Molecular cloning of subunits of complex I from Neurospora crassa. Primary structure and in vitro expression of a 22-kDa polypeptide

A lambda gt11 cDNA expression library was screened with antibodies directed against individual subunits of complex I from Neurospora crassa. Clones encoding cytoplasmically synthesized polypeptides with apparent molecular masses of 22, 29, 31, and 33 kDa were isolated. Northern blot analysis revealed that the corresponding genes are transcribed into mRNA species of about 0.85, 0.95, 1.3, and 1.4 kilobases, respectively. Further characterization of clones encoding the 22-kDa subunit was performed. A cDNA insert of 755 base pairs containing the complete coding sequence was used to express the polypeptide in vitro. A precursor of the protein is synthesized on cytoplasmic ribosomes without a cleavable signal sequence. Our data indicate that after import into the organelle and before assembly into complex I, the 22-kDa polypeptide forms intramolecular disulfide bridge(s). Nucleotide sequencing revealed an open reading frame coding for a protein of 183 amino acids. A molecular mass of 20,828 daltons was calculated. The polypeptide is hydrophilic and contains no obvious membrane-spanning domains. Eight cysteine residues arranged in a regular pattern are found in the primary structure of the protein. Therefore, this subunit is a good candidate to bind at least one of the iron-sulfur centers present in complex I of the respiratory chain.     

Site-specific S-glutathiolation of mitochondrial NADH ubiquinone reductase

The generation of reactive oxygen species in mitochondria acts as a redox signal in triggering cellular events such as apoptosis, proliferation, and senescence. Overproduction of superoxide (O2*-) and O2*--derived oxidants changes the redox status of the mitochondrial GSH pool. An electron transport protein, mitochondrial complex I, is the major host of reactive/regulatory protein thiols. An important response of protein thiols to oxidative stress is to reversibly form protein mixed disulfide via S-glutathiolation. Exposure of complex I to oxidized GSH, GSSG, resulted in specific S-glutathiolation at the 51 kDa and 75 kDa subunits (Beer et al. (2004) J. Biol. Chem. 279, 47939-47951). Here, to investigate the molecular mechanism of S-glutathiolation of complex I, we prepared isolated bovine complex I under nonreducing conditions and employed the techniques of mass spectrometry and EPR spin trapping for analysis. LC/MS/MS analysis of tryptic digests of the 51 kDa and 75 kDa polypeptides from glutathiolated complex I (GS-NQR) revealed that two specific cysteines (C206 and C187) of the 51 kDa subunit and one specific cysteine (C367) of the 75 kDa subunit were involved in redox modifications with GS binding. The electron transfer activity (ETA) of GS-NQR in catalyzing NADH oxidation by Q1 was significantly enhanced. However, O2*- generation activity (SGA) mediated by GS-NQR suffered a mild loss as measured by EPR spin trapping, suggesting the protective role of S-glutathiolation in the intact complex I. Exposure of NADH dehydrogenase (NDH), the flavin subcomplex of complex I, to GSSG resulted in specific S-glutathiolation on the 51 kDa subunit. Both ETA and SGA of S-glutathiolated NDH (GS-NDH) decreased in parallel as the dosage of GSSG increased. LC/MS/MS analysis of a tryptic digest of the 51 kDa subunit from GS-NDH revealed that C206, C187, and C425 were glutathiolated. C425 of the 51 kDa subunit is a ligand residue of the 4Fe-4S N3 center, suggesting that destruction of 4Fe-4S is the major mechanism involved in the inhibition of NDH. The result also implies that S-glutathiolation of the 75 kDa subunit may play a role in protecting the 4Fe-4S cluster of the 51 kDa subunit from redox modification when complex I is exposed to redox change in the GSH pool.     

Complex of pregnancy-associated plasma protein-A and the proform of eosinophil major basic protein. Disulfide structure and carbohydrate attachment

Pregnancy-associated plasma protein-A (PAPP-A) is a metzincin superfamily metalloproteinase responsible for cleavage of insulin-like growth factor-binding protein-4, thus causing release of bound insulin-like growth factor. PAPP-A is secreted as a dimer of 400 kDa but circulates in pregnancy as a disulfide-bound 500-kDa 2:2 complex with the proform of eosinophil major basic protein (pro-MBP), recently shown to function as a proteinase inhibitor of PAPP-A. Except for PAPP-A2, PAPP-A does not share global similarity with other proteins. Three lin-notch (LNR or LIN-12) modules and five complement control protein modules (also known as SCR modules) have been identified in PAPP-A by sequence similarity with other proteins, but no data are available that allow unambiguous prediction of disulfide bonds of these modules. To establish the connectivities of cysteine residues of the PAPP-A.pro-MBP complex, biochemical analyses of peptides derived from purified protein were performed. The PAPP-A subunit contains a total of 82 cysteine residues, of which 81 have been accounted for. The pro-MBP subunit contains 12 cysteine residues, of which 10 have been accounted for. Within the 2:2 complex, PAPP-A is dimerized by a single disulfide bond; pro-MBP is dimerized by two disulfides, and each PAPP-A subunit is connected to a pro-MBP subunit by two disulfide bonds. All other disulfides are intrachain bridges. We also show that of 13 potential sites for N-linked carbohydrate substitution of the PAPP-A subunit, 11 are occupied. The large number of disulfide bonds of the PAPP-A.pro-MBP complex imposes many restraints on polypeptide folding, and knowledge of the disulfide pattern of PAPP-A will facilitate structural studies based on recombinant expression of individual, putative PAPP-A domains. Furthermore, it will allow rational experimental design of functional studies aimed at understanding the formation of the PAPP-A.pro-MBP complex, as well as the inhibitory mechanism of pro-MBP.     

Cloning and sequence analysis of a cDNA encoding a Brazil nut protein exceptionally rich in methionine

The primary amino acid sequence of an abundant methionine-rich seed protein found in Brazil nut (Bertholletia excelsa H.B.K.) has been elucidated by protein sequencing and from the nucleotide sequence of cDNA clones. The 9 kDa subunit of this protein was found to contain 77 amino acids of which 14 were methionine (18%) and 6 were cysteine (8%). Over half of the methionine residues in this subunit are clustered in two regions of the polypeptide where they are interspersed with arginine residues. In one of these regions, methionine residues account for 5 out of 6 amino acids and four of these methionine residues are contiguous. The sequence data verifies that the Brazil nut sulfur-rich protein is synthesized as a precursor polypeptide that is considerably larger than either of the two subunits of the mature protein. Three proteolytic processing steps by which the encoded polypeptide is sequentially trimmed to the 9 kDa and 3 kDa subunit polypeptides have been correlated with the sequence information. In addition, we have found that the sulfur-rich protein from Brazil nut is homologous in its amino acid sequence to small water-soluble proteins found in two other oilseeds, castor bean (Ricinus communis) and rapeseed (Brassica napus). When the amino acid sequences of these three proteins are aligned to maximize homology, the arrangement of cysteine residues is conserved. However, the two subunits of the Brazil nut protein contain over 19% methionine whereas the homologous proteins from castor bean and rapeseed contain only 2.1% and 2.6% methionine, respectively.     

Cysteine 254 of the 73-kDa A subunit is responsible for inhibition of the coated vesicle (H+)-ATPase upon modification by sulfhydryl reagents.

The vacuolar class of (H+)-ATPases are highly sensitive to sulfhydryl reagents, such as N-ethylmaleimide. The cysteine residue which is responsible for inhibition of the coated vesicle (H+)-ATPase upon modification by N-ethylmalemide is located in subunit A and is able to form a disulfide bond with the cysteine moiety of cystine through an exchange reaction. This unique property distinguishes this cysteine residue from the remaining cysteine residues of the (H+)-ATPase. Using this reaction, we selectively labeled the cystine-reactive cysteine residue of subunit A with fluorescein-maleimide. After complete digestion of the labeled subunit A by V8 protease, a single labeled fragment of molecular mass 3.9 kDa was isolated and the amino-terminal sequence was determined. This fragment contains 2 cysteine residues, Cys240 and Cys254. Since Cys254 is conserved among all vacuolar (H+)-ATPases whereas Cys240 is not, it is likely that Cys254 is the residue which is responsible for the sensitivity of the vacuolar (H+)-ATPase to sulfhydryl reagents.     

Subunit composition of photosystem I and identification of center X as a [4Fe-4S] iron-sulfur cluster

A photosystem I (PS-I) preparation from barley (Hordeum vulgare L.) containing the reaction center protein P700-chlorophyll a-protein 1 (CP1) and smaller polypeptides with apparent molecular masses of 18, 16, 14, 9.5, 9, 4, and 1.5 kDa has been analyzed with respect to subunit stoichiometry. CP1 contains two homologous subunits with approximate masses of 82 kDa. CP1 and the smaller polypeptides were isolated, and the amino acid composition of each component and of the PS-I preparation was determined. Based on the amino acid composition data and the determined ability of each isolated polypeptide to bind Coomassie Brilliant Blue, the PS-I complex is shown to contain 1 mol of each of the homologous 82-kDa polypeptides as well as 1 mol of the 18-, 16-, 9.5-, and 9-kDa polypeptides for each mol of P700. The total polypeptide mass of the PS-I complex is 209 kDa excluding tryptophan and approximately 220 kDa including tryptophan. The two 82-kDa subunits present/P700 provide cysteine residues for binding only one Fe-S center. In conjunction with the earlier reported binding of four iron and four acid-labile sulfides to CP1/P700 (H?j, P. B., Svendsen, I., Scheller, H. V., and M?ller, B. L. (1987) J. Biol. Chem. 262, 12676-12684), this demonstrates the center X is a [4Fe-4S] cluster and eliminates the possibility of center X being composed of two [2Fe-2S] clusters.     

Iron-sulfur cluster N2 of the Escherichia coli NADH:ubiquinone oxidoreductase (complex I) is located on subunit NuoB

The proton-pumping NADH:ubiquinone oxidoreductase, also called respiratory complex I, couples the transfer of electrons from NADH to ubiquinone with the translocation of protons across the membrane. One FMN and up to 9 iron-sulfur (Fe/S) clusters participate in the redox reaction. There is discussion that the EPR-detectable Fe/S cluster N2 is involved in proton pumping. However, the assignment of this cluster to a distinct subunit of the complex as well as the number of Fe/S clusters giving rise to the EPR signal are still under debate. Complex I from Escherichia coli consists of 13 polypeptides called NuoA to N. Either subunit NuoB or NuoI could harbor Fe/S cluster N2. Whereas NuoB contains a unique motif for the binding of one Fe/S cluster, NuoI contains a typical ferredoxin motif for the binding of two Fe/S clusters. Individual mutation of all four conserved cysteine residues in NuoB resulted in a loss of complex I activity and of the EPR signal of N2 in the cytoplasmic membrane as well as in the isolated complex. Individual mutations of all eight conserved cysteine residues of NuoI revealed a variable phenotype. Whereas cluster N2 was lost in most NuoI mutants, it was still present in the cytoplasmic membranes of the mutants NuoI C63A and NuoI C102A. N2 was also detected in the complex isolated from the mutant NuoI C102A. From this we conclude that the Fe/S cluster N2 is located on subunit NuoB.     

Solution structure of HndAc: a thioredoxin-like domain involved in the NADP-reducing hydrogenase complex

The NADP-reducing hydrogenase complex from Desulfovibrio fructosovorans is a heterotetramer encoded by the hndABCD operon. Sequence analysis indicates that the HndC subunit (52 kDa) corresponds to the NADP-reducing unit, and the HndD subunit (63.5 kDa) is homologous to Clostridium pasteurianum hydrogenase. The role of HndA and HndB subunits (18.8 kDa and 13.8 kDa, respectively) in the complex remains unknown. The HndA subunit belongs to the [2Fe-2S] ferredoxin family typified by C. pasteurianum ferredoxin. HndA is organized into two independent structural domains, and we report in the present work the NMR structure of its C-terminal domain, HndAc. HndAc has a thioredoxin-like fold consisting in four beta-strands and two relatively long helices. The [2Fe-2S] cluster is located near the surface of the protein and bound to four cysteine residues particularly well conserved in this class of proteins. Electron exchange between the HndD N-terminal [2Fe-2S] domain (HndDN) and HndAc has been previously evidenced, and in the present studies we have mapped the binding site of the HndDN domain on HndAc. A structural analysis of HndB indicates that it is a FeS subunit with 41% similarity with HndAc and it contains a possible thioredoxin-like fold. Our data let us propose that HndAc and HndB can form a heterodimeric intermediate in the electron transfer between the hydrogenase (HndD) active site and the NADP reduction site in HndC.     

The protein responsible for center A/B in spinach photosystem I: isolation with iron-sulfur cluster(s) and complete sequence analysis

The 9 kDa polypeptide from spinach photosystem I (PS I) complex was isolated with iron-sulfur cluster(s) by an n-butanol extraction procedure under anaerobic conditions. The polypeptide was soluble in a saline solution and contained non-heme irons and inorganic sulfides. The absorption spectrum of this iron-sulfur protein was very similar to those of bacterial-type ferredoxins. The amino acid sequence of the polypeptide was determined by using a combination of gas-phase sequencer and conventional procedures. It was composed of 80 amino acid residues giving a molecular weight of 8,894, excluding iron and sulfur atoms. The sequence showed the typical distribution of cysteine residues found in bacterial-type ferredoxins and was highly homologous (91% homology) to that deduced from the chloroplast gene, frxA, of liverwort, Marchantia polymorpha. The 9 kDa polypeptide is considered to be the iron-sulfur protein responsible for the electron transfer reaction in PS I from center X to [2Fe-2S] ferredoxin, namely a polypeptide with center(s) A and/or B in PS I complex. It is noteworthy that the 9 kDa polypeptide was rather hydrophilic and a little basic in terms of the primary structure. A three-dimensional structure was simulated on the basis of the tertiary structure of Peptococcus aerogenes [8Fe-8S] ferredoxin, and the portions in the molecule probably involved in contacting membranes or other polypeptides were indicated. The phylogenetic implications of the structure of the present polypeptide as compared with those of several bacterial-type ferredoxins are discussed.     

Processing of the 24 kDa subunit mitochondrial import signal is not required for assembly of functional complex I in Yarrowia lipolytica.

A small deletion in the second intron of human NDUFV2 (IVS2+5_+8delGTAA) has been shown to cause hypertrophic cardiomyopathy and encephalomyopathy [Bénit, P., Beugnot, R., Chretien, D., Giurgea, I., de Lonlay-Debeney, P., Issartel, J.P., Kerscher, S., Rustin, P., R?tig, A. & Munnich, A. (2003) Human Mutat.21, 582-586]. Skipping of exon 2 results in a partial deletion of the mitochondrial targeting sequence of the precursor for the 24 kDa subunit of respiratory chain complex I. Immunoreactivity of the 24 kDa subunit and complex I activity, both present at 30-50% of normal levels in patient mitochondria, raised the question of how the mutant 24 kDa subunit precursor can be imported and assembled into functional complex I. In the present study, we have remodelled the human NDUFV2 mutation by deleting codons 17-32 from the orthologous NUHM gene of the obligate aerobic yeast Yarrowia lipolytica. The resulting mutant enzyme was indistinguishable from parental complex I with regard to activity, inhibitor sensitivity and EPR signature. Size, isoelectric point and presumably also N-terminal acetylation were altered, indicating that the residual targeting sequence was retained on the mature 24 kDa protein. Complete removal of the NUHM presequence resulted in the absence of complex I activity, strongly arguing against the presence of an internal mitochondrial targeting sequence within the 24 kDa protein.     

Cysteine-directed cross-linking to subunit B suggests that subunit E forms part of the peripheral stalk of the vacuolar H+-ATPase.

We have employed a combination of site-directed mutagenesis and covalent cross-linking to identify subunits in close proximity to subunit B in the vacuolar H(+)-ATPase (V-ATPase) complex. Unique cysteine residues were introduced into a Cys-less form of subunit B, and the V-ATPase complex in isolated vacuolar membranes from each mutant strain was reacted with the bifunctional, photoactivable maleimide reagent 4-(N-maleimido)benzophenone. Photoactivation resulted in cross-linking of the unique sulfhydryl groups on subunit B with other subunits in the complex. Four of the eight mutants constructed containing a unique cysteine residue at Ala(15), Lys(45), Glu(494), or Thr(501) resulted in the formation of cross-linked products, which were recognized by Western blot analysis using antibodies against both subunits B and E. These products had a molecular mass of 84 kDa, consistent with a cross-linked product of subunits B and E. Molecular modeling of subunit B places Ala(15) and Lys(45) near the top of the V(1) structure (i.e. farthest from the membrane), whereas Glu(494) and Thr(501) are predicted to reside near the bottom of V(1), with all four residues predicted to be oriented toward the external surface of the complex. A model incorporating these and previous data is presented in which subunit E exists in an extended conformation on the outer surface of the A(3)B(3) hexamer that forms the core of the V(1) domain. This location for subunit E suggests that this subunit forms part of the peripheral stalk of the V-ATPase that links the V(1) and V(0) domains.     

Monomaleimidogold labeling of the gamma subunit of the Escherichia coli F1 ATPase examined by cryoelectron microscopy.

A novel approach for locating sites of interest in a protein complex has been developed using monomaleimidonanogold (MMN). The Escherichia coli F1 ATPase, when prepared without the delta subunit, contains only a single reactive cysteine on one of the three copies of the alpha subunit. This site was reacted with MMN and the gold cluster visualized on the protein complex by cryoelectron microscopy. Additional sites for modification with MMN were added by introducing cysteine residues through site-directed mutagenesis. Labeling of two mutants, gamma S8-C and gamma T106-C, in which Ser8 and Thr106, respectively, had been replaced by a cysteine, placed the gold cluster on the central mass that is seen in the hexagonal projection of the ECF1 complex. The results establish that the central mass contains the N-terminal part of the gamma subunit.     

The 24-kDa iron-sulphur subunit of complex I is required for enzyme activity.

We have cloned the nuclear gene encoding the 24-kDa iron-sulphur subunit of complex I from Neurospora crassa. The gene was inactivated in vivo by repeat-induced point-mutations, and mutant strains lacking the 24-kDa protein were isolated. Mutant nuo24 appears to assemble an almost intact complex I only lacking the 24-kDa subunit. However, we also found reduced levels of the NADH-binding, 51-kDa subunit of the enzyme. Surprisingly, the complex I from the nuo24 strain lacks NADH:ferricyanide reductase activity. In agreement with this, the respiration of intact mitochondria or mitochondrial membranes from the mutant strain is insensitive to rotenone inhibition. These results suggest that the nuo24 complex is not functioning in electron transfer and the 24-kDa protein is absolutely required for complex I activity. This phenotype may explain the findings that the 24-kDa iron-sulphur protein is reduced or absent in human mitochondrial diseases. In addition, selected substitutions of cysteine to alanine residues in the 24-kDa protein suggest that binding of the iron-sulphur centre is a requisite for protein assembly.     

A 9 kDa antifreeze protein from the Antarctic springtail, Gomphiocephalus hodgsoni

A 9 kDA antifreeze protein (AFP) was isolated and purified from the Antarctic springtail, Gomphiocephalus hodgsoni. By combining selective sampling procedures and a modified ice affinity purification protocol it was possible to directly isolate a single AFP protein without recourse to chromatographic separation techniques. Mass spectrometry identified a single 9 kDa component in the purified ice fraction. Intramolecular disulphide bonding was suggested by the presence of 12 cysteine residues. The specific amino acid composition is unique, particularly with regard to the presence of histidine (11.5%). But it also shows noticeable commonalities with insect AFPs in the abundance of cysteine (13.8%), while simultaneously hinting, through the presence of glycine (11.5%), that the metabolic building blocks of AFPs in Collembola may have a phylogenetically-determined component.     

The ND5 subunit was labeled by a photoaffinity analogue of fenpyroximate in bovine mitochondrial complex I

Fenpyroximate is a potent inhibitor of the mitochondrial proton-translocating NADH-quinone oxidoreductase (complex I). We synthesized its photoaffinity analogue [(3)H](trifluoromethyl)phenyldiazirinylfenpyroximate ([(3)H]TDF). When bovine heart submitochondrial particles (SMP) were illuminated with UV light in the presence of [(3)H]TDF, radioactivity was mostly incorporated into a 50 kDa band. There was a good correlation between radioactivity labeling of the 50 kDa band and inhibition of the NADH oxidase activity, indicating that a 50 kDa protein is responsible for the inactivation of complex I. Blue native gel electrophoresis of the [(3)H]TDF-labeled SMP revealed that the majority of radioactivity was found in complex I. Analysis of the complex I band on an SDS gel showed a major peak of radioactivity at approximately 50 kDa. There are three subunits in complex I that migrate in this region: FP51K, IP49K, and ND5. Further analysis using the 2D gel electrophoresis implied that the labeled protein was the ND5 subunit. Labeling of the ND5 subunit was stimulated by NADH/NADPH but was prevented by various complex I inhibitors. Amiloride derivatives that are known to be inhibitors of Na(+)/H(+) antiporters also diminished the labeling. In agreement with the protective effect, we observed that the amiloride derivatives inhibited NADH-ubiquinone-1 reductase activity but not NADH-K(3)Fe(CN)(6) reductase activity in bovine SMP. These results suggest that the ND5 subunit is involved in construction of the inhibitor- and quinone-binding site(s). Furthermore, it seems likely that the ND5 subunit may participate in H(+)(Na(+)) translocation in coupling site 1.     

The phosphorylation of subunits of complex I from bovine heart mitochondria

In bovine heart mitochondria and in submitochondrial particles, membrane-associated proteins with apparent molecular masses of 18 and 10 kDa become strongly radiolabeled by [(32)P]ATP in a cAMP-dependent manner. The 18-kDa phosphorylated protein is subunit ESSS from complex I and not as previously reported the 18 k subunit (with the N-terminal sequence AQDQ). The phosphorylated residue in subunit ESSS is serine 20. In the 10 kDa band, the complex I subunit MWFE was phosphorylated on serine 55. In the presence of protein kinase A and cAMP, the same subunits of purified complex I were phosphorylated by [(32)P]ATP at the same sites. Subunits ESSS and MWFE both contribute to the membrane arm of complex I. Each has a single hydrophobic region probably folded into a membrane spanning alpha-helix. It is likely that the phosphorylation site of subunit ESSS lies in the mitochondrial matrix and that the site in subunit MWFE is in the intermembrane space. Subunit ESSS has no known role, but subunit MWFE is required for assembly into complex I of seven hydrophobic subunits encoded in the mitochondrial genome. The possible effects of phosphorylation of these subunits on the activity and/or the assembly of complex I remain to be explored.     

ND3, ND1 and 39 kDa subunits are more exposed in the de-active form of bovine mitochondrial complex I

An intriguing feature of mitochondrial complex I from several species is the so-called A/D transition, whereby the idle enzyme spontaneously converts from the active (A) form to the de-active (D) form. The A/D transition plays an important role in tissue response to the lack of oxygen and hypoxic deactivation of the enzyme is one of the key regulatory events that occur in mitochondria during ischaemia. We demonstrate for the first time that the A/D conformational change of complex I does not affect the macromolecular organisation of supercomplexes in vitro as revealed by two types of native electrophoresis. Cysteine 39 of the mitochondrially-encoded ND3 subunit is known to become exposed upon de-activation. Here we show that even if complex I is a constituent of the I + III₂ + IV (S₁) supercomplex, cysteine 39 is accessible for chemical modification in only the D-form. Using lysine-specific fluorescent labelling and a DIGE-like approach we further identified two new subunits involved in structural rearrangements during the A/D transition: ND1 (MT-ND1) and 39 kDa (NDUFA9). These results clearly show that structural rearrangements during de-activation of complex I include several subunits located at the junction between hydrophilic and hydrophobic domains, in the region of the quinone binding site. De-activation of mitochondrial complex I results in concerted structural rearrangement of membrane subunits which leads to the disruption of the sealed quinone chamber required for catalytic turnover.     

Site-directed cross-linking of b to the alpha, beta, and a subunits of the Escherichia coli ATP synthase

The b subunit dimer of the Escherichia coli ATP synthase, along with the delta subunit, is thought to act as a stator to hold the alpha(3)beta(3) hexamer stationary relative to the a subunit as the gammaepsilonc(9-12) complex rotates. Despite their essential nature, the contacts between b and the alpha, beta, and a subunits remain largely undefined. We have introduced cysteine residues individually at various positions within the wild type membrane-bound b subunit, or within b(24-156), a truncated, soluble version consisting only of the hydrophilic C-terminal domain. The introduced cysteine residues were modified with a photoactivatable cross-linking agent, and cross-linking to subunits of the F(1) sector or to complete F(1)F(0) was attempted. Cross-linking in both the full-length and truncated forms of b was obtained at positions 92 (to alpha and beta), and 109 and 110 (to alpha only). Mass spectrometric analysis of peptide fragments derived from the b(24-156)A92C cross-link revealed that cross-linking took place within the region of alpha between Ile-464 and Met-483. This result indicates that the b dimer interacts with the alpha subunit near a non-catalytic alpha/beta interface. A cysteine residue introduced in place of the highly conserved arginine at position 36 of the b subunit could be cross-linked to the a subunit of F(0) in membrane-bound ATP synthase, implying that at least 10 residues of the polar domain of b are adjacent to residues of a. Sites of cross-linking between b(24-156)A92C and beta as well as b(24-156)I109C and alpha are proposed based on the mass spectrometric data, and these sites are discussed in terms of the structure of b and its interactions with the rest of the complex.     

Two nuclear-coded subunits of mitochondrial complex I are similar to different domains of a bacterial formate hydrogenlyase subunit

A computer comparison of protein sequences revealed similarity between the 30.4 kDa subunit of complex I from the fungus Neurospora crassa and the ORF5 subunit of formate hydrogenlyase from Escherichia coli. The ORF5 protein was previously known to be homologous to the 49 kDa component of the mitochondrial enzyme. We show that the 30.4 kDa corresponds to the N-terminal part while the 49 kDa subunit corresponds to the C-terminal portion of the bacterial protein. Thus, this bacterial protein represents a fusion of the two mitochondrial polypeptides suggesting that the two complex I genes arose from a single ancestor. Our results indicate that the 30.4 kDa and 49 kDa subunits are part of a structural and functional unit in complex I.