Stepwise evolution of essential centromere function in a Drosophila neogene.

Evolutionarily young genes that serve essential functions represent a paradox; they must perform a function that either was not required until after their birth or was redundant with another gene. How young genes rapidly acquire essential function is largely unknown. We traced the evolutionary steps by which the Drosophila gene Umbrea acquired an essential role in chromosome segregation in D.

Phylogenomic analysis reveals dynamic evolutionary history of the Drosophila heterochromatin protein 1 (HP1) gene family.

Heterochromatin is the gene-poor, satellite-rich eukaryotic genome compartment that supports many essential cellular processes. The functional diversity of proteins that bind and often epigenetically define heterochromatic DNA sequence reflects the diverse functions supported by this enigmatic genome compartment. Moreover, heterogeneous signatures of selection at chromosomal proteins often mirror the heterogeneity of evolutionary forces that act on heterochromatic DNA.

Multiple roles for heterochromatin protein 1 genes in Drosophila.

Heterochromatin is the gene-poor, transposon-rich, late-replicating chromatin compartment that was first cytologically defined more than 70 years ago. The identification of heterochromatin protein 1 (HP1) paved the way for a molecular dissection of this important component of complex eukaryotic genomes. Although initial studies revealed HP1's key role in heterochromatin maintenance and function, more recent studies have discovered a role for HP1 in numerous processes including, surprisingly, euchromatic gene expression.

A surrogate approach to study the evolution of noncoding DNA elements that organize eukaryotic genomes.

Comparative genomics provides a facile way to address issues of evolutionary constraint acting on different elements of the genome. However, several important DNA elements have not reaped the benefits of this new approach. Some have proved intractable to current day sequencing technology.

Structure, dynamics, and evolution of centromeric nucleosomes.

Centromeres are defining features of eukaryotic chromosomes, providing sites of attachment for segregation during mitosis and meiosis. The fundamental unit of centromere structure is the centromeric nucleosome, which differs from the conventional nucleosome by the presence of a centromere-specific histone variant (CenH3) in place of canonical H3. We have shown that the CenH3 nucleosome core found in interphase Drosophila cells is a heterotypic tetramer, a "hemisome" consisting of one molecule each of CenH3, H4, H2A, and H2B, rather than the octamer of canonical histones that is found in bulk nucleosomes.

Species-specific positive selection of the male-specific lethal complex that participates in dosage compensation in Drosophila.

In many taxa, males and females have unequal ratios of sex chromosomes to autosomes, which has resulted in the invention of diverse mechanisms to equilibrate gene expression between the sexes (dosage compensation). Failure to compensate for sex chromosome dosage results in male lethality in Drosophila. In Drosophila, a male-specific lethal (MSL) complex of proteins and noncoding RNAs binds to hundreds of sites on the single male X chromosome and up-regulates gene expression.

The CNA1 histone of the ciliate Tetrahymena thermophila is essential for chromosome segregation in the germline micronucleus.

Ciliated protozoans present several features of chromosome segregation that are unique among eukaryotes, including their maintenance of two nuclei: a germline micronucleus, which undergoes conventional mitosis and meiosis, and a somatic macronucleus that divides by an amitotic process. To study ciliate chromosome segregation, we have identified the centromeric histone gene in the Tetrahymena thermophila genome (CNA1). CNA1p specifically localizes to peripheral centromeres in the micronucleus but is absent in the macronucleus during vegetative growth.

Positive selection drives the evolution of rhino, a member of the heterochromatin protein 1 family in Drosophila.

Heterochromatin comprises a significant component of many eukaryotic genomes. In comparison to euchromatin, heterochromatin is gene poor, transposon rich, and late replicating. It serves many important biological roles, from gene silencing to accurate chromosome segregation, yet little is known about the evolutionary constraints that shape heterochromatin.

Maintenance of chromatin states: an open-and-shut case.

The traditional view of chromatin envisions two states: one is 'active' and accessible to nucleases, whereas the other is 'silent' and relatively inaccessible. Recent evidence that combinations of diverse histone tail modifications represent a spectrum of chromatin states challenges this simple view. Here, we examine inter-relationships between chromatin remodeling, histone modification, DNA methylation, RNA interference, and nucleosome assembly activities.

The budding yeast Ipl1/Aurora protein kinase regulates mitotic spindle disassembly.

Ipl1p is the budding yeast member of the Aurora family of protein kinases, critical regulators of genomic stability that are required for chromosome segregation, the spindle checkpoint, and cytokinesis. Using time-lapse microscopy, we found that Ipl1p also has a function in mitotic spindle disassembly that is separable from its previously identified roles. Ipl1-GFP localizes to kinetochores from G1 to metaphase, transfers to the spindle after metaphase, and accumulates at the spindle midzone late in anaphase.

Centromere targeting element within the histone fold domain of Cid.

Centromeres require specialized nucleosomes; however, the mechanism of localization is unknown. Drosophila sp. centromeric nucleosomes contain the Cid H3-like protein.

Recurrent evolution of DNA-binding motifs in the Drosophila centromeric histone.

All eukaryotes contain centromere-specific histone H3 variants (CenH3s), which replace H3 in centromeric chromatin. We have previously documented the adaptive evolution of the Drosophila CenH3 (Cid) in comparisons of Drosophila melanogaster and Drosophila simulans, a divergence of approximately 2.5 million years.