Inn1 and Cyk3 regulate chitin synthase during cytokinesis in budding yeasts.

The chitin synthase that makes the primary septum during cell division in budding yeasts is an important therapeutic target with an unknown activation mechanism. We previously found that the C2-domain of the Saccharomyces cerevisiae Inn1 protein plays an essential but uncharacterised role at the cleavage site during cytokinesis. By combining a novel degron allele of INN1 with a point mutation in the C2-domain, we screened for mutations in other genes that suppress the resulting defect in cell division. In this way, we identified 22 dominant mutations of CHS2 (chitin synthase II) that map to two neighbouring sites in the catalytic domain. Chs2 in isolated cell membranes is normally nearly inactive (unless protease treatment is used to bypass inhibition); however, the dominant suppressor allele Chs2-V377I has enhanced activity in vitro. We show that Inn1 associates with Chs2 in yeast cell extracts. It also interacts in a yeast two-hybrid assay with the N-terminal 65% of Chs2, which contains the catalytic domain. In addition to compensating for mutations in the Inn1 C2-domain, the dominant CHS2 alleles suppress cytokinesis defects produced by the lack of the Cyk3 protein. Our data support a model in which the C2-domain of Inn1 acts in conjunction with Cyk3 to regulate the catalytic domain of Chs2 during cytokinesis. These findings suggest novel approaches for developing future drugs against important fungal pathogens.

Conditional Budding Yeast Mutants with Temperature-Sensitive and Auxin-Inducible Degrons for Screening of Suppressor Genes.

The conditional control of protein expression is useful to characterize the function of proteins, especially of those that are essential for cell viability. Two degron-based systems, temperature-sensitive and auxin-inducible degrons, can be used to generate conditional mutants of budding yeast, simply by transforming appropriate cells with PCR-amplified DNA. We describe a protocol for the generation of temperature-sensitive and auxin-inducible degron mutants. We also show that a conditional mutant with few spontaneous revertants was generated by combining two degron systems for the Inn1 protein. Finally, we describe a suppressor screening method that uses the dual degron-Inn1 mutant to identify mutant proteins that suppress Inn1-K31A, which has a defect in cytokinesis.

miR-146a is a significant brake on autoimmunity, myeloproliferation, and cancer in mice.

Excessive or inappropriate activation of the immune system can be deleterious to the organism, warranting multiple molecular mechanisms to control and properly terminate immune responses. MicroRNAs (miRNAs), ∼22-nt-long noncoding RNAs, have recently emerged as key posttranscriptional regulators, controlling diverse biological processes, including responses to non-self. In this study, we examine the biological role of miR-146a using genetically engineered mice and show that targeted deletion of this gene, whose expression is strongly up-regulated after immune cell maturation and/or activation, results in several immune defects. Collectively, our findings suggest that miR-146a plays a key role as a molecular brake on inflammation, myeloid cell proliferation, and oncogenic transformation.