Primary structure and mitochondrial import in vitro of the 20.9 kDa subunit of complex I from Neurospora crassa (original) (raw)
Related papers
Biochemistry, 1992
A small polypeptide subunit of the NADH:ubiquinone reductase (complex I) from Neurospora crassa has been identified by photoaffinity labeling to participate in the binding of ubiquinone [Heinrich, H., 8c Werner, S. (1992) Biochemistry (preceding paper in this issue)]. This polypeptide is further characterized by its primary structure and by an assessment of its localization within complex I. A Xgtl 1 cDNA expression library was screened using a specific antibody directed against this individual subunit of complex I. Two groups of clones, coding for polypeptide subunits of the appropriate apparent molecular weight, were isolated. One group was shown to contain the relevant recombinants. The derived amino acid sequence for the 9.5-kDa ubiquinone-binding polypeptide shows a similarity with a putative ubiquinolbinding subunit (also a 9.5-kDa polypeptide) from complex 111 of bovine heart [Usui, S., Yu, L., & Tu, C.-A. (1 990) Biochemistry 29, 46 18-46261. The polypeptide has a hydrophobic stretch of a sufficient length to span the membrane. It resists against extraction with NaBr or N a~C 0 3 , and therefore probably is buried in the so-called hydrophobic membrane portion of complex I. This nuclearly-encoded subunit lacks a typical cleavable presequence and is imported into isolated mitochondria by a membrane potentialdependent process. This research was supported by the Deutsche Forschungsgemeinschaft (SFB 184, Projekt B-5).
European Journal of Biochemistry, 1989
In mitochondria of Neurospora crassa grown in the presence of chloramphenicol a small form of NADH : ubiquinone reductase is made in place of the normal electron-transfer-complex I. This smaller enzyme has a molecular mass of approximately 350 kDa and consists of (at least) 13 different subunits which are all synthesized in the cytoplasm. The complex I which is normally found in Neurospora has a molecular mass of approximately 700 kDa and consists of around 30 different subunits, of which at least six are made in the mitochondria. Immunoblotting and peptide mapping suggest that the subunits of the small enzyme are homologous to subunits of the large enzyme, one subunit might even be identical. The small and the large NADH : ubiquinone reductases have the same high-affinity binding site for NADH but the two enzymes differ in the affinity and inhibitor sensitivity of the ubiquinone-binding site. The possibility is discussed that the small NADH : ubiquinone reductase is primitive isoform of complex I.
Molecular & Cellular Proteomics, 2010
Respiratory complex I (NADH:quinone oxidoreductase) is an entry point to the electron transport chain in the mitochondria of many eukaryotes. It is a large, multisubunit enzyme with a hydrophilic domain in the matrix and a hydrophobic domain in the mitochondrial inner membrane. Here we present a comprehensive analysis of the protein composition and post-translational modifications of complex I from Pichia pastoris, using a combination of proteomic and bioinformatic approaches. Forty-one subunits were identified in P. pastoris complex I, comprising the 14 core (conserved) subunits and 27 supernumerary subunits; seven of the core subunits are mitochondrial encoded. Three of the supernumerary subunits (named NUSM, NUTM, and NUUM) have not been observed previously in any species of complex I. However, homologues to all three of them are present in either Yarrowia lipolytica or Pichia angusta complex I. P. pastoris complex I has 39 subunits in common with Y. lipolytica complex I, 37 in common with N. crassa complex I, and 35 in common with the bovine enzyme. The mitochondrial encoded subunits (translated by the mold mitochondrial genetic code) retain their N-␣-formyl methionine residues. At least eight subunits are N-␣-acetylated, but the N-terminal modifications of the nuclear encoded subunits are not well-conserved. A combination of two methods of protein separation (SDS-PAGE and HPLC) and three different mass spectrometry techniques (peptide mass fingerprinting, tandem MS and molecular mass measurements) were required to define the protein complement of P. pastoris complex I. This requirement highlights the need for inclusive and comprehensive strategies for the characterization of challenging membrane-bound protein complexes containing both hydrophilic and hydrophobic components.
European Journal of Biochemistry, 1995
The proton-translocating NADH :ubiquinone oxidoreductase (complex I) was isolated from Escherichia coli by chromatographic steps performed in the presence of an alkylglucoside detergent at pH 6.0. The complex is obtained in a monodisperse state with a molecular mass of approximately 550000 Da and is composed of 14 subunits. The subunits were assigned to the 14 genes of the nu0 operon, partly based on their N-terminal sequences and partly on their apparent molecular masses. The preparation contains one noncovalently bound FMN/molecule. At least two binuclear (Nlb and Nlc) and three tetranuclear (N2, N3 and N4) iron-sulfur clusters were detected by EPR in the preparation when reduced with NADH. Their EPR characteristics remained mostly unaltered during the isolation process. After reconstitution in phospholipid membranes, the preparation catalyses piericidin-A-sensitive electron transfer from NADH to ubiquinone-2 with K,,, values similar to those of complex I in cytoplasmic membranes but with only 10% of the V,,, value. The isolated complex I was cleaved into three fragments when the pH was raised from 6.0 to 7.5 and the detergent exchanged to Triton X-100. One of these fragments is a water-soluble NADH dehydrogenase fragment which is composed of three subunits bearing at least four iron-sulfur clusters (Nlb, Nlc, N3 and N4) that can be reduced with NADH, one of them bearing FMN. The second, amphipathic, fragment, which is presumed to connect the NADH dehydrogenase fragment with the membrane, contains four subunits and at least one EPR-detectable iron-sulfur cluster whose spectral properties are reminiscent of the eucaryotic cluster N2. The third membrane fragment is composed of seven homologues of the mitochondrially encoded subunits of the eucaryotic complex I. This subunit arrangement coincidences to some extent with the order of the genes on the nu0 operon. A topological model of the E. coli complex I is proposed.
Journal of Molecular Biology, 1999
Respiratory chains of bacteria and mitochondria contain closely related forms of the proton-pumping NADH:ubiquinone oxidoreductase, or complex I. The bacterial complex I consists of 14 subunits, whereas the mitochondrial complex contains some 25 extra subunits in addition to the homologues of the bacterial subunits. One of these extra subunits with a molecular mass of 40 kDa belongs to a heterogeneous family of reductases/isomerases with a conserved nucleotide binding site. We deleted this subunit in Neurospora crassa by gene disruption. In the mutant nuo40, a complex I lacking the 40 kDa subunit is assembled. The mutant complex I does not contain tightly bound NADPH present in wild-type complex I. This NADPH cofactor is not connected to the respiratory electron pathway of complex I. The mutant complex has normal NADH dehydrogenase activity and contains the redox groups known for wild-type complex I, one¯avin mononucleotide and four iron-sulfur clusters detectable by electron paramagnetic resonance spectroscopy. In the mutant complex these groups are all readily reduced by NADH. However, the mutant complex is not capable of reducing ubiquinone. A recently described redox group identi®ed in wild-type complex I by UV-visible spectroscopy is not detectable in the mutant complex. We propose that the reductase/isomerase subunit with its NADPH cofactor takes part in the biosynthesis of this new redox group.
Biochemical Journal, 1993
We have cloned and sequenced a cDNA encoding a 17.8 kDa subunit of the hydrophobic fragment of complex I from Neurospora crassa. The deduced primary structure of this subunit was partially confirmed by automated Edman degradation of the isolated polypeptide. The sequence data obtained indicate that the 17.8 kDa subunit is made as an extended precursor of 20.8 kDa. Resistance of the polypeptide to alkaline extraction from mitochondrial membranes and the existence of a putative membrane-spanning domain suggests that the 17.8 kDa subunit is an intrinsic (bitopic) membrane protein. The in vitro synthesized precursor of the 17.8 kDa subunit can be efficiently imported into isolated mitochondria, where it is cleaved to the mature species by the metal-dependent matrix-processing peptidase. The in vitro imported mature subunit is found mainly exposed to the mitochondrial intermembrane space. However, a significant fraction of the imported polypeptide acquires the same membrane topology as t...
Biogenesis of mitochondrial ubiquinol
1982
The precursor proteins to the subunits of ubiquinol:cytochrome c reductase (cytochrome bc1 complex) of Neurospora crassa were synthesized in a reticulocyte lysate. These precursors were immunoprecipitated with antibodies prepared against the individual subunits and compared to the mature subunits immunoprecipitated or isolated from mitochondria. Most subunits were synthesized as precursors with larger apparent molecular weights (subunits I, 51,500 versus 50,000; subunit II, 47,500 versus 45,000; subunit IV (cytochrome c1), 38,000 versus 31,000; subunit V (Fe-S protein), 28,000 versus 25,000; subunit VII, 12,000 versus 11,500; subunit VIII, 11,600 versus 11,200). Subunit VI (14,000) was synthesized with the same apparent molecular weight. The post-translational transfer of subunits I, IV, V, and VII was studied in an in vitro system employing reticulocyte lysate and isolated mitochondria. The transfer and proteolytic processing of these precursors was found to be dependent on the mit...