Drosophila melanogaster chromosome 4 is an anomaly because of its small size, chromatin structure, and most notably its lack of crossing over during meiosis. Earlier ideas about the absence of crossovers on 4 hypothesize that these unique characteristics function to prevent crossovers. Here, we explore hypotheses about the absence of crossovers on 4, how these have been addressed, and new insights into the mechanism behind this suppression. We review recently published results that indicate that global crossover patterning, in particular the centromere effect, make a major contribution to the prevention of crossovers on 4
We study the evolutionary effects of reduced recombination on the Drosophila melanogaster genome, an...
Meiotic crossing over ensures proper segregation of homologous chromosomes and generates genotypic d...
While major changes to chromosomal form is generally deleterious, karyotypes are not static. Major c...
In most sexually reproducing organisms, crossover formation between homologous chromosomes is necess...
Meiotic crossovers are distributed nonrandomly across the genome. Classic studies in Drosophila sugg...
Crossover events are beneficial for organisms because they create genetic variation that can be pass...
The Bloom syndrome helicase, BLM, has numerous functions that prevent mitotic crossovers. We used un...
Meiosis is the process by which homologous chromosomes segregate to form four, genetically diverse h...
Under ordinary conditions there is so little crossing over in the fourth chromosome of Drosophila me...
The present study is concerned chiefly with the behavior of a duplicating chromosome derived from th...
Meiotic recombination gives rise to crossovers, which are required in most organisms for the faithfu...
Meiosis is an essential process to halve an organism’s genome in preparation for transmission to the...
Recombination suppression in chromosomal inversion heterozygotes is a well-known but poorly understo...
Meiotic recombination is a highly regulated process necessary for promoting proper chromosome disjun...
The fourth chromosome of Drosophila melanogaster has a number of unique properties that make it a co...
We study the evolutionary effects of reduced recombination on the Drosophila melanogaster genome, an...
Meiotic crossing over ensures proper segregation of homologous chromosomes and generates genotypic d...
While major changes to chromosomal form is generally deleterious, karyotypes are not static. Major c...
In most sexually reproducing organisms, crossover formation between homologous chromosomes is necess...
Meiotic crossovers are distributed nonrandomly across the genome. Classic studies in Drosophila sugg...
Crossover events are beneficial for organisms because they create genetic variation that can be pass...
The Bloom syndrome helicase, BLM, has numerous functions that prevent mitotic crossovers. We used un...
Meiosis is the process by which homologous chromosomes segregate to form four, genetically diverse h...
Under ordinary conditions there is so little crossing over in the fourth chromosome of Drosophila me...
The present study is concerned chiefly with the behavior of a duplicating chromosome derived from th...
Meiotic recombination gives rise to crossovers, which are required in most organisms for the faithfu...
Meiosis is an essential process to halve an organism’s genome in preparation for transmission to the...
Recombination suppression in chromosomal inversion heterozygotes is a well-known but poorly understo...
Meiotic recombination is a highly regulated process necessary for promoting proper chromosome disjun...
The fourth chromosome of Drosophila melanogaster has a number of unique properties that make it a co...
We study the evolutionary effects of reduced recombination on the Drosophila melanogaster genome, an...
Meiotic crossing over ensures proper segregation of homologous chromosomes and generates genotypic d...
While major changes to chromosomal form is generally deleterious, karyotypes are not static. Major c...