The sperm ultrastructure of Caurinus dectes Russell (Mecoptera: Boreidae) and its phylogenetic implications.

The sperm structure of the enigmatic mecopteran species Caurinus dectes (Boreidae) is described for the first time. Diagnostic features are the bi-layered acrosome, a cylindric nucleus provided with two longitudinal opposite grooves, and a simple 9 + 2 axoneme which degenerates in the posterior tail end. The results are conform with the monophyly of Mecoptera including Boreidae. A possible autapomorphy of the order is the presence of the two longitudinal opposite grooves along the nucleus, and the presence of two electron-dense fibres beneath the axoneme. Some apparently plesiomorphic features are preserved in the sperm of Caurinus. Features characterizing the distal part of the flagellum, including the presence of an axial cylindrical structure and the distinctive type of axoneme degeneration, are potential synapomorphies of Caurinus and Boreus, i.e. autapomorphic traits of Boreidae.

Unmasking the redundancy between Cdk1 and Cdk2 at G2 phase in human cancer cell lines.

A series of studies published in 2003 has challenged the essentiality of Cdk2. A recently published work indicates that cyclin E-Cdk1 compensates for Cdk2's function at G1/S transition in Cdk2(-/-) Mefs. In this study, we uncovered a redundant mechanism between Cdk1 and Cdk2 at G2 in multiple cancer cell lines. When either Cdk2 or Cdk1 is ablated using RNAi, there were complex shifts of cyclin A towards its reciprocal partner, i.e., when Cdk2 is ablated, cyclin A redistributes to Cdk1; when Cdk1 is ablated, cyclin A forms more abundant complexes with Cdk2. Further, cyclin B redistributes to Cdk2 upon Cdk1 knockdown. These redistributions bring about increased kinase activities of corresponding complexes. Elimination of the compensatory mechanism by knockdown of both Cdk1 and Cdk2 using RNAi reveals phenotypes at G2 phase. The results suggest that the redistributed complexes contribute to the cyclin B-Cdk1 activation when either Cdk1 or Cdk2 alone is ablated and this redundancy masks Cdk2's role when Cdk2 is singly ablated. It is also worth noting that the predominant G2 arrest described here, unlike those Cdk1-Cdk2 double ablated Mefs, raises a question of whether different Cdk activities are required for G1/S or G2/M progression in normal vs. cancer cells.

Gene silencing of CENP-E by small interfering RNA in HeLa cells leads to missegregation of chromosomes after a mitotic delay.

Centromeric protein-E (CENP-E) is a kinesin-like motor protein required for chromosome congression at prometaphase. Functional perturbation of CENP-E by various methods results in a consistent phenotype, i.e., unaligned chromosomes during mitosis. One unresolved question from previous studies is whether cells complete mitosis or sustain mitotic arrest in the presence of unaligned chromosomes. Using RNA interference and video-microscopy, we analyzed the dynamic process of mitotic progression of HeLa(H2B)-GFP cells lacking CENP-E. Our results demonstrate that these cells initiated anaphase after a delayed mitotic progression due to the presence of unaligned chromosomes. In some dividing cells, unaligned chromosomes are present during anaphase, causing nondisjunction of some sister chromatids producing aneuploid daughter cells. Unlike in Xenopus extract, the loss of CENP-E in HeLa cells does not impair gross checkpoint activation because cells were arrested in mitosis in response to microtubule-interfering agents. However, the lack of CENP-E at kinetochores reduced the hyperphosphorylation of BubR1 checkpoint protein during mitosis, which may explain the loss of sensitivity of a cell to a few unaligned chromosomes in the absence of CENP-E. We also found that presynchronization with nocodazole sensitizes cells to the depletion of CENP-E, leading to more unaligned chromosomes, longer arrest, and cell death.