembling to this group of thesaurismoses in other respects, these diseases frequently were described as Hurler variants.In Gm₁ gangliosidosis types I and II, Fucosidosis, Mannosidosis and in infantile Sulfatidosis with mucopolysacchariduria enzyme defects have been identified which are thought to be causally related to the diseases. In others the pathogenesis is unknown. They are tentatively named Mucolipidosis I, II and III.Supported by grants Wi 80 and Sp 63/2 of the Deutsche Forschungsgemeinschaft.     

植物钾营养性状的遗传潜力v

钾是植物生长发育所必需的大量元素,是与氮、磷并列的植物营养的“三大要素”之一。不同植物种类或同种类植物的不同品种之间钾营养效率的差异非常显著,这为植物钾营养性状的遗传改良提供了科学依据     

The human genetic map

The introduction of new technology and increased effort from around the world is driving the completion of the human gene map. In parallel with the creation of the map, we are beginning to see the bio-medical benefits that are a direct consequence of learning more about our own genome.     

The revised genetic code

Recent findings on the genetic code are reviewed, including selenocysteine usage, deviations in the assignments of sense and nonsense codons, RNA editing, natural ribosomal frameshifts and non-orthodox codon-anticodon pairings. A multi-stage codon reading process is presented.     

The population genetic theory of hidden variation and genetic robustness

One of the most solid generalizations of transmission genetics is that the phenotypic variance of populations carrying a major mutation is increased relative to the wild type. At least some part of this higher variance is genetic and due to release of previously hidden variation. Similarly, stressful environments also lead to the expression of hidden variation. These two observations have been considered as evidence that the wild type has evolved robustness against genetic variation, i.e., genetic canalization. In this article we present a general model for the interaction of a major mutation or a novel environment with the additive genetic basis of a quantitative character under stabilizing selection. We introduce an approximation to the genetic variance in mutation-selection-drift balance that includes the previously used stochastic Gaussian and house-of-cards approximations as limiting cases. We then show that the release of hidden genetic variation is a generic property of models with epistasis or genotype-environment interaction, regardless of whether the wild-type genotype is canalized or not. As a consequence, the additive genetic variance increases upon a change in the environment or the genetic background even if the mutant character state is as robust as the wild-type character. Estimates show that this predicted increase can be considerable, in particular in large populations and if there are conditionally neutral alleles at the loci underlying the trait. A brief review of the relevant literature suggests that the assumptions of this model are likely to be generic for polygenic traits. We conclude that the release of hidden genetic variance due to a major mutation or environmental stress does not demonstrate canalization of the wild-type genotype.     

The probability of parallel genetic evolution from standing genetic variation

Parallel evolution is often assumed to result from repeated adaptation to novel, yet ecologically similar, environments. Here, we develop and analyse a mathematical model that predicts the probability of parallel genetic evolution from standing genetic variation as a function of the strength of phenotypic selection and constraints imposed by genetic architecture. Our results show that the probability of parallel genetic evolution increases with the strength of natural selection and effective population size and is particularly likely to occur for genes with large phenotypic effects. Building on these results, we develop a Bayesian framework for estimating the strength of parallel phenotypic selection from genetic data. Using extensive individual‐based simulations, we show that our estimator is robust across a wide range of genetic and evolutionary scenarios and provides a useful tool for rigorously testing the hypothesis that parallel genetic evolution is the result of adaptive evolution. An important result that emerges from our analyses is that existing studies of parallel genetic evolution frequently rely on data that is insufficient for distinguishing between adaptive evolution and neutral evolution driven by random genetic drift. Overcoming this challenge will require sampling more populations and the inclusion of larger numbers of loci.     

The evolution of genetic architecture. I. Diversification of genetic backgrounds by genetic drift

The genetic architecture of a phenotype plays a critical role in determining phenotypic evolution through its effects on patterns of genetic variation. Genetic architecture is often considered to be constant in evolutionary quantitative genetic models. However, genetic architecture may be variable and itself evolve when there are dominance and epistatic interactions among alleles at the same and different loci, respectively. The evolution of genetic architecture by genetic drift is examined here by testing the breeding value of four standard inbred mouse strains mated across a set of 26 related recombinant quasi-inbred (RqI) lines generated from the intercross of the Large (LG/J) and Small (SM/J) inbred mouse strains. Phenotypes of interest include age-specific body weights, growth, and adult body composition. If the genetic architecture of these traits has differentiated by genetic drift during the production of the RqI strains, we should observe interactions between tester strain and RqI strain. The breeding values of the tester strains will change relative to one another depending on which RqI strain they are crossed to. The study included an average of 15.1 offspring per cross, over a total of 100 different crosses. Multivariate and univariate analyses of variance indicate that there is strongly significant interaction for all traits. Interaction is more pronounced in males than in females and accounted for an average of about 40% of the explained variation in males and 30% in females. These results indicate that the genetic architecture of these traits has differentiated by genetic drift in the RqI strains since their isolation from a common founder population. Further analysis indicates that this differentiation results in changes in the order of tester strain effects so that common patterns of selection in these differentiated populations could result in the fixation of different alleles.     

The nature of genetic recombination

The biological evolutionary axiom proposed earlier by the author states that in the absence of genetic recombination the evolution of organic forms would be impossible. In the present paper the literature data are considered, illustrating the role of genetic recombination in evolution. It is urged that a tendency towards an increasing complexity of biological organization results from periodical recombinational combining of the diverged genes as well as the whole genomes of different origin. The alternative mechanism implying the production of duplications from the identical gene copies or whole genomes is considered to be unlikely. According to the biological evolutionary axiom, the origin of life is connected with the appearance of a mode of reparation of crystalline type aggregates--the precursors of DNA by means of exchanges among their constituents. A hypothesis is proposed that in the process of recombination a certain distribution of the 6-amino bases (adenine, cytosine) along the DNA molecule is settled, with respect to the 6-carbonyl bases (guanine, thymine). It is proposed that the relative distribution of the bases mentioned influences electrostatic stability of the DNA molecule as a crystalline associate.