[超物种遗传系统]。

Pub Date : 2014-07-01
N A Provorov, I A Tikhonovich
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引用次数: 0

摘要

多种生物的遗传整合产生了三种类型的超物种遗传系统:宏基因组(占据一定生态位的微生物群落的遗传因子集合)、共生基因组(伴侣共生基因的功能整合系统)和全基因组(共生起源生物的整个遗传系统)。宏基因组的完整性是基于共同进化生物中基因的交叉调控和水平转移,在土壤微生物群落中伴随着稳定的细胞外DNA库的维持。共生基因组的形成与高度特异性的伴侣信号相互作用有关,这些信号相互作用负责基于特化的细胞和组织结构的联合代谢途径的发展。共生基因组向全基因组的转变是由于内共生基因从微共生体转移到它们的宿主。在共生细菌中,这些转变与多组分、还原和基本基因组的建立相结合,分别揭示了生态强制性共生体、遗传强制性共生体和细胞器的基因组。它们的进化与宿主传播微共生体的严格程度有关,从伪垂直传播(通过环境)增加到跨胚胎传播(通过胚胎和周围组织)和跨卵巢传播(通过生殖细胞),并在细胞器的细胞质遗传中达到高潮。我们提出在土壤宏基因组受寄主控制的基础上,内生植物共生基因组通过参与微生物群落的群体感应自动调节而产生的假说。
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[Super-species genetic systems].

Genetic integration of diverse organisms results in generation of three types of the super-species systems of heredity: metagenome (set of genetic factors of the microbial community which occupies a certain ecological niche), symbiogenome (functionally integrated system of the partners' symbiotic genes) and hologenome (entire hereditary system of a symbiotically originated organism). The integrity of metagenome is based on the cross-regulation and horizontal transfer of genes in co-evolving organisms which in the soil microbial communities are accompanied by maintenance of the stable extracellular DNA pool. Formation of symbiogenome is related to the highly specific partners' signaling interactions which are responsible for development of the joint metabolic pathways based on the specialized cellular and tissue structures. Transitions of symbiogenome into hologenome are due to the endosymbiotic gene transfer from microsymbionts to their hosts. In symbiotic bacteria, these transitions are coupled with establishments of multi-component, reduced and rudimentary genomes revealed for the ecologically obligatory symbionts, genetically obligatory symbionts, and cellular organelles, respectively. Their evolution is related to the stringency of transmission of microsymbionts by hosts increased from pseudo-vertical (via environment) to the trans-embryonic (via embryos and the surrounding tissues) and trans-ovarian transmission (via germ cells) which are culminated in the cytoplasmic inheritance of cellular organelles. We suggest the hypothesis about generation of endophytic plant symbiogenome on the basis of soil metagenome subjected to the control of host by its involvement into the quorum sensing auto-regulation of microbial community.

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