pK a Coupling at the Intein Active Site: Implications for the Coordination Mechanism of Protein Splicing with a Conserved Aspartate

pK a Coupling at the Intein Active Site: Implications for the Coordination Mechanism of Protein Splicing with a Conserved Aspartate

Protein splicing is a robust multistep posttranslational process catalyzed by inteins. In the Mtu RecA intein, a conserved block-F aspartate (D422) coordinates different steps in protein splicing, but the precise mechanism is unclear. Solution NMR shows that D422 has a strikingly high pK a of 6.1, t...

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Bibliographic Details
Published in:Journal of the American Chemical Society Vol. 133; no. 26; pp. 10275 - 10282
Main Authors: Du, Zhenming, Zheng, Yuchuan, Patterson, Melissa, Liu, Yangzhong, Wang, Chunyu
Format: Journal Article
Language:English
Published: United States American Chemical Society 06-07-2011
Subjects:
Aspartic Acid
Catalytic Domain
Conserved Sequence
Hydrogen Bonding
Inteins
Models, Molecular
Mutation
Mycobacterium tuberculosis - enzymology
Protein Splicing
Protons
Rec A Recombinases - chemistry
Rec A Recombinases - genetics
Rec A Recombinases - metabolism
Solutions
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Summary:Protein splicing is a robust multistep posttranslational process catalyzed by inteins. In the Mtu RecA intein, a conserved block-F aspartate (D422) coordinates different steps in protein splicing, but the precise mechanism is unclear. Solution NMR shows that D422 has a strikingly high pK a of 6.1, two units above the normal pK a of aspartate. The elevated pK a of D422 is coupled to the depressed pK a of another active-site residue, the block-A cysteine (C1). A C1A mutation lowers the D422 pK a to normal, while a D422G mutation increases the C1 pK a from 7.5 to 8.5. The pK a coupling and NMR structure determination demonstrate that protonated D422 serves as a hydrogen bond donor to stabilize the C1 thiolate and promote the N–S acyl shift, the first step of protein splicing. Additionally, in vivo splicing assays with mutations of D422 to Glu, Cys, and Ser show that the deprotonated aspartate is essential for splicing, most likely by deprotonating and activating the downstream nucleophile in transesterification, the second step of protein splicing. We propose that the sequential protonation and deprotonation of the D422 side chain is the coordination mechanism for the first two steps of protein splicing.
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ISSN:0002-7863
1520-5126
DOI:10.1021/ja203209f