Combining Spinach-tagged RNA and gene localization to image gene expression in live yeast.

Although many factors required for the formation of export-competent mRNPs have been described, an integrative view of the spatiotemporal coordinated cascade leading mRNPs from their site of transcription to their site of nuclear exit, at a single cell level, is still partially missing due to technological limitations. Here we report that the RNA Spinach aptamer is a powerful tool for mRNA imaging in live S. cerevisiae with high spatial-temporal resolution and no perturbation of the mRNA biogenesis properties. Dedicated image processing workflows are developed to allow detection of very low abundance of transcripts, accurate quantitative dynamic studies, as well as to provide a localization precision close to 100 nm at consistent time scales. Combining these approaches has provided a state-of-the-art analysis of the osmotic shock response in live yeast by localizing induced transcription factors, target gene loci and corresponding transcripts.

Casein kinase II regulation of the Hot1 transcription factor promotes stochastic gene expression.

In Saccharomyces cerevisiae, Hog1 MAPK is activated and induces a transcriptional program in response to hyperosmotic stress. Several Hog1-responsive genes exhibit stochastic transcription, resulting in cell-to-cell variability in mRNA and protein levels. However, the mechanisms governing stochastic gene activity are not fully defined. Here we uncover a novel role for casein kinase II (CK2) in the cellular response to hyperosmotic stress. CK2 interacts with and phosphorylates the Hot1 transcription factor; however, Hot1 phosphorylation is not sufficient for controlling the stochastic response. The CK2 protein itself is required to negatively regulate mRNA expression of Hot1-responsive genes and Hot1 enrichment at target promoters. Single-cell gene expression analysis reveals altered activation of Hot1-targeted STL1 in ck2 mutants, resulting in a bimodal to unimodal shift in expression. Together, this work reveals a novel CK2 function during the hyperosmotic stress response that promotes cell-to-cell variability in gene expression.

From hypothesis to mechanism: uncovering nuclear pore complex links to gene expression.

The gene gating hypothesis put forth by Blobel in 1985 was an alluring proposal outlining functions for the nuclear pore complex (NPC) in transcription and nuclear architecture. Over the past several decades, collective studies have unveiled a full catalog of nucleoporins (Nups) that comprise the NPC, structural arrangements of Nups in the nuclear pore, and mechanisms of nucleocytoplasmic transport. With this foundation, investigations of the gene gating hypothesis have now become possible. Studies of several model organisms provide credence for Nup functions in transcription, mRNA export, and genome organization. Surprisingly, Nups are not only involved in transcriptional events that occur at the nuclear periphery, but there are also novel roles for dynamic Nups within the nucleoplasmic compartment. Several tenants of the original gene gating hypothesis have yet to be addressed. Knowledge of whether the NPC impacts the organization of the genome to control subsets of genes is limited, and the cooperating molecular machinery or specific genomic anchoring sequences are not fully resolved. This minireview summarizes the current evidence for gene gating in Saccharomyces cerevisiae, Caenorhabditis elegans, Drosophila melanogaster, and mammalian model systems. These examples highlight new and unpredicted mechanisms for Nup impacts on transcription and questions that are left to be explored.

Nuclear GPS for interchromosomal clustering.

Nuclear architecture and the relative position of a gene can play roles in the regulation of its expression. In this issue of Developmental Cell, Brickner et al. (2012) analyze nuclear global positioning of genes and reveal that the Put3 transcription factor functions with cis-encoded DNA elements and nuclear pore complexes to regulate interchromosomal gene clustering.

Trafficking to uncharted territory of the nuclear envelope.

The nuclear envelope (NE) in eukaryotic cells serves as the physical barrier between the nucleus and cytoplasm. Until recently, mechanisms for establishing the composition of the inner nuclear membrane (INM) remained uncharted. Current findings uncover multiple pathways for trafficking of integral and peripheral INM proteins. A major route for INM protein transport occurs through the nuclear pore complexes (NPCs) with additional requirements for nuclear localization sequences, transport receptors, and Ran-GTP. Studies also reveal a putative NPC-independent vesicular pathway for NE trafficking. INM perturbations lead to changes in nuclear physiology highlighting the potential human disease impacts of continued NE discoveries.