Open AccessChromatin Evolution and Molecular Drive in Speciation
Author(s) -
Kyoichi Sawamura
Publication year - 2011
Publication title -
international journal of evolutionary biology
Language(s) - English
Resource type - Journals
eISSN - 2090-8032
pISSN - 2090-052X
DOI - 10.1155/2012/301894
Subject(s) - biology , sterility , chromatin , genetic algorithm , heterochromatin , centromere , evolutionary biology , genetics , meiosis , gene , chromosome
Are there biological generalities that underlie hybrid sterility or inviability? Recently, around a dozen “speciation genes” have been identified mainly in Drosophila , and the biological functions of these genes are revealing molecular generalities. Major cases of hybrid sterility and inviability seem to result from chromatin evolution and molecular drive in speciation. Repetitive satellite DNAs within heterochromatin, especially at centromeres, evolve rapidly through molecular drive mechanisms (both meiotic and centromeric). Chromatin-binding proteins, therefore, must also evolve rapidly to maintain binding capability. As a result, chromatin binding proteins may not be able to interact with chromosomes from another species in a hybrid, causing hybrid sterility and inviability.
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