The structure and function of mammalian membrane-attack complex/perforin-like proteins.

The membrane-attack complex (MAC) of complement pathway and perforin (PF) are important tools deployed by the immune system to target pathogens. Both perforin and the C9 component of the MAC contain a common 'MACPF' domain and form pores in the cell membrane as part of their function. The MAC targets gram-negative bacteria and certain pathogenic parasites, while perforin, released by natural killer cells or cytotoxic T lymphocytes (CTLs), targets virus-infected and transformed host cells (1). Remarkably, recent structural studies show that the MACPF domain is homologous to the pore-forming portion of bacterial cholesterol-dependent cytolysins; these data have provided important insight into the mechanism of pore-forming MACPF proteins. In addition to their role in immunity, MACPF family members have been identified as animal venoms, factors required for pathogen migration across host cell membranes and factors that govern developmental processes such as embryonic patterning and neuronal guidance (2). While most MACPF proteins characterized to date either form pores or span lipid membranes, some do not (e.g. the C6 component of the MAC). A current challenge is thus to understand the role, pore forming or otherwise, of MACPF proteins in developmental biology. This review discusses structural and functional diversity of the mammalian MACPF proteins.

Expression in Saccharomyces cerevisiae of antigenically and enzymatically active recombinant glutamic acid decarboxylase.

Glutamic acid decarboxylase (GAD) is one of the major autoantigens found in insulin-dependent (Type 1) diabetes mellitus (IDDM). A novel hybrid form of GAD was created by fusing amino acids 1-101 of the human GAD67 protein to amino acids 96-585 of the human GAD65 protein. This hybrid GAD67/65 was expressed constitutively under the control of the phosphoglycerate kinase promoter (PGK1) in the yeast Saccharomyces cerevisiae. Enzymatically active GAD was prepared from yeast lysates by a one-step purification on an affinity column using GAD-1 antibody. The purified hybrid GAD67/65 was radiolabelled with iodine-125 and tested in an immunoprecipitation assay with IDDM sera. Results obtained using the recombinant yeast hybrid GAD67/65 were very similar to those obtained using 125I-labelled porcine GAD. Recombinant yeast hybrid GAD67/65 should have utility for diagnosis and presymptomatic detection of IDDM.

Molecular genetic analysis of the central hydrophobic domain of subunit 8 of yeast mitochondrial ATP synthase.

Subunit 8 (Y8) of yeast mitochondrial ATP synthase (mtATPase) is a hydrophobic component of the membrane Fo sector. Encoded by the mitochondrial aap1 gene, Y8 is a 48-amino-acid polypeptide having a central hydrophobic domain (CHD) spanning 19 residues. Site-directed mutagenesis was carried out on a nuclear code-equivalent gene encoding Y8, to introduce either adjacent charged amino acids (positive or negative) or proline residues into the CHD, or to alter the length of this domain by deletion or insertion of additional non-polar residues. We report a functional resilience of Y8 in tolerating the introduction of charged residues implanted within the CHD. Thus, expression of variants having adjacent positively charged amino acids (arginines) in Y8-deficient cells restored growth on the non-fermentable substrate ethanol, though in some cases this was impaired compared to that conferred by the parent Y8 construct. Introduction of adjacent negative charges (aspartate residues) was less well tolerated, but in all cases a measurable rate of cell growth on ethanol was retained. These results underscore the interpretation that it is not necessary for Y8 to maintain a transmembrane stem in its role as an integral component of functional mtATPase. Further, the impaired growth properties of cells expressing variants of Y8 having changes designed to perturb the structure (proline substitutions) and length (insertions or deletions) of the CHD lead us to conclude that the overall shape and dimensions of Y8 are important for its function in mtATPase.

Non-functional variants of yeast mitochondrial ATP synthase subunit 8 that assemble into the complex.

Subunit 8 (Y8) is a component of the proton channel of yeast (Saccharomyces cerevisiae) mitochondrial ATP synthase (mtATPase), whose function in the complex remains to be precisely defined. Y8 variants truncated at residue 46 (Lys47-->STP), or in which each of three conserved C-terminal amino acid residues (Arg37, Arg42 and Lys47) were substituted with isoleucine, have defects in assembly and function. The additional positive charge substitution (Gln29-->Lys) was introduced into each of the variants to determine whether functional compensation for these defects could be achieved. In the case of the (Lys47-->STP) variant, the additional positive charge restored the ability of cells to grow on non-fermentable substrate. By contrast, for the (Lys47-->Ile) variant the additional positive charge did not confer any improvement in cellular growth rate compared to that of cells expressing the Lys47-->Ile substitution alone. For the (Arg42-->Ile) and (Arg37-->Ile) variants, the presence of the Gln29-->Lys substitution failed to restore growth of host cells lacking endogenous subunit 8 on non-fermentable substrate. However, use of an in vitro assembly assay revealed that, unlike their respective parents (Arg42-->Ile or Arg37-->Ile), the (Gln29-->Lys Arg42-->Ile) and (Gln29-->Lys Arg37-->Ile) variants assemble into mtATPase. Thus we conclude that Arg42 and Arg37 have a role in mtATPase function, in addition to being required for assembly of Y8 into mtATPase.

Relationship of subunit 8 of yeast ATP synthase and the inner mitochondrial membrane. Subunit 8 variants containing multiple lysine residues in the central hydrophobic domain retain function.

A molecular genetic approach has been used to test the proposition that the central hydrophobic domain of yeast mitochondrial ATP synthase subunit 8 represents a transmembrane stem in contact with the lipid bilayer. The rationale for this approach is the general inability of membrane bilayers to accomodate unshielded charged residues of polypeptide chains. Non-polar residues at several positions within the central hydrophobic domain of subunit 8 were replaced with the positively charged amino acid lysine. This was done in an attempt to disrupt subunit 8 function, and thereby determine the boundaries of the putative transmembrane stem. Each subunit 8 variant was allotopically expressed in vivo as a mitochondrial import precursor encoded by a nuclear gene. It was found that all variants, which included proteins carrying two lysines at various positions in the hydrophobic domain, exhibited the ability to restore growth of subunit-8-deficient cells on the non-fermentable substrate ethanol. This indicated that the function of none of these subunit 8 variants was severely compromised. There was also no detectable change in the proteolipid characteristics of subunit 8, as defined by the chloroform/methanol solubility properties of variant proteins extracted from membranes following import into isolated mitochondria. These data suggest that subunit 8 is located in a hydrophobic niche in the mitochondrial ATP synthase, probably in contact with other protein subunits of the complex. We conclude that the function of subunit 8 does not necessarily require it to be integrated within the inner mitochondrial membrane, in contact with the lipid bilayer. Our findings also suggest that hydropathy plots, indicating hydrophobic domains within polypeptides, cannot reliably be interpreted as transmembrane helices in the absence of independent evidence.

Structure/function analysis of yeast mitochondrial ATP synthase subunit 8.

Subunit 8 of yeast mitochondrial ATP synthase is a small hydrophobic component of the membrane-associated F0 sector. Structure/function relations in subunit 8 were studied by focusing on three structural domains: a highly conserved NH2-terminal region, a central hydrophobic region (previously suggested to be a transmembrane stem), and a COOH-terminal region bearing a conserved array of three positively charged residues. A combined approach was used, which encompasses site-directed mutagenesis, in vitro import and assembly tests, and an in vivo allotopic expression system (using host cells unable to synthesise subunit 8 in mitochondria). The results indicate that the NH2-terminal region of subunit 8 is involved functionally in the F0 sector. As the central hydrophobic region can functionally tolerate the introduction of multiple, positively charged residues (which abolishes the proteolipid solubility characteristics of the entire subunit), the role of this hydrophobic region as a transmembrane stem is brought into question. Each of the three positively charged residues toward the COOH-terminus of subunit 8 is required for the efficient assembly of this subunit into the F0 sector. Removal of the more proximal charged residues Arg37 or Arg42 has a more severe impact on subunit 8 assembly than does removal of the most distal residue Lys47 in terms of both in vitro import and assembly as well as the ability of the subunit 8 variant to function in mitochondrial ATP synthase in vivo.

The C-terminal positively charged region of subunit 8 of yeast mitochondrial ATP synthase is required for efficient assembly of this subunit into the membrane F0 sector.

This paper deals with a truncated derivative of subunit 8 of yeast mitochondrial ATP synthase in which a conserved positively charged residue (Lys47) has been removed by site-directed mutagenesis together with the C-terminal residue (Leu48). This derivative has been expressed as a chimaeric precursor N9L/Y8-1(K47-STP) carrying an N-terminal cleavable leader sequence (N9L), fused by a short bridging sequence to the truncated subunit-8 passenger protein. Allotopic expression of N9L/Y8-1(K47-STP) in vivo in an aap1 mit- host yeast strain lacking endogenous subunit 8 leads to partial restoration of bioenergetic function in the transformant strain denoted T475. Import and assembly studies were carried out in vitro using target mitochondria from strain YGL-1 partially depleted in subunit 8; such controlled depletion has been previously shown to be required for the efficient assembly (monitored immunochemically) of full-length subunit 8 imported in vitro as the precursor N9L/Y8-1. It was found that N9L/Y8-1(K47-STP) synthesized in vitro was imported successfully into YGL-1 mitochondria, but no significant assembly of the truncated subunit 8 was observed in these or any other mitochondria tested. The bioenergetic defects in T475 mitochondria are ascribed to the impaired assembly of the subunit-8 variant in vivo, resulting from the truncation at Lys47. In consequence, T475 mitochondria behave as though partially depleted of subunit 8. This conclusion was supported by the ability of isolated T475 mitochondria to provide a vehicle for the efficient import and assembly of subunit 8 processed from full-length N9L/Y8-1. Two related aspects of import and assembly have been addressed as part of the analysis of truncated subunit 8. First, mitochondria from strain T2-1, an aap1 mit- mutant genetically reconstituted by allotopic expression of N9L/Y8-1, were also found to be effective in the in vitro assembly of subunit 8 derived from imported N9L/Y8-1. This suggests an intramitochondrial shortage of subunit 8 delivered by allotopic expression of N9L/Y8-1 in vivo, which may underlie the incomplete restoration of energy coupling in T2-1 mitochondria compared to those of wild-type yeast. Second, on allotopic expression of N9L/Y8-2 (containing subunit 8 directly fused to N9L) in the aap1 mit- host, a rescued transformant strain T10-1 was generated which displays bioenergetic defects superficially similar to those of T475. Processed subunit 8 clearly assembled into the ATP synthase of isolated YGL-1 mitochondria, in spite of the relatively weak import of N9L/Y8-2 in vitro.(ABSTRACT TRUNCATED AT 400 WORDS)

Aberrant mitochondrial processing of chimaeric import precursors containing subunits 8 and 9 of yeast mitochondrial ATP synthase.

A set of chimaeric precursors which contain the same leader sequences but different passenger proteins has been analyzed for the site of protease cleavage following import into yeast mitochondria. Each precursor comprises the leader of Neurospora crassa subunit 9 of mitochondrial ATP synthase fused to subunit 8 or 9 of the corresponding yeast enzyme. Precursors containing the first five residues of mature N. crassa subunit 9 interposed between the leader and the yeast passenger protein were cleaved at the natural site of the N. crassa subunit 9 precursor. Direct fusions without interposed sequences were cleaved at novel sites. Cleavage occurred between the 3rd and 4th residues of yeast subunit 8, but for yeast subunit 9, cleavage occurred within the leader, 8 residues upstream of the passenger protein.

Import into mitochondria of precursors containing hydrophobic passenger proteins: pretreatment of precursors with urea inhibits import.

We have studied the import into isolated yeast mitochondria of three hydrophobic passenger proteins attached to the N-terminal cleavable presequence of mitochondrial ATPase subunit 9 from Neurospora crassa. One natural precursor (pN9) contained N. crassa subunit 9; two chimaeric precursors, N9L/Y8-1 and N9L/Y9-2, respectively contained yeast mitochondrial ATPase subunits 8 and 9. In the absence of urea, pN9 and N9L/Y8-1 are imported efficiently but N9L/Y9-2 is not imported. After pretreatment of precursors in 4 M urea, binding of pN9 to mitochondria is marginally affected while its import is substantially inhibited; the binding to mitochondria of chimaeric proteins, N9L/Y8-1 and N9L/Y9-2, is greatly enhanced but no import is observed. This behaviour of import precursors containing hydrophobic passenger proteins is contrasted with that of a hydrophilic chimaeric precursor pCOXIV-DHFR, whose binding and import are enhanced by pretreatment with a high concentration of urea (8 M). The import of N9L/Y8-1 is very sensitive to the presence of low concentrations of urea in the import reaction mixture, and is abolished above 0.5 M urea although precursor binding to mitochondria is increased. By contrast, neither the import nor binding of pCOXIV-DHFR is affected directly by urea up to 0.8 M. These deleterious effects of urea on import of the chimaeric precursors N9L/Y8-1 and N9L/Y9-2 are interpreted in terms of a non-productive binding of these precursors to mitochondria, brought about by exposure of their hydrophobic domains resulting from urea unfolding. The generalization that membrane translocation of mitochondrial import precursors is enhanced by their prior unfolding in urea thus does not apply in the case of these precursors containing hydrophobic passenger proteins.

Assembly of imported subunit 8 into the ATP synthase complex of isolated yeast mitochondria.

This study concerns the assembly into a multisubunit enzyme complex of a small hydrophobic protein imported into isolated mitochondria. Subunit 8 of yeast mitochondrial ATPase (normally a mitochondrial gene product) was expressed in vitro as a chimaeric precursor N9L/Y8-1, which includes an N-terminal-cleavable transit peptide to direct its import into mitochondria. Assembly into the enzyme complex of the imported subunit 8 was monitored by immunoadsorption using an immobilized anti-F1-beta monoclonal antibody. Preliminary experiments showed that N9L/Y8-1 imported into normal rho+ mitochondria, with its complement of fully assembled ATPase, did not lead to an appreciable assembly of the exogenous subunit 8. With the expectation that mitochondria previously depleted of subunit 8 could allow such assembly in vitro, target mitochondria were prepared from genetically modified yeast cells in which synthesis of subunit 8 was specifically blocked. Initially, mitochondria were prepared from strain M31, a mit- mutant completely incapable of intramitochondrial biosynthesis of subunit 8. These mit- mitochondria however were unsuitable for assembly studies because they could not import protein in vitro. A controlled depletion strategy was then evolved. An artificial nuclear gene encoding N9L/Y8-1 was brought under the control of a inducible promoter GAL1. This regulated gene construct, in a low copy number yeast expression vector, was introduced into strain M31 to generate strain YGL-1. Galactose control of the expression of N9L/Y8-1 was demonstrated by the ability of strain YGL-1 to grow vigorously on galactose as a carbon source, and by the inability to utilize ethanol alone for prolonged periods of growth. The measurement of bioenergetic parameters in mitochondria from YGL-1 cells experimentally depleted of subunit 8, by transferring growing cells from galactose to ethanol, was consistent with the presence in mitochondria of a mosaic of ATPase, namely fully assembled functional ATPase complexes and partially assembled complexes with defective F0 sectors. These mitochondria demonstrated very efficient import of N9L/Y8-1 and readily incorporated the imported processed subunit 8 protein into ATPase. Comparison of the kinetics of import and assembly of subunit 8 showed that assembly was noticeably delayed with respect to import. These findings open the way to a new systematic analysis of the assembly of imported proteins into multisubunit mitochondrial enzyme complexes.

Expression in yeast of antisense RNA to ADE1 mRNA.

The utility of antisense RNA as a means of regulating gene expression in yeast has been explored by inserting into a high copy number yeast expression vector an ADE1 gene fragment in such an orientation so as to produce antisense RNA in vivo which could hybridize to natural ADE1 mRNA. Northern blotting analysis of total cellular RNA extracted from transformed yeast cells confirmed the presence of high levels of antisense RNA to ADE1 mRNA within cells. However the high level of expression of antisense RNA did not result in production of Ade- cells.

Studies on the import into mitochondria of yeast ATP synthase subunits 8 and 9 encoded by artificial nuclear genes.

Direct fusions have been constructed between each of subunits 8 and 9 from mitochondrial ATPase of Saccharomyces cerevisiae, proteins normally encoded inside mitochondria, and the cleavable N-terminal transit peptide from the nuclearly encoded precursor to subunit 9 of Neurospora crassa mitochondrial ATPase. The subunit 8 construct was imported efficiently into isolated yeast mitochondria and was processed at or very near the fusion point. When expressed in vivo from its artificial nuclear gene, this cytoplasmically synthesized form of subunit 8 restored the growth defects of aap 1 mutants unable to produce subunit 8 inside the mitochondria. The subunit 9 construct was, however, unable to be imported into isolated mitochondria and could not, following nuclear expression in vivo, complement growth defects in mitochondrial oli 1 mutants. This behaviour is contrasted with the previously demonstrated import competence of another yeast subunit 9 fusion, bearing the first five residues of mature N. crassa subunit 9 interposed between its own transit peptide and the yeast subunit 9 moiety.

Physical aspects of the inhibition of enzymes by hydrocarbons: the inhibition of alpha-chymotrypsin by chlorinated aromatics and alkanes.

The inhibition of alpha-chymotrypsin by a series of chlorinated hydrocarbons, including polychlorinated biphenyls, has been studied. The solubility of the hydrocarbons was determined by autocorrelation analysis of light scattering. Kinetic analysis indicated that inhibition of the enzyme occurs when 1-2 molecules of inhibitor bind per molecule of enzyme. Chlorinated aromatics including polychlorinated biphenyls were more potent than monochloroalkanes in inhibition of the enzyme. Considerable inhibition was seen when some compounds were present as micelles. Molar volume correlations suggest that chlorinated hydrocarbons exert effects on soluble enzymes similar to their effects on membrane-bound enzymes, and that a membrane lipid phase is not essential for this type of inhibition.