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Related Concept Videos

The Evidence for Evolution02:55

The Evidence for Evolution

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Genetic variations accumulating within populations over generations give rise to biological evolution. Evolutionary changes can result in the formation of novel varieties and entire new species. These changes are responsible for the diverse forms of life inhabiting the planet. The evidence for evolution suggests that all living organisms descended from common ancestors.
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Evolutionary Relationships through Genome Comparisons02:54

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Genome comparison is one of the excellent ways to interpret the evolutionary relationships between organisms. The basic principle of genome comparison is that if two species share a common feature, it is likely encoded by the DNA sequence conserved between both species. The advent of genome sequencing technologies in the late 20th century enabled scientists to understand the concept of conservation of domains between species and helped them to deduce evolutionary relationships across diverse...
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Eukaryotic Evolution01:24

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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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In a population that is not at Hardy-Weinberg equilibrium, the frequency of alleles changes over time. Therefore, any deviations from the five conditions of Hardy-Weinberg equilibrium can alter the genetic variation of a given population. Conditions that change the genetic variability of a population include mutations, natural selection, non-random mating, gene flow, and genetic drift (small population size).
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Daily Transfers, Archiving Populations, and Measuring Fitness in the Long-Term Evolution Experiment with Escherichia coli
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Experimental Evolution in a Warming World: The Omics Era.

Marta A Santos1,2, Ana Carromeu-Santos2, Ana S Quina2,3

  • 1CE3C-Centre for Ecology, Evolution and Environmental Changes & CHANGE, Global Change and Sustainability Institute, Lisboa, Portugal.

Molecular Biology and Evolution
|July 22, 2024
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Summary
This summary is machine-generated.

Understanding genetic adaptation to heat is crucial for predicting climate change impacts on biodiversity. Evolve and resequence studies reveal complex genetic bases for thermal adaptation, but results vary across studies and taxa.

Keywords:
climate changeevolve and resequenceexperimental evolutiongenomicsthermal adaptationtranscriptomics

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Area of Science:

  • Evolutionary biology
  • Genetics
  • Climate change research

Background:

  • Predicting species' responses to climate change requires understanding genetic adaptation to thermal variation.
  • Experimental evolution, particularly evolve and resequence (E&R) studies, is a powerful tool for investigating the genetic basis of adaptation.
  • Despite a rise in E&R studies on thermal adaptation, knowledge integration remains limited.

Purpose of the Study:

  • To review and synthesize findings from thermal evolve and resequence studies.
  • To identify key trends and knowledge gaps in the genetic basis of thermal adaptation.
  • To propose methodological improvements for future research.

Main Methods:

  • Literature review of experimental evolution studies using high-throughput resequencing.
  • Analysis of trends in genetic architecture and targets of selection in thermal adaptation.
  • Identification of research gaps concerning taxa diversity, environmental relevance, and trait integration.

Main Results:

  • Thermal adaptation is often highly polygenic, involving many genes.
  • Candidate genes under selection show little consistency across different studies.
  • Adaptive responses appear to be largely specific to particular environments.

Conclusions:

  • Future research should broaden taxa diversity and employ more dynamic, ecologically relevant thermal environments.
  • Integrating genomic data with life history and behavioral traits is essential for a complete genotype-phenotype understanding.
  • Standardizing methodologies and leveraging new technologies will enhance the study of thermal adaptation.