Origin of the genetic code: A physical-chemical model of primitive codon assignments

Selective compartmentalization of amino acids and nucleotides according to their polarities is proposed as a physical-chemical model for the origin of the genetic code. Assumptions made in this hypothesis are: (1) an oil-slick covered the surface of the primitive ocean, constituents of which formed association colloids or micelles at the water-oil-air interfaces; (2) depending on the polarity of the media, these aggregates possessed hydrophilic and hydrophobic interiors where selective uptake of amino acids and nucleic acid constituents could take place; and 93) condensation and polymerization in the micellar phase were enhanced. According to the chromatographically observed polarities, for example, lysine and uridylate fall into the hydrophilic compartment, and phenylalanine and adenylate are enriched in the hydrophobic environment. These components could eventually be condensed to form a charged adaptor loop with an anticodon which is complementary to the presently valid codon. Only two groups of amino acids, hydrophilic and hydrophobic, were recognized by the primitive translation mechanism. Implications of this hypothesis for the further development of the genetic code is discussed. The catalytic power of micelles have been substantiated by successful synthesis of nucleotides under relatively mild conditions using thiophosphates as high energy phosphates.     

On the evolution of dominance modifiers II: a non-equilibrium approach to the evolution of genetic systems

The evolution of dominance is both the simplest and best investigated example of the evolution of genetic systems. Nevertheless, there exists striking empirical material, e.g. industrial melanism, for which no satisfactory explanation could so far be provided. In this paper we take an approach to this classical problem based on a global analysis together with computer simulations. It reveals that during the evolution of dominance one has to distinguish a "nonequilibrium phase" and a "Fisherian phase". The non-equilibrium phase appears to be characterized by the fact that in general the selection intensity at the primary locus does not affect the degree of modifier selection but only the time necessary for passing through this phase. A further essential conclusion is that modifier evolution only obtains a reasonable amount of efficiency if the population reaches the Fisherian phase already with a high modifier frequency. Using these results, predictions on the population genetic prerequisites for the evolution of dominance are derived. From these we conclude that even in populations in which dominance evolution has occurred it cannot be expected that back-crosses into relics of the ancestral population lead to a breakdown of dominance within a few generations. These predictions are in accordance with empirical data on Biston betularia and Odontopera bidentata.     

Vacuolation: Origin and development of the lysosomal apparatus in root-tip cells

Summary The morphology of vacuolation has been investigated in root tip cells of corn using the freeze-etching technique. The genesis of vacuoles involves the following processes: a) Formation of small, endoplasmic-reticulum (ER)-derived vesicles (provacuoles); b) fusion of provacuoles resulting in the formation of small vacuoles, and followed by fusion and expansion of vacuoles; c) incorporation of large, dictyosome-derived vesicles into vacuoles by invagination of the tonoplast; d) invagination of the tonoplast resulting in the incorporation of cytoplasmic material into vacuoles. The morphological findings are correlated with biochemical data obtained from isolated vacuoles (lysosomes). Provacuoles (ER-derived vesicles) are shown to be primary lysosomes; their hydrolases arise from the ER. Vacuoles represent secondary lysosomes (digestive vacuoles) of the higher-plant cell. The metabolic role of lytic processes proceeding in the lysosomal apparatus is discussed.     

Moving up the hierarchy: A hypothesis on the evolution of a genetic sex determination pathway

A hypothesis on the evolutionary origin of the genetic pathway of sex determination in the nematode Caenorhabditis elegans is presented here. It is suggested that the pathway arose in steps, driven by frequency-dependent selection for the minority sex at each step, and involving the sequential acquisition of dominant negative, neomorphic genetic switches, each one reversing the action of the previous one. A central implication is that the genetic pathway evolved in reverse order from the final step in the hierarchy up to the first. The possible applicability of the model to the other well-characterized sex determination pathway, that of Drosophila melanogaster, and to sex determination in mammals, is discussed, along with some potential implications for pathway evolution in general. Finally, the specific molecular and population genetic questions that the model raises are described and some tests are proposed.     

Origin and evolution of the Notch signalling pathway: an overview from eukaryotic genomes

Background  

Of the 20 or so signal transduction pathways that orchestrate cell-cell interactions in metazoans, seven are involved during development. One of these is the Notch signalling pathway which regulates cellular identity, proliferation, differentiation and apoptosis via the developmental processes of lateral inhibition and boundary induction. In light of this essential role played in metazoan development, we surveyed a wide range of eukaryotic genomes to determine the origin and evolution of the components and auxiliary factors that compose and modulate this pathway.     

Speculations on the evolution of the genetic code II

An evolutionary scheme is postulated in which a primitive code, involving only guanine and cytosine, would code for glycine (GG), alanine (GC), arginine (CG) and proline (CC). From each of these amino acids and their codons, there evolves a family of related amino acids as the code expands. The four families are: (1)alanine valine, leucine, isoleucine, phenylalanine, tyrosine, methionine and tryptophane; (2)proline, threonine and serine; (3)arginine, lysine, and histidine; (4)glycine, serine, cysteine, glutamic acid, glutamine, aspartic acid and asparagine. Except for the glycine relation to glutamic acid and aspartic acid, all amino acids are related by chemical similarities in their side chains. Glycine not having a side chain would permit a more complex set of substitutions.     

Chromosomal evolution of the Canidae. II. Divergence from the primitive carnivore karyotype

The Giemsa-banding patterns of chromosomes from the arctic fox (Alopex lagopus), the red fox (Vulpes vulpes), the kit fox (Vulpes macrotis), and the raccoon dog (Nyctereutes procyonoides) are compared. Despite their traditional placement in different genera, the arctic fox and the kit fox have an identical chromosome morphology and G-banding pattern. The red fox has extensive chromosome arm homoeology with these two species, but has only two entire chromosomes in common. All three species share some chromosomes with the raccoon dog, as does the high diploid-numbered grey wolf (Canis lupus, 2n = 78). Moreover, some chromosomes of the raccoon dog show partial or complete homoeology with metacentric feline chromosomes which suggests that these are primitive canid chromosomes. We present the history of chromosomal rearrangements within the Canidae family based on the assumption that a metacentric-dominated karyotype is primitive for the group.     

新基因起源：从自然进化到人工设计

生命体系历经40多亿年的自然进化,创造了无数丰富多彩的功能基因,保障了生命体系的传承与繁荣。然而生命体系的自然进化历程极其缓慢,新的功能基因产生需要数百万年时间,无法满足快速发展的工业生产需求。利用合成生物学技术,研究人员可以依据已知的酶催化机理和蛋白质结构进行全新的基因设计与合成,按照工业生产需求快速创造全新的蛋白质催化剂,实现各种自然界生物无法催化的生物化学反应。尽管新基因设计技术展现了激动人心的应用前景,但是目前该技术还存在设计成功率不高、酶催化活性较低、合成成本较高等科技挑战。未来随着合成生物学技术的快速发展,设计、改造、合成和筛选等技术将融合为一体,为新基因设计与创建带来全新的发展机遇。     

On the origin and evolution of the genetic code. II. Origin of the genetic code as a primordial collector language. The pairing-release hypothesis.

The genetic code is treated as a language used by primordial “collector societies” of tRNA molecules (meaning: societies of RNA molecules specialized in the collection of amino acids and possibly other molecular objects), as a means to organize the delivery of collected material. Its origin is ascribed to the utilization of the complementarity between each tRNA and the genome segment from which it was originally copied, as a means to identify by annealing operations the tRNA molecules returning from their collection trips, and elicit the release of the amino acids they are carrying (the pairing release hypothesis).The gradual conversion of tRNA complements into codon-triplets in the regions of the primordial RNA genomes which specialized in the task of directing the delivery of amino acids by returning tRNA molecules, is ascribed to the removal of genetic redundancy in a gradual reorganization process.A reconstruction of the codon-triplets in one of the earliest genetic codes is attempted by the wobbling reintroduction procedure used in a preceding paper.     

On the physico-chemical rationale of the genetic code

We analysed two different and seemingly independent aspects of protein biosynthesis: the primary structure of codons and the reactivity of aminoacyl groups. This analysis revealed that more reactive aminoacyl groups correspond to less stable codon-anticodon complexes. The possible meaning of such a correlation is discussed in terms of the kinetic proofreading theory.     

Origin, evolution and genetic effects of nuclear insertions of organelle DNA

In eukaryotes, nuclear genomes are subject to an influx of DNA from mitochondria and plastids. The nuclear insertion of organellar sequences can occur during the illegitimate repair of double-stranded breaks. After integration, nuclear organelle DNA is modified by point mutations, and by deletions. Insertion of organelle DNA into nuclear genes is not rare and can potentially have harmful effects. In humans, some insertions of nuclear mitochondrial DNA are associated with heritable diseases. It remains to be determined whether nuclear organelle DNA can contribute beneficially to gene evolution.     

Origin and evolution of binucleate cells in cultures of HEp-2 cells

Abstract. The origin and evolution of binucleate cells in cultures of HEp-2 cells have been studied by means of interval photography and time-lapse video-recording. Binuc leate cells most frequently formed by the fusion of two sister cells born in a previous mitosis. The study of binucleate cells has shown that they are a cellular type able to successfully undergo mitosis. However, the mitosis may be bipolar, tripolar or multi-polar. The daughter cells arising from these divisions do not follow a clear pattern in the number of nuclei they have, instead showing a wide range of possibilities.