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Inversions can happen either through ectopic recombination between repetitive sequences, or through chromosomal breakage followed by non-homologous end joining. [4] Inversions are of two types: paracentric and pericentric. Paracentric inversions do not include the centromere, and both breakpoints
Inversions that exclude the centromere are known as paracentric inversions, which result in unbalanced gametes after meiosis. [2] During prophase of meiosis I, homologous chromosomes form an inversion loop and crossover occurs. If a paracentric inversion has occurred, one of the products will be acentric, while the other product will be dicentric.
Inversion was first noted in 1822 by the French zoologist Étienne Geoffroy Saint-Hilaire, when he dissected a crayfish (an arthropod) and compared it with the vertebrate body plan. The idea was heavily criticised, but periodically resurfaced, and is now supported by some molecular embryologists.
The formation of dicentric chromosomes has been attributed to genetic processes, such as Robertsonian translocation [6] and paracentric inversion. [7] Dicentric chromosomes can have a variety of fates, including mitotic stability. [ 8 ]
In the underlying chromosomal polymorphism, the standard (ZAL2) and alternative (ZAL2m) arrangements differ by a pair of included pericentric inversions at least. ZAL2m suppresses recombination in the heterokaryotype and is evolving as a rare nonrecombining autosomal segment of the genome .
A Robertsonian translocation. The short arms of the chromosomes (shown on right) are often lost . Robertsonian translocation (ROB) is a chromosomal abnormality where the entire long arms of two different chromosomes become fused to each other.
Fold-back inversions are chimeric sequences that span head-to-head arrangements of inverted tandem-duplicated segments, and are expected to appear in BFB modified genomes. In addition, BFB induces amplification of segments of the original genome, where the number of repeats of each segment in the rearranged genome can be experimentally measured .
Such changes may involve several different classes of events, like deletions, duplications, inversions, and translocations. Usually, these events are caused by a breakage in the DNA double helices at two different locations, followed by a rejoining of the broken ends to produce a new chromosomal arrangement of genes , different from the gene ...