Prem Kumar Sinha scite author profile

The bacterial proton-translocating NADH:quinone oxidoreductase (NDH-1) consists of two domains, a peripheral arm and a membrane arm. NuoH is a counterpart of ND1, which is one of seven mitochondrially encoded hydrophobic subunits, and is considered to be involved in quinone/inhibitor binding. Sequence comparison in a wide range of species showed that NuoH is comprehensively conserved, particularly with charged residues in the cytoplasmic side loops. We have constructed 40 mutants of 27 conserved residues predicted to be in the cytoplasmic side loops of 6 reductase activity, undetectable NDH-1 in Blue Native gels, low contents of peripheral subunits (especially NuoB and NuoCD) bound to the membranes, and a significant loss of the membrane potential and proton-pumping function coupled to deamino-NADH oxidation. The results indicated that these conserved residues located in the cytoplasmic side loops are essential for the assembly of the peripheral subunits with the membrane arm. Implications for the involvement of NuoH (ND1) in maintaining the structure and function of NDH-1 are discussed.The H ϩ -translocating NADH:quinone (Q) 3 oxidoreductase (EC 1.6.5.3) is a complex membrane-bound enzyme that catalyzes electron transfer from NADH to Q coupled with proton pumping across the inner mitochondrial membrane (complex I) or the bacterial cytoplasmic membrane (NDH-1) (1, 2). The Escherichia coli NDH-1 is composed of 13 subunits and all 13 nuo-encoded subunits from E. coli (NuoA-N) have their homologues present in the mitochondrial enzyme that contains 45 subunits (3-5). A chromosomal deletion of all nuo genes has been achieved earlier by homologous recombination in E. coli (6). Thus NDH-1 serves as a model system to elucidate the structure and function of complex I due to its structural simplicity and ease of gene manipulation (7-10). Electron microscopic analyses have established that NDH-1/complex I has a characteristic L-shaped structure consisting of two domains, a peripheral arm protruding into the cytoplasm (or the matrix) and a membrane domain embedded within the cytoplasmic membrane (or the inner mitochondrial membrane) (11-13). The NADH binding site and all known redox cofactors of complex I are located in the peripheral domain (14,15). This was also confirmed by the crystal structure of the peripheral arm from Thermus thermophilus (16). Unlike the peripheral arm, the membrane arm does not contain any prosthetic group identified so far. Information about the structural and functional roles of these membrane domain subunits are rather limited despite recent progress in the field of structural biology. Based on the projection structure of the membrane domain and detergent-based fractionation study that led to the disruption of the membrane arm into fragments containing NuoL/M, NuoA/ K/N, and NuoH/J subunits, a speculative arrangement of the membrane segment of E. coli NDH-1 has been proposed, wherein subunits NuoA, NuoK, NuoN, NuoJ, and NuoH are present in the vicinity of the peripheral arm, whereas the NuoL an...

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Structural Contribution of C-terminal Segments of NuoL (ND5) and NuoM (ND4) Subunits of Complex I from Escherichia coli

Torres‐Bacete

Sinha

Matsuno‐Yagi

et al. 2011

Journal of Biological Chemistry

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The proton-translocating NADH-quinone oxidoreductase (complex I/NDH-1) is a multisubunit enzymatic complex. It has a characteristic L-shaped form with two domains, a hydrophilic peripheral domain and a hydrophobic membrane domain. The membrane domain contains three antiporter-like subunits (NuoL, NuoM, and NuoN, Escherichia coli naming) that are considered to be involved in the proton translocation. Deletion of either NuoL or NuoM resulted in an incomplete assembly of NDH-1 and a total loss of the NADH-quinone oxidoreductase activity. We have truncated the C terminus segments of NuoM and NuoL by introducing STOP codons at different locations using site-directed mutagenesis of chromosomal DNA. Our results suggest an important structural role for the C-terminal segments of both subunits. The data further advocate that the elimination of the last transmembrane helix (TM14) of NuoM and the TM16 (at least C-terminal seven residues) or together with the HL helix and the TM15 of the NuoL subunit lead to reduced stability of the membrane arm and therefore of the whole NDH-1 complex. A region of NuoL critical for stability of NDH-1 architecture has been discussed.

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Conserved Amino Acid Residues of the NuoD Segment Important for Structure and Function of Escherichia coli NDH-1 (Complex I)

Sinha

Castro-Guerrero²,

Patki³

et al. 2015

Biochemistry

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The NuoD segment (homologue of mitochondrial 49 kDa subunit) of the proton-translocating NADH:quinone oxidoreductase (complex I/NDH-1) from Escherichia coli is in the hydrophilic domain and bears many highly conserved amino acid residues. The three-dimensional structural model of NDH-1 suggests that the NuoD segment, together with the neighboring subunits, constitutes a putative quinone binding cavity. We used the homologous DNA recombination technique to clarify the role of selected key amino acid residues of the NuoD segment. Among them, residues Tyr273 and His224 were considered candidates for having important interactions with the quinone headgroup. Mutant Y273F retained partial activity but lost sensitivity to capsaicin-40. Mutant H224R scarcely affected the activity, suggesting that this residue may not be essential. His224 is located in a loop near the N-terminus of the NuoD segment (Gly217–Phe227) which is considered to form part of the quinone binding cavity. In contrast to the His224 mutation, mutants G217V, P218A, and G225V almost completely lost the activity. One region of this loop is positioned close to a cytosolic loop of the NuoA subunit in the membrane domain, and together they seem to be important in keeping the quinone binding cavity intact. The structural role of the longest helix in the NuoD segment located behind the quinone binding cavity was also investigated. Possible roles of other highly conserved residues of the NuoD segment are discussed.

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Distinctive Solvation Patterns Make Renal Osmolytes Diverse

Jackson-Atogi

Sinha

Rösgen

2013

Biophysical Journal

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The kidney uses mixtures of five osmolytes to counter the stress induced by high urea and NaCl concentrations. The individual roles of most of the osmolytes are unclear, and three of the five have not yet been thermodynamically characterized. Here, we report partial molar volumes and activity coefficients of glycerophosphocholine (GPC), taurine, and myo-inositol. We derive their solvation behavior from the experimental data using Kirkwood-Buff theory. We also provide their solubility data, including solubility data for scyllo-inositol. It turns out that renal osmolytes fall into three distinct classes with respect to their solvation. Trimethyl-amines (GPC and glycine-betaine) are characterized by strong hard-sphere-like self-exclusion; urea, taurine, and myo-inositol have a tendency toward self-association; sorbitol and most other nonrenal osmolytes have a relatively constant, intermediate solvation that has components of both exclusion and association. The data presented here show that renal osmolytes are quite diverse with respect to their solvation patterns, and they can be further differentiated based on observations from experiments examining their effect on macromolecules. It is expected, based on the available surface groups, that each renal osmolyte has distinct effects on various classes of biomolecules. This likely allows the kidney to use specific combinations of osmolytes independently to fine-tune the chemical activities of several types of molecules.

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Prem Kumar Sinha

Critical Roles of Subunit NuoH (ND1) in the Assembly of Peripheral Subunits with the Membrane Domain of Escherichia coli NDH-1

Structural Contribution of C-terminal Segments of NuoL (ND5) and NuoM (ND4) Subunits of Complex I from Escherichia coli

Conserved Amino Acid Residues of the NuoD Segment Important for Structure and Function of Escherichia coli NDH-1 (Complex I)

Distinctive Solvation Patterns Make Renal Osmolytes Diverse

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