Your search keyword '"Marie Pak"' showing total 5 results

1. Concurrent chaperone and protease activities of ClpAP and the requirement for the N-terminal ClpA ATP binding site for chaperone activity

Author

Marie Pak, Satyendra K. Singh, Michael R. Maurizi, Sue Wickner, and Joel R. Hoskins

Subjects

Models, Molecular, medicine.medical_treatment, ATPase, Mutant, Chromosomal translocation, Biochemistry, chemistry.chemical_compound, Adenosine Triphosphate, Endopeptidases, medicine, Binding site, Molecular Biology, Adenosine Triphosphatases, Protease, Binding Sites, biology, Serine Endopeptidases, DNA Helicases, Proteins, Cell Biology, Endopeptidase Clp, Adenosine, DNA-Binding Proteins, chemistry, Models, Chemical, Chaperone (protein), biology.protein, Mutagenesis, Site-Directed, Trans-Activators, DNA, medicine.drug, Molecular Chaperones

Abstract

ClpA, a member of the Clp/Hsp100 family of ATPases, is both an ATP-dependent molecular chaperone and the regulatory component of ClpAP protease. We demonstrate that chaperone and protease activities occur concurrently in ClpAP complexes during a single round of RepA binding to ClpAP and ATP-dependent release. This result was substantiated with a ClpA mutant, ClpA(K220V), carrying an amino acid substitution in the N-terminal ATP binding site. ClpA(K220V) is unable to activate RepA, but the presence of ClpP or chemically inactivated ClpP restores its ability to activate RepA. The presence of ClpP simultaneously facilitates degradation of RepA. ClpP must remain bound to ClpA(K220V) for these effects, indicating that both chaperone and proteolytic activities of the mutant complex occur concurrently. ClpA(K220V) itself is able to form stable complexes with RepA in the presence of a poorly hydrolyzed ATP analog, adenosine 5′-O-(thiotriphosphate), and to release RepA upon exchange of adenosine 5′-O-(thiotriphosphate) with ATP. However, the released RepA is inactive in DNA binding, indicating that the N-terminal ATP binding site is essential for the chaperone activity of ClpA. Taken together, these results suggest that substrates bound to the complex of the proteolytic and ATPase components can be partitioned between release/reactivation and translocation/degradation.

Published

1999

2. The essential Gcd10p–Gcd14p nuclear complex is required for 1-methyladenosine modification and maturation of initiator methionyl-tRNA

Author

Marie Pak, Bradley A. Carlson, James M. Anderson, Alan G. Hinnebusch, Katsura Asano, Mercedes Tamame, Lon Phan, Rafael Cuesta, and Glenn R. Björk

Subjects

Messenger RNA, Mutation, Adenosine, RNA, Transfer, Met, biology, Saccharomyces cerevisiae, Mutant, Genes, Fungal, Nuclear Proteins, biology.organism_classification, medicine.disease_cause, Suppression, Genetic, Biochemistry, Transfer RNA, Genetics, medicine, Protein biosynthesis, Nuclear protein, RNA Processing, Post-Transcriptional, Peptide Chain Initiation, Translational, Nuclear localization sequence, Developmental Biology, Research Paper

Abstract

Gcd10p and Gcd14p are essential proteins required for the initiation of protein synthesis and translational repression ofGCN4mRNA. The phenotypes ofgcd10mutants were suppressed by high-copy-numberIMTgenes, encoding initiator methionyl tRNA (tRNAiMet), orLHP1, encoding the yeast homolog of the human La autoantigen. Thegcd10-504mutation led to a reduction in steady-state levels of mature tRNAiMet, attributable to increased turnover rather than decreased synthesis of pre-tRNAiMet. Remarkably, the lethality of aGCD10deletion was suppressed by high-copy-numberIMT4, indicating that its role in expression of mature tRNAiMetis the essential function of Gcd10p. Agcd14-2mutant also showed reduced amounts of mature tRNAiMet, but in addition, displayed a defect in pre-tRNAiMetprocessing. Gcd10p and Gcd14p were found to be subunits of a protein complex with prominent nuclear localization, suggesting a direct role in tRNAiMetmaturation. The chromatographic behavior of elongator and initiator tRNAMeton a RPC-5 column indicated that both species are altered structurally ingcd10Δcells, and analysis of base modifications revealed that 1-methyladenosine (m1A) is undetectable ingcd10ΔtRNA. Interestingly,gcd10andgcd14mutations had no effect on processing or accumulation of elongator tRNAMet, which also contains m1A at position 58, suggesting a unique requirement for this base modification in initiator maturation.

Published

1998

3. The role of the ClpA chaperone in proteolysis by ClpAP

Author

Joel R. Hoskins, Michael R. Maurizi, Sue Wickner, and Marie Pak

Subjects

Endopeptidase Clp, Proteolysis, ATPase, Protein degradation, Substrate Specificity, ATP hydrolysis, medicine, ATP-Dependent Proteases, Binding site, Adenosine Triphosphatases, Multidisciplinary, biology, medicine.diagnostic_test, Hydrolysis, Serine Endopeptidases, DNA Helicases, Proteins, Biological Sciences, DNA-Binding Proteins, Biochemistry, Chaperone (protein), biology.protein, Biophysics, Trans-Activators, Molecular Chaperones

Abstract

ClpA, a member of the Clp/Hsp100 family of ATPases, is a molecular chaperone and, in combination with a proteolytic component ClpP, participates in ATP-dependent proteolysis. We investigated the role of ClpA in protein degradation by ClpAP by dissociating the reaction into several discrete steps. In the assembly step, ClpA–ClpP–substrate complexes assemble either by ClpA–substrate complexes interacting with ClpP or by ClpA–ClpP complexes interacting with substrate; ClpP in the absence of ClpA is unable to bind substrates. Assembly requires ATP binding but not hydrolysis. We discovered that ClpA translocates substrates from their binding sites on ClpA to ClpP. The translocation step specifically requires ATP; nonhydrolyzable ATP analogs are ineffective. Only proteins that are degraded by ClpAP are translocated. Characterization of the degradation step showed that substrates can be degraded in a single round of ClpA–ClpP–substrate binding followed by ATP hydrolysis. The products generated are indistinguishable from steady-state products. Taken together, our results suggest that ClpA, through its interaction with both the substrate and ClpP, acts as a gatekeeper, actively translocating specific substrates into the proteolytic chamber of ClpP where degradation occurs. As multicomponent ATP-dependent proteases are widespread in nature and share structural similarities, these findings may provide a general mechanism for regulation of substrate import into the proteolytic chamber.

Published

1998

4. Mechanism of protein remodeling by ClpA chaperone

Author

Marie Pak and Sue Wickner

Subjects

Endopeptidase Clp, Dimer, Plasma protein binding, Random hexamer, chemistry.chemical_compound, Viral Proteins, Adenosine Triphosphate, ATP hydrolysis, Nucleotide, Bacteriophage P1, chemistry.chemical_classification, Adenosine Triphosphatases, Multidisciplinary, biology, Serine Endopeptidases, DNA Helicases, Proteins, Biological Sciences, Recombinant Proteins, DNA-Binding Proteins, Models, Structural, Kinetics, Biochemistry, chemistry, Chaperone (protein), Protein Biosynthesis, biology.protein, Biophysics, Trans-Activators, Adenosine triphosphate, Dimerization, Protein Binding

Abstract

ClpA, a newly discovered ATP-dependent molecular chaperone, remodels bacteriophage P1 RepA dimers into monomers, thereby activating the latent specific DNA binding activity of RepA. We investigated the mechanism of the chaperone activity of ClpA by dissociating the reaction into several steps and determining the role of nucleotide in each step. In the presence of ATP or a nonhydrolyzable ATP analog, the initial step is the self-assembly of ClpA and its association with inactive RepA dimers. ClpA-RepA complexes form rapidly and at 0°C but are relatively unstable. The next step is the conversion of unstable ClpA-RepA complexes into stable complexes in a time- and temperature-dependent reaction. The transition to stable ClpA-RepA complexes requires binding of ATP, but not ATP hydrolysis, because nonhydrolyzable ATP analogs satisfy the nucleotide requirement. The stable complexes contain approximately 1 mol of RepA dimer per mol of ClpA hexamer and are committed to activating RepA. In the last step of the reaction, active RepA is released upon exchange of ATP with the nonhydrolyzable ATP analog and ATP hydrolysis. Importantly, we discovered that one cycle of RepA binding to ClpA followed by ATP-dependent release is sufficient to convert inactive RepA to its active form.

Published

1997

5. A Site in the Dinucleotide-fold Domain Contributes to the Accuracy of tRNA Selection by Escherichia coli Methionyl-tRNA Synthetase.

Author

Hae-Yeong Kim, Marie Pak, and Hieronim Jakubowski

Abstract

Interactions of specific amino acid residues of the carboxyl-terminal domain of MetRS with the CAU anticodon of tRNA Met assure accurate and efficient aminoacylation. The substitution of one such residue, Trp461 by Phe, impairs the binding of cognate tRNA, but enhances the binding of noncognate tRNAs, particularly those containing G at the wobble position. However, the enhanced binding of noncognate tRNAs is not accompanied by the increased aminoacylation of these tRNAs. A genetic screening procedure was designed to isolate methionyl-tRNA synthetase mutants which were able to aminoacylate a GGU (threonine) anticodon derivative of tRNA lMet. One such mutant, obtained from W461F MetRS, had an Ile29 to Thr substitution in helix A located in the amino-terminal dinucleotide-fold domain that forms the site for amino acid activation. Analysis of the catalytic properties of the I29TIW461F enzyme indicates that the mutation in helix A of the dinucleotidefold domain affects kcat for aminoacylation of tRNAs having a GGU threonine anticodon. Interactions with cognate tRNAfMet(CAU), as well as with methionine and ATP were not affected by the Ile29 to Thr substitution. We conclude that the I29T substitution leads to a slight adjustment of the alignment of the CCA stem of noncognate tRNAs (GGU) in the catalytic domain of the enzyme, reflected in the increase in kcat' which also allows mischarging in vivo. A function of Ile29 is therefore to minimize the mischarging of tRNAThr (GGU) by methionyl-tRNA synthetase. The methods described here provide useful tools for examining the mechanisms of tRNA selection by aminoacyl-tRNA synthetases. [ABSTRACT FROM AUTHOR]

Published

1998