The nurse's lived experience of becoming an interprofessional leader.

In the current complex health care environment, nurses in all practice settings are called on to be leaders in advocating for a healthier future. Health care reform, the rise of the evidence-based practice movement, and the proliferation of new educational options are opening opportunities as never before for nurses to expand their leadership capacity to an interprofessional level. This interpretive phenomenological study conducted with eight nurse participants describes their experience of becoming an interprofessional leader.

Functional screen of human MCM2-7 variant alleles for disease-causing potential.

Origin licensing builds a fundamental basis for genome stability in DNA replication. Recent studies reported that deregulation of origin licensing is associated with replication stress in precancerous lesions. The heterohexameric complex of minichromosome maintenance proteins (MCM2-7 complex) plays an essential role in origin licensing.

Consideration of digitization precision when building local coordinate axes for a foot model.

This study investigated whether points digitized for the purpose of embedding coordinate systems into the foot accurately represented the orientation of the bone described. Eight complete data sets were collected from 9 adult cadaver specimens. Palpable landmarks defined 5 segments to include the calcaneus, navicular, medial cuneiform, first metatarsal, and hallux.

In vivo analysis of chromosome condensation in Saccharomyces cerevisiae.

Although chromosome condensation in the yeast Saccharomyces cerevisiae has been widely studied, visualization of this process in vivo has not been achieved. Using Lac operator sequences integrated at two loci on the right arm of chromosome IV and a Lac repressor-GFP fusion protein, we were able to visualize linear condensation of this chromosome arm during G2/M phase. As previously determined in fixed cells, condensation in yeast required the condensin complex.

A viable allele of Mcm4 causes chromosome instability and mammary adenocarcinomas in mice.

Mcm4 (minichromosome maintenance-deficient 4 homolog) encodes a subunit of the MCM2-7 complex (also known as MCM2-MCM7), the replication licensing factor and presumptive replicative helicase. Here, we report that the mouse chromosome instability mutation Chaos3 (chromosome aberrations occurring spontaneously 3), isolated in a forward genetic screen, is a viable allele of Mcm4. Mcm4(Chaos3) encodes a change in an evolutionarily invariant amino acid (F345I), producing an apparently destabilized MCM4.

Topoisomerase II checkpoints: universal mechanisms that regulate mitosis.

Checkpoint controls confer order to the cell cycle and help prevent genome instability. Here we discuss the Topoisomerase II (Decatenation) Checkpoint which functions to regulate mitotic progression so that chromosomes can be efficiently condensed in prophase and can be segregated with high fidelity in anaphase.

A mitotic topoisomerase II checkpoint in budding yeast is required for genome stability but acts independently of Pds1/securin.

Topoisomerase II (Topo II) performs topological modifications on double-stranded DNA molecules that are essential for chromosome condensation, resolution, and segregation. In mammals, G2 and metaphase cell cycle delays induced by Topo II poisons have been proposed to be the result of checkpoint activation in response to the catenation state of DNA. However, the apparent lack of such controls in model organisms has excluded genetic proof that Topo II checkpoints exist and are separable from the conventional DNA damage checkpoint controls.

Evidence that the yeast spindle assembly checkpoint has a target other than the anaphase promoting complex.

The spindle assembly checkpoint monitors biorientation of chromosomes on the metaphase spindle and inhibits the Anaphase Promoting Complex (APC) specificity factor Cdc20. If APC-Cdc20 is the sole target of the spindle checkpoint, then cells lacking APC and its targets, B-type cyclin and securin, would lack spindle checkpoint function. We tested this hypothesis in yeast cells that are APC-null.

Regulated separation of sister centromeres depends on the spindle assembly checkpoint but not on the anaphase promoting complex/cyclosome.

Key to faithful genetic inheritance is the cohesion between sister centromeres that physically links replicated sister chromatids and is then abruptly lost at the onset of anaphase. Misregulated cohesion causes aneuploidy, birth defects and perhaps initiates cancers. Loss of centromere cohesion is controlled by the spindle checkpoint and is thought to depend on a ubiquitin ligase, the Anaphase Promoting Complex/Cyclosome (APC).

MRX (Mre11/Rad50/Xrs2) mutants reveal dual intra-S-phase checkpoint systems in budding yeast.

The intra-S-phase checkpoint is a signaling pathway that induces slow DNA replication in the presence of DNA damage. In humans, defects in this checkpoint pathway might account for phenotypes seen in autosomal recessive diseases including ataxia telangiectasia-like disorder and Nijmegen breakage syndrome, where MRN complex components,Mre11 and Nbs1, are mutated. Here we provide evidence that the equivalent budding yeast complex, MRX (Mre11/Rad50/Xrs2), is not required for the intra-S-phase checkpoint in response to DNA alkylation damage, but is required in the presence of double-stranded DNA breaks.

Cdc20 in S-phase: the Banquo at replication's banquet.

The Anaphase Promoting Complex/Cyclosome (APC/C) is an E3 ubiquitin ligase that covalently attaches ubiquitins onto proteins to target them for proteolysis by the 26S proteasome. During mitosis, the APC/C is instrumental in allowing the cell to enter and exit from mitosis. The APC/C accomplishes this by using different specificity factors to recognize, interact with, and ubiquitylate key proteins that block cell cycle progression.

S-phase checkpoint controls mitosis via an APC-independent Cdc20p function.

Cells divide with remarkable fidelity, allowing complex organisms to develop and possess longevity. Checkpoint controls contribute by ensuring that genome duplication and segregation occur without error so that genomic instability, associated with developmental abnormalities and a hallmark of most human cancers, is avoided. S-phase checkpoints prevent cell division while DNA is replicating.