Coordinated posttranscriptional mRNA population dynamics during T-cell activation.

Although RNA-binding proteins (RBPs) coordinate many key decisions during cell growth and differentiation, the dynamics of RNA-RBP interactions have not been extensively studied on a global basis. We immunoprecipitated endogenous ribonucleoprotein complexes containing HuR and PABP throughout a T-cell activation time course and identified the associated mRNA populations using microarrays. We used Gaussian mixture modeling as a discriminative model, treating RBP association as a discrete variable (target or not target), and as a generative model, treating RBP-association as a continuous variable (probability of association). We report that HuR interacts with different populations of mRNAs during T-cell activation. These populations encode functionally related proteins that are members of the Wnt pathway and proteins mediating T-cell receptor signaling pathways. Moreover, the mRNA targets of HuR were found to overlap with the targets of other posttranscriptional regulatory factors, indicating combinatorial interdependence of posttranscriptional regulatory networks and modules after activation. Applying HuR mRNA dynamics as a quantitative phenotype in the drug-gene-phenotype Connectivity Map, we identified candidate small molecule effectors of HuR and T-cell activation. We show that one of these candidates, resveratrol, exerts T-cell activation-dependent posttranscriptional effects that are rescued by HuR. Thus, we describe a strategy to systematically link an RBP and condition-specific posttranscriptional effects to small molecule drugs.

Signal sequence- and translation-independent mRNA localization to the endoplasmic reticulum.

The process of mRNA localization typically utilizes cis-targeting elements and trans-recognition factors to direct the compartmental organization of translationally suppressed mRNAs. mRNA localization to the endoplasmic reticulum (ER), in contrast, occurs via a co-translational, signal sequence/signal recognition particle (SRP)-dependent mechanism. We have utilized cell fractionation/cDNA microarray analysis, shRNA-mediated suppression of SRP expression, and mRNA reporter construct studies to define the role of the SRP pathway in ER-directed mRNA localization. Cell fractionation studies of mRNA partitioning between the cytosol and ER demonstrated the expected enrichment of cytosolic/nucleoplasmic protein-encoding mRNAs and secretory/integral membrane protein-encoding mRNAs in the cytosol and ER fractions, respectively, and identified a subpopulation of cytosolic/nucleoplasmic protein-encoding mRNAs in the membrane-bound mRNA pool. The latter finding suggests a signal sequence-independent pathway of ER-directed mRNA localization. Extending from these findings, mRNA partitioning was examined in stable SRP54 shRNA knockdown HeLa cell lines. shRNA-directed reductions in SRP did not globally alter mRNA partitioning patterns, although defects in membrane protein processing were observed, further suggesting the existence of multiple pathways for mRNA localization to the ER. ER localization of GRP94-encoding mRNA was observed when translation was disabled by mutation of the start codon/insertion of a 5'UTR stem-loop structure or upon deletion of the encoded signal sequence. Combined, these data indicate that the mRNA localization to the ER can be conferred independent of the signal sequence/SRP pathway and suggest that mRNA localization to the ER may utilize cis-encoded targeting information.

Stable ribosome binding to the endoplasmic reticulum enables compartment-specific regulation of mRNA translation.

In eukaryotic cells, protein synthesis is compartmentalized; mRNAs encoding secretory/membrane proteins are translated on endoplasmic reticulum (ER)-bound ribosomes, whereas mRNAs encoding cytosolic proteins are translated on free ribosomes. mRNA partitioning between the two compartments occurs via positive selection: free ribosomes engaged in the translation of signal sequence-encoding mRNAs are trafficked from the cytosol to the ER. After translation termination, ER-bound ribosomes are thought to dissociate, thereby completing a cycle of mRNA partitioning. At present, the physiological basis for termination-coupled ribosome release is unknown. To gain insight into this process, we examined ribosome and mRNA partitioning during the unfolded protein response, key elements of which include suppression of the initiation stage of protein synthesis and polyribosome breakdown. We report that unfolded protein response (UPR)-elicited polyribosome breakdown resulted in the continued association, rather than release, of ER-bound ribosomes. Under these conditions, mRNA translation in the cytosol was suppressed, whereas mRNA translation on the ER was sustained. Furthermore, mRNAs encoding key soluble stress proteins (XBP-1 and ATF-4) were translated primarily on ER-bound ribosomes. These studies demonstrate that ribosome release from the ER is termination independent and identify new and unexpected roles for the ER compartment in the translational response to induction of the unfolded protein response.

Post-transcriptional operons and regulons co-ordinating gene expression.

Experiments reported over the past several years, including genome-wide microarray approaches, have demonstrated that many eukaryotic RNA-binding proteins (RBPs) associate with multiple messenger RNAs (mRNAs) both in vitro and in vivo. This multi-targeted binding property of RBPs has led to a model of regulated gene expression in eukaryotes that we termed the post-transcriptional operon. This concept was established by an analogy between polycistronic mRNAs that are generated from bacterial operons, and the co-ordinated regulation of multiple monocistronic mRNAs by RBPs. Post-transcriptional operons represent a powerful mechanism to organize and express genetic information as functionally related combinations of monocistronic mRNAs. In fact, much of the diversification of individual proteomes may be determined by the combinatorial properties of post-transcriptional operons. This review examines data supporting the role of post-transcriptional operons and regulons in organizing genetic information and co-ordinating expression of functionally related transcripts from their origins at transcription to their subsequent splicing, export and translation.

Partitioning and translation of mRNAs encoding soluble proteins on membrane-bound ribosomes.

In eukaryotic cells, it is generally accepted that protein synthesis is compartmentalized; soluble proteins are synthesized on free ribosomes, whereas secretory and membrane proteins are synthesized on endoplasmic reticulum (ER)-bound ribosomes. The partitioning of mRNAs that accompanies such compartmentalization arises early in protein synthesis, when ribosomes engaged in the translation of mRNAs encoding signal-sequence-bearing proteins are targeted to the ER. In this report, we use multiple cell fractionation protocols, in combination with cDNA microarray, nuclease protection, and Northern blot analyses, to assess the distribution of mRNAs between free and ER-bound ribosomes. We find a broad representation of mRNAs encoding soluble proteins in the ER fraction, with a subset of such mRNAs displaying substantial ER partitioning. In addition, we present evidence that membrane-bound ribosomes engage in the translation of mRNAs encoding soluble proteins. Single-cell in situ hybridization analysis of the subcellular distribution of mRNAs encoding ER-localized and soluble proteins identify two overall patterns of mRNA distribution in the cell-endoplasmic reticular and cytosolic. However, both partitioning patterns include a distinct perinuclear component. These results identify previously unappreciated roles for membrane-bound ribosomes in the subcellular compartmentalization of protein synthesis and indicate possible functions for the perinuclear membrane domain in mRNA sorting in the cell.

Ribonomics: identifying mRNA subsets in mRNP complexes using antibodies to RNA-binding proteins and genomic arrays.

Although in vitro methods have been used to identify putative targets of mRNA-binding proteins, direct in vivo methods are needed to identify endogenously associated mRNAs and their cognate proteins. Therefore, we have developed high-throughput methods to identify structurally and/or functionally related mRNA transcripts through their endogenous association with RNA-binding proteins. We have termed the identification and analysis of mRNA subsets using RNA-associated proteins ribonomics, and have established four primary steps for the method: (1) isolation of endogenous mRNA-protein complexes (mRNPs) under optimized conditions, (2) the en masse characterization of the protein and mRNA components associated with the targeted mRNP complexes, (3) identification of sequences or structural similarities among members of the mRNA subset, and (4) determination of functional relationships among the protein products coded for by members of the mRNA subset. We have hypothesized that mRNAs are organized into structurally and functionally linked groups to better affect information transfer through coordinate gene expression. The functional consequences of such organization would be to facilitate the production of proteins that regulate processes necessary for growth and differentiation. This article describes a series of biochemical techniques that deal with the first two steps of ribonomic profiling: purifying endogenous mRNP complexes and identifying multiple mRNA targets using microarray analysis.