Sylvie Sinapah scite author profile

Sylvie Sinapah

3Publications

101Citation Statements Received

131Citation Statements Given

How they've been cited

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126

Affiliations

Yale University, Uppsala University, The Ohio State University

Publications

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Cleavage of model substrates by archaeal RNase P: role of protein cofactors in cleavage-site selection

Sinapah

Chen

et al. 2010

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RNase P is a catalytic ribonucleoprotein primarily involved in tRNA biogenesis. Archaeal RNase P comprises a catalytic RNase P RNA (RPR) and at least four protein cofactors (RPPs), which function as two binary complexes (POP5•RPP30 and RPP21• RPP29). Exploiting the ability to assemble a functional Pyrococcus furiosus (Pfu) RNase P in vitro, we examined the role of RPPs in influencing substrate recognition by the RPR. We first demonstrate that Pfu RPR, like its bacterial and eukaryal counterparts, cleaves model hairpin loop substrates albeit at rates 90- to 200-fold lower when compared with cleavage by bacterial RPR, highlighting the functionally comparable catalytic cores in bacterial and archaeal RPRs. By investigating cleavage-site selection exhibited by Pfu RPR (±RPPs) with various model substrates missing consensus-recognition elements, we determined substrate features whose recognition is facilitated by either POP5•RPP30 or RPP21•RPP29 (directly or indirectly via the RPR). Our results also revealed that Pfu RPR + RPP21•RPP29 displays substrate-recognition properties coinciding with those of the bacterial RPR-alone reaction rather than the Pfu RPR, and that this behaviour is attributable to structural differences in the substrate-specificity domains of bacterial and archaeal RPRs. Moreover, our data reveal a hierarchy in recognition elements that dictates cleavage-site selection by archaeal RNase P.

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The human large subunit ribosomal protein L36A-like contacts the CCA end of P-site bound tRNA

Baouz¹,

Woisard²,

Sinapah³

et al. 2009

Biochimie

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Mutational analysis of Sep‐tRNA:Cys‐tRNA synthase reveals critical residues for tRNA‐dependent cysteine formation

et al. 2011

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In methanogenic archaea, Sep-tRNA:Cys-tRNA synthase (SepCysS) converts Sep-tRNACys to Cys-tRNACys. The mechanism of tRNA-dependent cysteine formation remains unclear due to the lack of functional studies. In this work, we mutated 19 conserved residues in Methanocaldococcus jannaschii SepCysS, and employed an in vivo system to determine the activity of the resulting variants. Our results show that three active-site cysteines (Cys39, Cys42 and Cys247) are essential for SepCysS activity. In addition, combined with structural modeling, our mutational and functional analyses also reveal multiple residues that are important for the binding of PLP, Sep and tRNA. Our work thus represents the first systematic functional analysis of conserved residues in archaeal SepCysSs, providing insights into the catalytic and substrate binding mechanisms of this poorly characterized enzyme.

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Sylvie Sinapah

Cleavage of model substrates by archaeal RNase P: role of protein cofactors in cleavage-site selection

The human large subunit ribosomal protein L36A-like contacts the CCA end of P-site bound tRNA

Mutational analysis of Sep‐tRNA:Cys‐tRNA synthase reveals critical residues for tRNA‐dependent cysteine formation

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