Separation anxiety at the centromere.

During mitosis, replicated sister-chromatids must maintain cohesion as they attach to the mitotic spindle. At anaphase, cohesion is lost simultaneously along the entire chromosome, releasing sisters from one another and allowing them to segregate to opposite poles. During meiosis, sisters separate in a two-step process. At anaphase of meiosis I, cohesion is lost along the chromosome arms but is maintained at centromeric regions. Not until meiosis II are sister chromatids able to break the connection at the centromere and separate away from one another. Recent studies suggest that the centromere exhibits dynamics that are very different compared with those of the chromatid arms during both mitosis and meiosis. This review discusses the nature of the specialized chromatid cohesion seen at the centromere.

The endocycle controls nurse cell polytene chromosome structure during Drosophila oogenesis.

Polytene chromosomes exhibit intricate higher order chromatin structure that is easily visualized due to their precisely aligned component strands. However, it remains unclear if the same factors determine chromatin organization in polyploid and diploid cells. We have analyzed one such factor, the cell cycle, by studying changes in Drosophila nurse cell chromosomes throughout the 10 to 12 endocycles of oogenesis. We find that nurse cells undergo three distinct types of endocycle whose parameters are correlated with chromosome behavior. The first four endocycles support complete DNA replication; poorly banded polytene euchromatin progressively condenses during the late S phases to produce blob-like chromosomes. During the unique fifth endocycle, an incomplete late S phase is followed by a mitosis-like state during which the 64C chromosomes dissociate into 32 chromatid pairs held together by unreplicated regions. All the subsequent endocycles lack any late S phase; during these cycles a new polytene chromosome grows from each 2C chromatid pair to generate 32-ploid polytene nuclei. These observations suggest that euchromatin begins to condense during late S phase and that nurse cell polytene chromosome structure is controlled by regulating whether events characteristic of late S and M phase are incorporated or skipped within a given endocycle.

A hotspot for the Drosophila gypsy retroelement in the ovo locus.

The Drosophila retroelement gypsy has a number of unusual features including an unusual LTR terminal sequence and an apparent target sequence preference. The ovo locus is a known hotspot for gypsy insertion. We examined the target sequence preference of gypsy within ovo by isolating 26 new insertions and sequencing the gypsy/ovo junctions. Insertions were found at multiple sites within the ovo locus. The insertions clustered within an approximately 150 bp region in the non-translated region of the ovo beta transcript, with most insertions falling within the first intron. There were seven sites of insertion within this region and these mostly conform to the consensus sequence YRYRYR (where Y = pyrimidine and R = purine). However, this target sequence is at best necessary but not sufficient to specify a hotspot, as there were several other sequences conforming to this consensus in the ovo locus that were not hit. The results indicate that gypsy may have a higher degree of target specificity than most infectious LTR retroelements.