Cysteine Alkylation Blocks siRNA Binding to a p19 Viral Suppressor of RNA Silencing

NRC publication: Ye

Studies of a viral suppressor of RNA silencing p19-CFP fusion protein: A FRET-based probe for sensing double stranded fluorophore tagged small RNAs

Eukaryotes have evolved complex cellular responses to double-stranded RNA. One response that is highly conserved across many species is the RNA silencing pathway. Tombusviruses have evolved a mechanism to evade the RNA silencing pathway that involves a small protein, p19, that acts as a suppressor of RNA silencing. This protein binds specifically to small-interfering RNAs (siRNAs) with nanomolar affinity in a sequence-independent manner and with size selectivity.Peer reviewed: YesNRC publication: N

Cysteine residues of Carnation Italian ringspot virus p19 suppressor of RNA silencing help maintain global structural integrity and stability for siRNA binding

Carnation Italian Ringspot virus (CIRV) has evolved a protein called p19 that acts as a suppressor of RNA silencing in the host cell and aids in viral persistence. This protein has been shown to be sensitive to cysteine alkylation resulting in a reduction in its ability to bind to short-interfering RNA (siRNA). To determine the sites within the protein that are sensitive to alkylation, we systematically tested the functional role of each cysteine residue using site-directed mutagenesis. Variants of the p19 protein were created at locations C110, C134 and C160 where the cysteines were replaced by an inert amino acid such as serine or isoleucine. The results from activity measurements of the purified mutant p19 proteins indicate that the mutants maintain the ability to bind siRNAs with nanomolar affinity, however, their stabilities, as measured by circular dichroism (CD), vary. Functional studies in the presence of the cysteine alkylating agent N-ethylmaleimide (NEM) indicated that p19's ability to bind siRNAs and act as a suppressor of RNA silencing is sensitive to alkylation at all three cysteine residues with the maximum effects occurring when C110 and C134 are both alkylated. These results suggest that the role of the cysteine amino acid conservation is likely to preserve the overall structural integrity of p19 for optimal thermostability and subsequent siRNA-binding activity. We find that p19 function is maximally compromised at high levels of thiol alkylation or in an oxidizing environment.Peer reviewed: YesNRC publication: N

Stabilized recombinant suppressors of RNA silencing: functional effects of linking monomers of Carnation Italian Ringspot virus p19

Eukaryotes have evolved complex cellular responses to double-stranded RNA including the RNA silencing pathway. Tombusviruses have adapted a mechanism to evade RNA silencing that involves a 19 kDa dimeric protein (p19) that is a suppressor of RNA silencing. In order to develop stabilized p19 proteins, linked versions of p19 from the Carnation Italian Ringspot virus (CIRV) were constructed that joined the C-terminus of one subunit to the N-terminus of the second subunit. Like the native CIRV p19, these linked p19 proteins were able to bind to double-stranded siRNAs with nanomolar affinity and discriminate siRNA according to length. In addition, the interdomain linker improved both the stability and binding properties of the p19 dimer. The observed binding properties support the idea that the semi-rigid cross-link favors the folded, binding-competent state of p19. The cross-linked recombinant CIRV-p19s represent novel stabilized suppressors of RNA silencing and may be useful in future biophysical, immunological and cell biology studies.NRC publication: Ye

Porcine pancreatic α-amylase inhibition by the kidney bean (Phaseolus vulgaris) inhibitor (α-AI1) and structural changes in the α-amylase inhibitor complex

International audiencePorcine pancreatic a-amylase (PPA) is inhibited by the red kidney bean (Phaseolus vulgaris) inhibitor a-AI1 [Eur. J. Biochem. 265 (1999) 20]. Inhibition kinetics were carried out using DP 4900-amylose and maltopentaose as substrate. As shown by graphical and statistical analysis of the kinetic data, the inhibitory mode is of the mixed noncompetitive type whatever the substrate thus involving the EI, EI2, ESI and ESI2 complexes. This contrast with the E2I complex obtained in the crystal and with biophysical studies. Such difference very likely depends on the [I]/[E] ratio. At low ratio, the E2I complex is favoured; at high ratio the EI, ESI and EI2 complexes are formed. The inhibition model also differs from those previously proposed for acarbose [Eur. J. Biochem. 241 (1996) 787 and Eur. J. Biochem. 252 (1998) 100]. In particular, with a-AI1, the inhibition takes place only when PPA and a-AI are preincubated together before adding the substrate. This indicates that the abortive PPA-aAI1 complex is formed during the preincubation period. One additional carbohydrate binding site is also demonstrated yielding the ESI complex. Also, a second protein binding site is found in EI2 and ESI2 abortive complexes. Conformational changes undergone by PPA upon a-AI1 binding are shown by higher sensitivity to subtilisin attack. From X-ray analysis of the a-AI1-PPA complex (E2I), the major interaction occurs with two hairpin loops L1 (residues 29-46) and L2 (residues 171-189) of a-AI1 protruding into the V-shaped active site of PPA. The hydrolysis of a-AI1 that accounts for the inhibitory activity is reported.

Molecular events linking cholesterol to Alzheimer\u2019s disease and inclusion body myositis in a rabbit model

Alzheimer\u2019s disease (AD) is the most common neurodegenerative disorder, characterized by cognitive impairment and dementia, resulting from progressive synaptic dysfunction, loss and neuronal cell death. Inclusion body myositis (IBM) is a skeletal muscle degenerative disease, displaying progressive proximal and distal muscle weakness, in association with muscle fiber atrophy, degeneration and death. Studies have shown that the late onset version of AD (LOAD) and sporadic IBM (sIBM) in muscle share many pathological features, including the presence of extracellular plaques of \u3b2-amyloid peptides and intracellular tangles of hyperphosphorylated tau proteins. High blood cholesterol is suggested to be a risk factor for LOAD. Many neuropathological changes of LOAD can be reproduced by feeding rabbits a 2% enriched cholesterol diet for 12 weeks. The cholesterol fed rabbit model also simultaneously develops sIBM like pathology, which makes it an ideal model to study the molecular mechanisms common to the development of both diseases. In the present study, we determined the changes of gene expression in rabbit brain and muscle during the progression of LOAD and sIBM pathology using a custom rabbit nucleotide microarray, followed by qRT-PCR analyses. Out of 869 unique transcripts screened, 47 genes showed differential expression between the control and the cholesterol-treated group during the 12 week period and 19 changed transcripts appeared to be common to LOAD and sIBM. The most notable changes are the upregulation of the hemoglobin gene family and the downregulation of the genes required for mitochondrial oxidative phosphorylation in both brain and muscle tissues throughout the time course. The significant overlap on the changes of gene expression in the brain and muscle of rabbits fed with cholesterol-enriched diet supports the notion that LOAD and sIBM may share a common etiology.Peer reviewed: YesNRC publication: Ye

FLEth RNA Intercalating Probe is a Convenient Reporter for Small Interfering RNAs

Here we report that the phenanthridine derivative covalently linked to a fluorescein moiety (FLEth) can act as a fluorescence based probe for duplex short interfering RNA (siRNA) and that this probe can also be used to report on protein 12RNA interactions. A fluorescence resonance energy transfer (FRET) signal that is observed at 600 nm occurs when FLEth is complexed with siRNA. At least 2 molecules of FLEth can bind to 21 nt duplex siRNA, and the dissociation constants for these interactions are reported. We find that FLEth can also report on the interaction of siRNAs with the Carnation Italian ringspot viral suppressor of RNA silencing p19. FLEth does not bind to the siRNA 12p19 complex nor can p19 bind to the siRNA 12FLEth complex; rather FLEth can report on the fraction of siRNA that is unbound. FLEth can also bind siRNA in delivery systems such as liposomes. Once the siRNA reaches the interior of Huh 7.5 cells, FLEth dissociates from the siRNA and is found in the nucleoli suggesting that FLEth cannot bind to siRNAs that are associated with the RNA silencing machinery.Peer reviewed: YesNRC publication: N