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Evolutionary Relationships through Genome Comparisons02:54

Evolutionary Relationships through Genome Comparisons

7.1K
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...
7.1K
Gene Evolution - Fast or Slow?02:05

Gene Evolution - Fast or Slow?

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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...
8.3K
Gene Evolution - Fast or Slow?02:05

Gene Evolution - Fast or Slow?

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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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Synteny and Evolution02:31

Synteny and Evolution

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John H. Renwick first coined the term “synteny” in 1971, which refers to the genes present on the same chromosomes, even if they are not genetically linked. The species with common ancestry tend to show conserved syntenic regions. Therefore, the concept of synteny is nowadays used to describe the evolutionary relationship between species.
Around 80 million years ago, the human and mice lineages diverged from the common ancestor. During the course of evolution, the ancestral...
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Genetics of Speciation02:16

Genetics of Speciation

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Speciation is the evolutionary process resulting in the formation of new, distinct species—groups of reproductively isolated populations.
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Related Experiment Video

Updated: Mar 1, 2026

Following the Dynamics of Structural Variants in Experimentally Evolved Populations
04:52

Following the Dynamics of Structural Variants in Experimentally Evolved Populations

Published on: February 3, 2023

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TRANSLATING BETWEEN MICROEVOLUTIONARY PROCESS AND MACROEVOLUTIONARY PATTERNS: THE CORRELATION STRUCTURE OF

Thomas F Hansen1, Emília P Martins2

  • 1University of Oslo, Division of Zoology, Department of Biology, P. O. Box 1050, Blindern, N 0316, Oslo 3, Norway.

Evolution; International Journal of Organic Evolution
|June 1, 2017
PubMed
Summary
This summary is machine-generated.

Evolutionary models reveal how microevolutionary forces shape species

Keywords:
Comparative methodevolutionphylogenetic analysispopulation geneticsquantitative geneticssystematics

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Using Phylogenetic Analysis to Investigate Eukaryotic Gene Origin
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Using Phylogenetic Analysis to Investigate Eukaryotic Gene Origin
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Area of Science:

  • Evolutionary biology
  • Phylogenetics
  • Quantitative genetics

Background:

  • Closely related species often share phenotypic similarities due to common evolutionary histories.
  • The degree of similarity is influenced by phylogenetic structure and the nature of evolutionary changes.
  • Understanding microevolutionary processes is key to interpreting macroevolutionary patterns.

Purpose of the Study:

  • To translate models of microevolutionary change into predictable macroevolutionary patterns.
  • To derive the expected structure of phenotypic covariances between species.
  • To explore how different microevolutionary forces influence covariance structure.

Main Methods:

  • Developed a framework to link microevolutionary models to macroevolutionary outcomes.
  • Analyzed phenotypic covariance structures resulting from various evolutionary models.
  • Included models of genetic drift, directional selection, stabilizing selection, environmental change, and punctuated evolution.

Main Results:

  • Stabilizing selection predicts an exponential decrease in interspecific covariance with phylogenetic distance.
  • This contrasts with the commonly assumed linear decrease in covariance.
  • Linear covariance decrease can arise from diverse processes including drift, directional selection, and punctuated evolution.

Conclusions:

  • The study provides a novel framework for understanding the relationship between micro- and macroevolutionary processes.
  • The findings challenge assumptions in comparative and systematic methods regarding covariance patterns.
  • The framework supports advancements in phylogenetic reconstruction, evolutionary process inference, and statistical analyses of comparative data.