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相关概念视频

Prokaryotic Cells01:51

Prokaryotic Cells

144.2K
Prokaryotes are small unicellular organisms that include the domains—Archaea and Bacteria. Bacteria include many common organisms, such as Salmonella and E. coli, while the Archaea include extremophiles that live in harsh environments, such as volcanic springs.
Like eukaryotic cells, all prokaryotic cells are surrounded by a plasma membrane, have genetic material in the form of single, circular DNA, a cytoplasm that fills the interior of the cell, and ribosomes that synthesize proteins....
144.2K
Genomic DNA in Prokaryotes00:46

Genomic DNA in Prokaryotes

51.2K
The genome of most prokaryotic organisms consists of double-stranded DNA organized into one circular chromosome in a region of cytoplasm called the nucleoid. The chromosome is tightly wound, or supercoiled, for efficient storage. Prokaryotes also contain other circular pieces of DNA called plasmids. These plasmids are smaller than the chromosome and often carry genes that confer adaptive functions, such as antibiotic resistance.
Genomic Diversity in Bacteria
Although bacterial genomes are much...
51.2K
Genomic DNA in Eukaryotes00:58

Genomic DNA in Eukaryotes

54.5K
Eukaryotes have large genomes compared to prokaryotes. To fit their genomes into a cell, eukaryotic DNA is packaged extraordinarily tightly inside the nucleus. To achieve this, DNA is tightly wound around proteins called histones, which are packaged into nucleosomes that are joined by linker DNA and coil into chromatin fibers. Additional fibrous proteins further compact the chromatin, which is recognizable as chromosomes during certain phases of cell division.
54.5K
Comparing Mitochondrial, Chloroplast, and Prokaryotic Genomes02:16

Comparing Mitochondrial, Chloroplast, and Prokaryotic Genomes

17.5K
The present-day mitochondrial and chloroplast genomes have retained some of the characteristics of their ancestral prokaryotes and also have acquired new attributes during their evolution within eukaryotic cells. Like prokaryotic genomes, mitochondrial and chloroplast genomes neither bind with histone-like proteins nor show complex packaging into chromosome-like structures, as observed in eukaryotes. Unlike mitotic cell divisions observed in eukaryotic cells, mitochondria and chloroplasts...
17.5K
Prokaryotic Cells01:28

Prokaryotic Cells

53.3K
Prokaryotes are small unicellular organisms that include the domains — Archaea and Bacteria. Bacteria include many common microorganisms, such as Salmonella and E. coli, while the Archaea include extremophiles that live in harsh environments, such as volcanic springs.
Like eukaryotic cells, all prokaryotic cells are surrounded by a plasma membrane, have genetic material in the form of single, circular DNA, a cytoplasm that fills the interior of the cell, and ribosomes that synthesize...
53.3K
Evolution of Microbial Genome01:08

Evolution of Microbial Genome

56
Microbial genome evolution is a highly dynamic process shaped by continual gene gain and loss across species and strains. This genomic flexibility allows microorganisms to adapt rapidly to environmental pressures and interactions with other organisms. Central to understanding this diversity is the distinction between the core and pan genomes.The core genome comprises the genes shared by all sampled strains of a species, representing essential functions needed for fundamental cellular processes.
56

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相关实验视频

Updated: Apr 13, 2026

Optimization and Comparative Analysis of Plant Organellar DNA Enrichment Methods Suitable for Next-generation Sequencing
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Optimization and Comparative Analysis of Plant Organellar DNA Enrichment Methods Suitable for Next-generation Sequencing

Published on: July 28, 2017

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基因组和细胞复杂性从共生简单性.

Seth R Bordenstein1

  • 1Departments of Biological Sciences and Pathology, Microbiology, and Immunology Vanderbilt University, Nashville, TN 37235, USA.

Cell
|September 13, 2014
PubMed
概括

生物学家发现,稳定的动物-微生物伙伴关系在没有获得新的遗传物质的情况下扩展了其复杂的网络. 这凸显了生物学的共生关系的复杂和不断变化的性质.

科学领域:

  • 共生微生物学的共生微生物.
  • 动物与微生物的相互作用
  • 进化生物学是进化的生物学.

背景情况:

  • 共生微生物对动物生活有着深刻的影响.
  • 了解这些关系揭示了大自然在生物尺度上的相互联系.
  • 动物-微生物互惠关系对于生态稳定至关重要.

研究的目的:

  • 调查已建立的动物-微生物相互主义中基因间网络扩张背后的机制.
  • 为了确定网络复杂性的增加是否需要添加新的基因组.

主要方法:

  • 对长期存在的动物-微生物互惠关系进行比较基因组分析.
  • 在已建立的共生关系中调查网络动态.

主要成果:

  • 一个稳定的,长期的动物-微生物互惠关系表明其基因间网络的增加.
  • 这种网络扩张发生在没有添加任何新基因组的情况下.
  • 这项研究强调了共生网络的可塑性.

结论:

  • 在共生关系中的基因间网络可以在没有遗传增强的情况下增加复杂性.
  • 这一发现加深了我们对相互合作伙伴关系中的进化策略的理解.

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Fluorescence Live-cell Imaging of the Complete Vegetative Cell Cycle of the Slow-growing Social Bacterium Myxococcus xanthus

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Cell-cell Fusion of Genome Edited Cell Lines for Perturbation of Cellular Structure and Function
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Last Updated: Apr 13, 2026

Optimization and Comparative Analysis of Plant Organellar DNA Enrichment Methods Suitable for Next-generation Sequencing
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Optimization and Comparative Analysis of Plant Organellar DNA Enrichment Methods Suitable for Next-generation Sequencing

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Fluorescence Live-cell Imaging of the Complete Vegetative Cell Cycle of the Slow-growing Social Bacterium Myxococcus xanthus
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Fluorescence Live-cell Imaging of the Complete Vegetative Cell Cycle of the Slow-growing Social Bacterium Myxococcus xanthus

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Cell-cell Fusion of Genome Edited Cell Lines for Perturbation of Cellular Structure and Function

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  • 大自然的网络主义表明了在各种生物层面上的适应性.