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相关概念视频

Convergent Evolution01:54

Convergent Evolution

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Evolution shapes the features of organisms over time, ensuring that they are suited for the environments in which they live. Sometimes, selection pressure leads to the rise of similar but unrelated adaptations in organisms with no recent common ancestors, a process known as convergent evolution.
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The genomes of eukaryotes are punctuated by long stretches of sequence which do not code for proteins or RNAs. Although some of these regions do contain crucial regulatory sequences, the vast majority of this DNA serves no known function. Typically, these regions of the genome are the ones in which the fastest change, in evolutionary terms, is observed, because there is typically little to no selection pressure acting on these regions to preserve their sequences.
In contrast, regions which code...
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Overview of Transposition and Recombination02:13

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Transposons make up a significant part of genomes of various organisms. Therefore, it is believed that transposition played a major evolutionary role in speciation by changing genome sizes and modifying gene expression patterns. For example, in bacteria, transposition can lead to conferring antibiotic resistance. Movement of transposable elements within the genetic pool of pathogenic bacteria can aid in transfer of antibiotic-resistant genetic elements. In eukaryotes, transposons can carry out...
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Eukaryotic Evolution01:24

Eukaryotic Evolution

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The endosymbiont theory is the most widely accepted theory of eukaryotic evolution; however, its progression is still somewhat debated. According to the nucleus-first hypothesis, the ancestral prokaryote first evolved a membrane to enclose DNA and form the nucleus. Conversely, the mitochondria-first hypothesis suggests that the nucleus was formed after endosymbiosis of mitochondria.
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Evolutionary Processes in Microbes01:26

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Microbial evolution occurs rapidly due to short generation times and a variety of genetic processes, including horizontal gene transfer, mutation, recombination, and genetic drift. These mechanisms collectively enable microbes to adapt swiftly to changing environments.Horizontal gene transfer (HGT) allows genes to move between different species and occurs through three main mechanisms: conjugation, transformation, and transduction. Conjugation involves direct cell-to-cell contact for DNA...
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Evolution of New Traits in Microbes01:24

Evolution of New Traits in Microbes

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Microorganisms evolve rapidly due to their large population sizes and short generation times, often exhibiting measurable changes within days under laboratory conditions. Natural selection acts on standing genetic variation, enabling the retention and amplification of beneficial traits that confer fitness advantages in changing environments.Adaptive Pigment Regulation in RhodobacterIn Rhodobacter, a genus of purple non-sulfur bacteria, light-harvesting pigments such as bacteriochlorophyll and...
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相关实验视频

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Migratory Behavior of Cells Generated in Ganglionic Eminence Cultures
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Migratory Behavior of Cells Generated in Ganglionic Eminence Cultures

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中心层复杂性的主要进化过渡.

Harmit S Malik1, Steven Henikoff

  • 1Division of Basic Sciences, Fred Hutchinson Cancer Research Center, Seattle, WA 98109, USA. hsmalik@fhcrc.org

Cell
|September 22, 2009
PubMed
概括
此摘要是机器生成的。

中粒体对于染色体分离至关重要,其复杂性差异很大. 这项研究表明,祖先的表观遗传中心体进化为简单的点中心体和复杂的数组由于介质驱动.

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Following the Dynamics of Structural Variants in Experimentally Evolved Populations
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科学领域:

  • 遗传学 是一个遗传学.
  • 进化生物学 进化生物学
  • 分子生物学分子生物学

背景情况:

  • 在细胞分裂过程中,中间体对精确的染色体分离至关重要.
  • 中心体结构表现出了显著的多样性,从简单的点中心体到大型卫星DNA阵列.
  • 中心分子复杂性的进化起源和多样化仍然不太清楚.

研究的目的:

  • 提出一个统一的假设,用于中心分子复杂性的演变.
  • 为了解释从表观遗传学定义的祖先中间体过渡到各种现代形式.
  • 为了将中间体进化与中间体驱动和性冲突联系起来.

主要方法:

  • 对比基因组学分析.比较基因组学分析.
  • 中心分子相关蛋白质的遗传学重建.
  • 表观遗传遗传和介质驱动的理论建模.

主要成果:

  • 祖先的中间体被提议通过表观遗传来定义.
  • 简单的点心体可能起源于自私的遗传元素.
  • 植物和动物中复杂的中间体可能在强大的选择性压力下从介质驱动下演变.

结论:

  • 中心分子进化是由表观遗传调节和自私的遗传元素形成的.
  • 介质驱动,特别是在雌性介质变化中,为中粒体进化和多样化提供了强大的选择力.
  • 了解中心分子复杂性需要考虑结构和进化动态.