Browsing by Author "Mukherjee, Neelanjan"
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Item Open Access Integrative Regulatory Mapping Indicates that the RNA-Binding Protein HuR Couples Pre-mRNA Processing and mRNA Stability(MOLECULAR CELL, 2011-08-05) Mukherjee, Neelanjan; Corcoran, David L; Nusbaum, Jeffrey D; Reid, David W; Georgiev, Stoyan; Hafner, Markus; Ascano, Manuel; Tuschl, Thomas; Ohler, Uwe; Keene, Jack DItem Open Access Principles of HuR-RNA targeting, interaction dynamics, and functional outcomes(2010) Mukherjee, NeelanjanIn recent years, the pervasiveness and importance of post-transcriptional regulation has reshaped the underlying principles of the organizational logic of gene expression. RNA-binding proteins (RBPs) and non-coding RNAs are the regulatory molecules primary responsible for interaction with target mRNAs and thereby regulating post-transcriptional processes eventually influencing characteristics of the encoded protein. Many of the mRNA targets of RBPs encode functionally related proteins, which for post-trascriptional operons, resulting in coordination of macromolecular complexes or specific cellular processes. Thus, identifying RNA targets, precise binding sites, and the dynamics of these interactions will reveal how these important regulatory factors contribute to gene regulatory networks.
ELAV family of human RBPs consist of 4 members, which all have 3 RRM (RNA-recognition motif) domains the last separated by a hinge region. It predominant role is to positively regulate the stability and translation of target mRNAs through binding to ARE (AU-rich elements) in the 3' UTR (untranslated region) of protein coding transcripts. In response to certain stimuli, HuR is subject to post-translational modifications and changes subcellular localization, which impacts its regulatory capacity. In this study on a transcriptome-wide level, we interrogate the RNA targets, precise binding sites, as well as the remodeling of these interactions in response to stimuli.
We utilized two complementary methods, RIP-chip and PAR-CLIP, to identify targets of HuR and high-resolution binding sites on a transcriptome-wide scale. We discovered that HuR-mRNA interactions are not restricted to the 3' UTR and there are thousands of intronic binding sites. A significant proportion of intronic binding sites are contained in the poly-pyrimidine tract near 3' splice sites. Binding sites in the 3' UTR and intron are often approximately 30 nucleotides apart. HuR can bind to both AU-rich and U-rich sequences, the former more prevalent in 3' UTRs and the latter more prevalent at the 3' splice site.
Next we integrated the binding data with transcriptomics of HuR siRNA mediated knockdown. We found that the degree of binding is proportional to the degree of HuR-dependent stabilization. Moreover the ability to stabilize mRNA is not restricted to 3' UTR binding sites, as intronic binding sites also exhibited the binding degree correlated stabilization. We observed that the spatial pattern of HuR binding sites relative to exons influences exon usage decisions. Specifically, binding sites upstream of the exon promote exclusion, while binding sites downstream of the exon promote inclusion.
Item Restricted Tissue type-specific expression of the dsRNA-binding protein 76 and genome-wide elucidation of its target mRNAs.(PLoS One, 2010-07-23) Neplioueva, Valentina; Dobrikova, Elena Y; Mukherjee, Neelanjan; Keene, Jack D; Gromeier, MatthiasBACKGROUND: RNA-binding proteins accompany all steps in the life of mRNAs and provide dynamic gene regulatory functions for rapid adjustment to changing extra- or intracellular conditions. The association of RNA-binding proteins with their targets is regulated through changing subcellular distribution, post-translational modification or association with other proteins. METHODOLOGY: We demonstrate that the dsRNA binding protein 76 (DRBP76), synonymous with nuclear factor 90, displays inherently distinct tissue type-specific subcellular distribution in the normal human central nervous system and in malignant brain tumors of glial origin. Altered subcellular localization and isoform distribution in malignant glioma indicate that tumor-specific changes in DRBP76-related gene products and their regulatory functions may contribute to the formation and/or maintenance of these tumors. To identify endogenous mRNA targets of DRBP76, we performed RNA-immunoprecipitation and genome-wide microarray analyses in HEK293 cells, and identified specific classes of transcripts encoding critical functions in cellular metabolism. SIGNIFICANCE: Our data suggest that physiologic DRBP76 expression, isoform distribution and subcellular localization are profoundly altered upon malignant transformation. Thus, the functional role of DRBP76 in co- or post-transcriptional gene regulation may contribute to the neoplastic phenotype.