Browsing by Subject "RNA binding"
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Item Biophysical studies of an expanded RNA recognition motif from the Bruno protein(2009-08) Lyon, Angeline Marie; Hoffman, David W., Ph. D.; Robertus, Jon D.; Browning, Karen S.; Macdonald, Paul M.; Stevens, Scott W.RNA recognition motifs (RRMs) are a ubiquitous class of proteins which bind RNA in a sequence-specific fashion, often with high affinity. The mechanisms through which this single protein domain recognizes diverse RNA sequences is not fully understood. High-resolution three-dimensional structures are particularly important in understanding the structural features required for RNA recognition and binding. This work presents the structure of an expanded RRM domain from the Drosophila melanogaster Bruno protein. The Bruno protein is involved in establishing proper body patterning during development. This is accomplished through the translational repression of several mRNAs, in particular, the oskar mRNA. Previous work has identified an expanded RRM domain within the Bruno protein. This RRM requires an additional forty amino acids prior to the start of the canonical RRM domain for high affinity RNA binding. The protein was found to contain a canonical RRM domain comprised of four anti-parallel [beta] strands and two [alpha] helices. The RRM is preceded by a ten amino acid loop that interacts with [alpha]₁ and [beta]₂, while the remaining amino acids are flexible in solution. Interestingly, the deletion of these residues does not alter the fold or stability of the RRM domain. Thus, these additional residues must be involved in RNA binding, as they are not required for structure. From these studies, the Bruno RRM represents a new example of protein features required for recognition and high affinity binding of RNA.Item Mechanism of MDA5 Recognition of Short RNA Ligands and Crystal Structure of PepQ(2013-05-16) Watts, Tylan AubreyThe innate immune pathways that stimulate the expression of cytokines and proapoptotic factors in response to infection are triggered by the activation of the cytosolic receptors retinoic acid-inducible gene I (RIG-I) and melanoma differentiationassociated gene 5 (MDA5). Activation of both receptors occurs as a result of binding to RNA. MDA5 only recognizes double stranded forms of RNA, whereas RIG-I is capable of recognizing both single and double stranded RNA. In vivo, MDA5 is known to be stimulated by long (>1 kb) strands of RNA, forming filaments along the phosphate backbone. However, the manner in which MDA5 can recognize the terminal end of its RNA ligand is uncertain. I have examined the mechanism of binding of the MDA5 protein by comparing MDA5 binding to short (<18 bp) blunt RNA, 5? triphosphate RNA, and RNA with a 3? or 5? overhang. It is shown that while the MDA5 protein regulatory domain (RD) is essential for RNA recognition, the MDA5 RD only weakly recognizes short double stranded RNA ligands with overhangs or a 5? triphosphate group. The Cys951 residue was shown to disrupt stability of the MDA5 RD-RNA complex. Binding analyses were performed using a combination of SDS-PAGE, gel filtration analysis, and nondenaturing gel electrophoresis. In addition, structural data was gathered by crystallization of the MDA5 RD-RNA complex using X-ray crystallography. These results help to establish the manner in which MDA5 is regulated predominantly to the binding of long RNA ligands. Also included in this document is structural data on the dimer form of the PepQ protein from E. coli. PepQ is a highly conserved proline peptidase that has a secondary activity of hydrolyzing organophosphorus triesters, toxic compounds found in many pesticides. The PepQ protein was crystallized and analyzed by X-ray diffraction. The dimer interface was clearly defined within the structure and provides insight into how the active dimer forms from the PepQ monomer.