Your search keyword '"Debkumar Pain"' showing total 9 results

1. Fe-S cluster biogenesis in isolated mammalian mitochondria: coordinated use of persulfide sulfur and iron and requirements for GTP, NADH, and ATP

Author

Alok, Pandey, Jayashree, Pain, Arnab K, Ghosh, Andrew, Dancis, and Debkumar, Pain

Subjects

Aconitate Hydratase, Neurons, Iron, Gene Expression, Sulfides, NAD, Sulfur Radioisotopes, Recombinant Proteins, Cell Line, Mitochondria, Mitochondrial Proteins, Carbon-Sulfur Lyases, Mice, Adenosine Triphosphate, Metabolism, Escherichia coli, Animals, Ferredoxins, Humans, HSP70 Heat-Shock Proteins, Cysteine, Guanosine Triphosphate, HeLa Cells

Abstract

Iron-sulfur (Fe-S) clusters are essential cofactors, and mitochondria contain several Fe-S proteins, including the [4Fe-4S] protein aconitase and the [2Fe-2S] protein ferredoxin. Fe-S cluster assembly of these proteins occurs within mitochondria. Although considerable data exist for yeast mitochondria, this biosynthetic process has never been directly demonstrated in mammalian mitochondria. Using [(35)S]cysteine as the source of sulfur, here we show that mitochondria isolated from Cath.A-derived cells, a murine neuronal cell line, can synthesize and insert new Fe-(35)S clusters into aconitase and ferredoxins. The process requires GTP, NADH, ATP, and iron, and hydrolysis of both GTP and ATP is necessary. Importantly, we have identified the (35)S-labeled persulfide on the NFS1 cysteine desulfurase as a genuine intermediate en route to Fe-S cluster synthesis. In physiological settings, the persulfide sulfur is released from NFS1 and transferred to a scaffold protein, where it combines with iron to form an Fe-S cluster intermediate. We found that the release of persulfide sulfur from NFS1 requires iron, showing that the use of iron and sulfur for the synthesis of Fe-S cluster intermediates is a highly coordinated process. The release of persulfide sulfur also requires GTP and NADH, probably mediated by a GTPase and a reductase, respectively. ATP, a cofactor for a multifunctional Hsp70 chaperone, is not required at this step. The experimental system described here may help to define the biochemical basis of diseases that are associated with impaired Fe-S cluster biogenesis in mitochondria, such as Friedreich ataxia.

Published

2014

2. GTP is required for iron-sulfur cluster biogenesis in mitochondria

Author

Boominathan Amutha, Andrew Dancis, Elise R. Lyver, Donna M. Gordon, Yajuan Gu, and Debkumar Pain

Subjects

Iron-Sulfur Proteins, Saccharomyces cerevisiae Proteins, GTP', Iron–sulfur cluster, GTPase, Saccharomyces cerevisiae, Mitochondrion, Sulfur Radioisotopes, Biochemistry, Aconitase, Cofactor, chemistry.chemical_compound, Adenosine Triphosphate, Apoenzymes, Molecular Biology, Ferredoxin, Aconitate Hydratase, biology, Hydrolysis, Cell Biology, Cell biology, Mitochondria, Carbon-Sulfur Lyases, chemistry, Isotope Labeling, biology.protein, Ferredoxins, Guanosine Triphosphate, Holoenzymes, Biogenesis

Abstract

Iron-sulfur (Fe-S) cluster biogenesis in mitochondria is an essential process and is conserved from yeast to humans. Several proteins with Fe-S cluster cofactors reside in mitochondria, including aconitase [4Fe-4S] and ferredoxin [2Fe-2S]. We found that mitochondria isolated from wild-type yeast contain a pool of apoaconitase and machinery capable of forming new clusters and inserting them into this endogenous apoprotein pool. These observations allowed us to develop assays to assess the role of nucleotides (GTP and ATP) in cluster biogenesis in mitochondria. We show that Fe-S cluster biogenesis in isolated mitochondria is enhanced by the addition of GTP and ATP. Hydrolysis of both GTP and ATP is necessary, and the addition of ATP cannot circumvent processes that require GTP hydrolysis. Both in vivo and in vitro experiments suggest that GTP must enter into the matrix to exert its effects on cluster biogenesis. Upon import into isolated mitochondria, purified apoferredoxin can also be used as a substrate by the Fe-S cluster machinery in a GTP-dependent manner. GTP is likely required for a common step involved in the cluster biogenesis of aconitase and ferredoxin. To our knowledge this is the first report demonstrating a role of GTP in mitochondrial Fe-S cluster biogenesis.

Published

2007

3. Mrs3p, Mrs4p, and frataxin provide iron for Fe-S cluster synthesis in mitochondria

Author

Emmanuel Lesuisse, Andrew Dancis, Yan Zhang, Debkumar Pain, Simon A.B. Knight, Elise R. Lyver, Department of Medicine Division of Hematology-Oncology, Pennsylvania State University (Penn State), Penn State System-Penn State System, Department of Pharmacology and Physiology, Rutgers Biomedical and Health Sciences, Rutgers University System (Rutgers)-Rutgers University System (Rutgers), Institut Jacques Monod (IJM (UMR_7592)), and Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Iron-Sulfur Proteins, Saccharomyces cerevisiae Proteins, Genotype, Iron, Mutant, Saccharomyces cerevisiae, Mitochondrion, Biochemistry, Aconitase, Membrane Potentials, Mitochondrial Proteins, 03 medical and health sciences, chemistry.chemical_compound, Iron-Binding Proteins, Molecular Biology, Heme, Cation Transport Proteins, Ferredoxin, 030304 developmental biology, 0303 health sciences, biology, 030302 biochemistry & molecular biology, Cell Biology, Mitochondrial carrier, Yeast, [SDV.BBM.BC]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Biomolecules [q-bio.BM], Mitochondria, Kinetics, chemistry, Mitochondrial Membranes, Mutation, Frataxin, biology.protein

Abstract

Yeast Mrs3p and Mrs4p are evolutionarily conserved mitochondrial carrier proteins that transport iron into mitochondria under some conditions. Yeast frataxin (Yfh1p), the homolog of the human protein implicated in Friedreich ataxia, is involved in iron homeostasis. However, its precise functions are controversial. Anaerobically grown triple mutant cells (Deltamrs3/4/Deltayfh1) displayed a severe growth defect corrected by in vivo iron supplementation. Because anaerobically grown cells do not synthesize heme, and they do not experience oxidative stress, this growth defect was most likely due to Fe-S cluster deficiency. Fe-S cluster formation was assessed in anaerobically grown cells shifted to air for a brief period. In isolated mitochondria, Fe-S clusters were detected on newly imported yeast ferredoxin precursor and on endogenous aconitase by means of [35S]cysteine labeling and native gel separation. New cluster formation was dependent on iron addition to mitochondria, and the iron concentration dependence was shifted dramatically upward in the Deltamrs3/4 mutant, indicating a role of Mrs3/4p in iron transport. The frataxin mutant strain lacked protein import capacity because of low mitochondrial membrane potential, although this was partially restored by growth in the presence of high iron. Under these conditions, a kinetic defect in new Fe-S cluster formation was still noted. Import of frataxin into frataxin-minus isolated mitochondria promptly corrected the Fe-S cluster assembly defect without further iron addition. These findings show that Mrs3/4p transports iron into mitochondria, whereas frataxin makes iron already within mitochondria available for Fe-S cluster synthesis.

Published

2006

4. A GTP:AMP phosphotransferase, Adk2p, in Saccharomyces cerevisiae. Role of the C terminus in protein folding/stabilization, thermal tolerance, and enzymatic activity

Author

Yajuan, Gu, Donna M, Gordon, Boominathan, Amutha, and Debkumar, Pain

Subjects

Cytoplasm, Protein Denaturation, Protein Folding, Hot Temperature, Saccharomyces cerevisiae Proteins, Base Sequence, Adenylate Kinase, Molecular Sequence Data, Temperature, Saccharomyces cerevisiae, Polymerase Chain Reaction, Mitochondria, Protein Structure, Tertiary, Open Reading Frames, Urea, Trypsin, Amino Acid Sequence, Gene Deletion, Adenylyl Cyclases

Abstract

Adenylate kinases participate in maintaining the homeostasis of cellular nucleotides. Depending on the yeast strains, the GTP:AMP phosphotransferase is encoded by the nuclear gene ADK2 with or without a single base pair deletion/insertion near the 3' end of the open reading frame, and the corresponding protein exists as either Adk2p (short) or Adk2p (long) in the mitochondrial matrix. These two forms are identical except that the three C-terminal residues of Adk2p (short) are changed in Adk2p (long), and the latter contains an additional nine amino acids at the C terminus of the protein. The short form of Adk2p has so far been considered to be inactive (Schricker, R., Magdolen, V., Strobel, G., Bogengruber, E., Breitenbach, M., and Bandlow, W. (1995) J. Biol. Chem. 270, 31103-31110). Using purified proteins, we show that at the physiological temperature for yeast growth (30 degrees C), both short and long forms of Adk2p are enzymatically active. However, in contrast to the short form, Adk2p (long) is quite resistant to thermal inactivation, urea denaturation, and degradation by trypsin. Unfolding of the long form by high concentrations of urea greatly stimulated its import into isolated mitochondria. Using an integration-based gene-swapping approach, we found that regardless of the yeast strains used, the steady state levels of endogenous Adk2p (long) in mitochondria were 5-10-fold lower compared with those of Adk2p (short). Together, these results suggest that the modified C-terminal domain in Adk2p (long) is not essential for enzyme activity, but it contributes to and strengthens protein folding and/or stability and is particularly important for maintaining enzyme activity under stress conditions.

Published

2005

5. J-domain protein, Jac1p, of yeast mitochondria required for iron homeostasis and activity of Fe-S cluster proteins

Author

Debkumar Pain, Sandeep Saxena, Roy J. Kim, Andrew Dancis, and Donna M. Gordon

Subjects

Hemeproteins, Iron-Sulfur Proteins, Saccharomyces cerevisiae Proteins, Ultraviolet Rays, Iron, Protein domain, Mutant, Mutagenesis (molecular biology technique), Saccharomyces cerevisiae, Mitochondrion, Biology, Biochemistry, Fungal Proteins, Mitochondrial Proteins, Homeostasis, HSP70 Heat-Shock Proteins, Allele, Molecular Biology, chemistry.chemical_classification, Aconitate Hydratase, Cell Biology, Amino acid, Hsp70, Mitochondria, Succinate Dehydrogenase, Phenotype, chemistry, Mutagenesis, Genetic screen, Molecular Chaperones

Abstract

J-proteins are molecular chaperones with a characteristic domain predicted to mediate interaction with Hsp70 proteins. We have previously isolated yeast mutants of the mitochondrial Hsp70, Ssq1p, in a genetic screen for mutants with altered iron homeostasis. Here we describe the isolation of mutants of the J-domain protein, Jac1p, using the same screen. Mutant jac1 alleles predicted to encode severely truncated proteins (lacking 70 or 152 amino acids) were associated with phenotypes strikingly similar to the phenotypes of ssq1 mutants. These phenotypes include activation of the high affinity cellular iron uptake system and iron accumulation in mitochondria. In contrast to iron accumulation, Fe-S proteins of mitochondria were specifically deficient. In jac1 mutants, like in ssq1 mutants, processing of the Yfh1p precursor protein from intermediate to mature forms was delayed. In the genetic backgrounds used in this study, jac1 null mutants were found to be viable, permitting analysis of genetic interactions. The Deltajac1 Deltassq1 double mutant was more severely compromised for growth than either single mutant, suggesting a synthetic or additive effect of these mutations. Overexpression of Jac1p partially suppressed ssq1 slow growth and vice versa. Similar mitochondrial localization and similar mutant phenotypes suggest that Ssq1p and Jac1p are functional partners in iron homeostasis.

Published

2001

6. Yeast mitochondrial protein, Nfs1p, coordinately regulates iron-sulfur cluster proteins, cellular iron uptake, and iron distribution

Author

Jie Li, Mikhail Kogan, Simon A.B. Knight, Debkumar Pain, and Andrew Dancis

Subjects

Iron-Sulfur Proteins, Saccharomyces cerevisiae Proteins, FMN Reductase, Iron, Saccharomyces cerevisiae, Mutant, Molecular Sequence Data, Iron–sulfur cluster, Mitochondrion, Biochemistry, Fungal Proteins, Mitochondrial Proteins, chemistry.chemical_compound, Gene Expression Regulation, Fungal, Homeostasis, NADH, NADPH Oxidoreductases, Amino Acid Sequence, Cloning, Molecular, Promoter Regions, Genetic, Molecular Biology, Hydro-Lyases, Regulation of gene expression, biology, Genetic Complementation Test, Cell Biology, biology.organism_classification, Yeast, Mitochondria, chemistry, Cysteine desulfurase activity, Mitochondrial matrix, Sulfurtransferases, Mutation, Sequence Alignment, Transcription Factors

Abstract

Nfs1p is the yeast homolog of the bacterial proteins NifS and IscS, enzymes that release sulfur from cysteine for iron-sulfur cluster assembly. Here we show that the yeast mitochondrial protein Nfs1p regulates cellular and mitochondrial iron homeostasis. A strain of Saccharomyces cerevisiae, MA14, with a missense NFS1 allele (I191S) was isolated in a screen for altered iron-dependent gene regulation. This mutant exhibited constitutive up-regulation of the genes of the cellular iron uptake system, mediated through effects on the Aft1p iron-regulatory protein. Iron accumulating in the mutant cells was retained in the mitochondrial matrix while, at the same time, iron-sulfur proteins were deficient. In this work, the yeast protein was localized to mitochondria, and the gene was shown to be essential for viability. Furthermore, Nfs1p in the MA14 mutant was found to be markedly decreased, suggesting that this low protein level produced the observed regulatory effects. This hypothesis was confirmed by experiments in which expression of wild-type Nfs1p from a regulated galactose-induced promoter was turned off, leading to recapitulation of the iron regulatory phenotypes characteristic of the MA14 mutant. These phenotypes include decreases in iron-sulfur protein activities coordinated with increases in cellular iron uptake and iron distribution to mitochondria.

Published

1999

7. A GTP-dependent 'push' is generally required for efficient protein translocation across the mitochondrial inner membrane into the matrix

Author

Naresh Babu V. Sepuri, Donna M. Gordon, and Debkumar Pain

Subjects

Membrane potential, Protein Denaturation, GTP', Biological Transport, Cell Biology, Intracellular Membranes, Saccharomyces cerevisiae, Biology, Biochemistry, Transmembrane protein, Cell biology, Mitochondria, Fungal Proteins, Adenosine Triphosphate, Mitochondrial biogenesis, Translocase of the inner membrane, Inner membrane, Urea, Guanosine Triphosphate, Intermembrane space, Inner mitochondrial membrane, Molecular Biology, Mitochondrial ADP, ATP Translocases

Abstract

Mitochondrial biogenesis requires translocation of numerous preproteins across both outer and inner membranes into the matrix of the organelle. This translocation process requires a membrane potential (DeltaPsi) and ATP. We have recently demonstrated that the efficient import of a urea-denatured preprotein into the matrix requires GTP hydrolysis (Sepuri, N. B. V., Schülke, N., and Pain, D. (1998) J. Biol. Chem. 273, 1420-1424). We now demonstrate that GTP is generally required for efficient import of various preproteins, both native and urea-denatured. The GTP participation is localized to a particular stage in the protein import process. In the presence of DeltaPsi but no added nucleoside triphosphates, the transmembrane movement of preproteins proceeds only to a point early in their translocation across the inner membrane. The completion of translocation into the matrix is independent of DeltaPsi but is dependent on a GTP-mediated "push." This push is likely mediated by a membrane-bound GTPase on the cis side of the inner membrane. This conclusion is based on two observations: (i) GTP does not readily cross the inner membrane barrier and hence, primarily acts outside the inner membrane to stimulate import, and (ii) the GTP-dependent stage of import does not require soluble constituents of the intermembrane space and can be observed in isolated mitoplasts. Efficient import into the matrix, however, is achieved only through the coordinated action of a cis GTP-dependent push and a trans ATP-dependent "pull."

Published

1998

8. GTP hydrolysis is essential for protein import into the mitochondrial matrix

Author

Norbert Schulke, Debkumar Pain, and Naresh Babu V. Sepuri

Subjects

GTP', Saccharomyces cerevisiae, GTPase, Mitochondrion, Biochemistry, Membrane Potentials, Adenosine Triphosphate, Cytosol, Escherichia coli, Inner membrane, Molecular Biology, Membrane potential, Oxidoreductases Acting on CH-NH Group Donors, biology, Hydrolysis, Biological Transport, Cell Biology, Intracellular Membranes, biology.organism_classification, Cell biology, Mitochondria, 1-Pyrroline-5-Carboxylate Dehydrogenase, Kinetics, Mitochondrial matrix, Guanosine Triphosphate

Abstract

Protein import into the innermost compartment of mitochondria (the matrix) requires a membrane potential (delta psi) across the inner membrane, as well as ATP-dependent interactions with chaperones in the matrix and cytosol. The role of nucleoside triphosphates other than ATP during import into the matrix, however, remains to be determined. Import of urea-denatured precursors does not require cytosolic chaperones. We have therefore used a purified and urea-denatured preprotein in our import assays to bypass the requirement of external ATP. Using this modified system, we demonstrate that GTP stimulates protein import into the matrix; the stimulatory effect is directly mediated by GTP hydrolysis and does not result from conversion of GTP to ATP. Both external GTP and matrix ATP are necessary; neither one can substitute for the other if efficient import is to be achieved. These results suggest a "push-pull" mechanism of import, which may be common to other post-translational translocation pathways.

Published

1998

9. Voltage-gated K+ channels contain multiple intersubunit association sites

Author

William R. Skach, LiWei Tu, Vincent P. Santarelli, Zu Fang Sheng, Carol Deutsch, and Debkumar Pain

Subjects

Gene isoform, Subfamily, Potassium Channels, Immunoprecipitation, Xenopus, Peptide, In Vitro Techniques, Biochemistry, RNA, Complementary, Xenopus laevis, Animals, Molecular Biology, Sequence Deletion, chemistry.chemical_classification, Binding Sites, Kv1.3 Potassium Channel, biology, Molecular Structure, Translation (biology), Cell Biology, biology.organism_classification, Molecular biology, Transmembrane protein, Peptide Fragments, Amino acid, Cell biology, chemistry, Potassium Channels, Voltage-Gated, Protein Biosynthesis, Oocytes, Female, Ion Channel Gating

Abstract

A domain in the cytoplasmic NH2 terminus of voltage-gated K+ channels supervises the proper assembly of specific tetrameric channels (Li, M., Jan, J. M., and Jan, L. Y.(1992) Science 257, 1225-1230; Shen, N. V., Chen X., Boyer, M. M., and Pfaffinger, P. (1993) Neuron 11, 67-76). It is referred to as a first tetramerization domain, or T1 (Shen, N. V., Chen X., Boyer, M. M., and Pfaffinger, P.(1993) Neuron 11, 67-76). However, a deletion mutant of Kv1.3 that lacks the first 141 amino acids, Kv1.3 (T1(-)) forms functional channels, suggesting that additional association sites in the central core of Kv1.3 mediate oligomerization. To characterize these sites, we have tested the abilities of cRNA Kv1.3 (T1(-)) fragments co-injected with Kv1.3 (T1(-)) to suppress current in Xenopus oocytes. The fragments include portions of the six putative transmembrane segments, S1 through S6, specifically: S1, S1-S2, S1-S2-S3, S2-S3, S2-S3-S4, S3-S4, S3-S4-S5, S2 through COOH, S3 through COOH, S4 through COOH, and S5-S6-COOH. Electrophysiologic experiments show that the fragments S1-S2-S3, S3-S4-S5, S2 through COOH, and S3 through COOH strongly suppress Kv1.3 (T1(-)) current, while others do not. Suppression of expressed current is due to specific effects of the translated peptide Kv1.3 fragments, as validated by in vivo immunoprecipitation studies of a strong suppressor and a nonsuppressor. Pulse-chase experiments indicate that translation of truncated peptide fragments neither prevents translation of Kv1.3 (T1(-)) nor increases its rate of degradation. Co-immunoprecipitation experiments suggest that suppression involves direct association of a peptide fragment with Kv1.3 (T1(-)). Fragments that strongly suppress Kv1.3 (T1(-)) also suppress an analogous NH2-terminal deletion mutant of Kv2.1 (Kv2.1 (DeltaN139)), an isoform belonging to a different subfamily. Our results indicate that sites in the central core of Kv1.3 facilitate intersubunit association and that there are suppression sites in the central core, which are promiscuous across voltage-gated K+ channel subfamilies.

Published

1996