Mechanism of human S-adenosylmethionine decarboxylase proenzyme processing as revealed by the structure of the S68A mutant

S-Adenosylmethionine decarboxylase (AdoMetDC) is a pyruvoyl-dependent enzyme that catalyzes the formation of the aminopropyl group donor in the biosynthesis of the polyamines spermidine and spermine. The enzyme is synthesized as a protein precursor and is activated by an autocatalytic serinolysis reaction that creates the pyruvoyl group. The autoprocessing reaction proceeds via an N --> O acyl rearrangement, generating first an oxyoxazolidine anion intermediate followed by an ester intermediate. A similar strategy is utilized in self-catalyzed protein splicing reactions and in autoproteolytic activation of protein precursors. Mutation of Ser68 to alanine in human AdoMetDC prevents processing by removing the serine side chain necessary for nucleophilic attack at the adjacent carbonyl carbon atom. We have determined the X-ray structure of the S68A mutant and have constructed models of the proenzyme and the oxyoxazolidine intermediate. Formation of the oxyoxazolidine intermediate is promoted by a hydrogen bond from Cys82 and stabilized by a hydrogen bond from Ser229. These observations are consistent with mutagenesis studies, which show that the C82S and C82A mutants process slowly and that the S229A mutant does not process at all. Donation of a proton by His243 to the nitrogen atom of the oxyoxazolidine ring converts the oxyoxazolidine anion to the ester intermediate. The absence of a base to activate the hydroxyl group of Ser68 suggests that strain may play a role in the cleavage reaction. Comparison of AdoMetDC with other self-processing proteins shows no common structural features. Comparison to histidine decarboxylase and aspartate decarboxylase shows that these pyruvoyl-dependent enzymes evolved different catalytic strategies for forming the same cofactor.     

Roles of cysteine proteases Cwp84 and Cwp13 in biogenesis of the cell wall of Clostridium difficile

Clostridium difficile expresses a number of cell wall proteins, including the abundant high-molecular-weight and low-molecular-weight S-layer proteins (SLPs). These proteins are generated by posttranslational cleavage of the precursor SlpA by the cysteine protease Cwp84. We compared the phenotypes of C. difficile strains containing insertional mutations in either cwp84 or its paralog cwp13 and complemented with plasmids expressing wild-type or mutant forms of their genes. We show that the presence of uncleaved SlpA in the cell wall of the cwp84 mutant results in aberrant retention of other cell wall proteins at the cell surface, as demonstrated by secretion of the proteins Cwp66 and Cwp2 into the growth medium. These phenotypes are restored by complementation with a plasmid expressing wild-type Cwp84 enzyme but not with one encoding a Cys116Ala substitution in the active site. The cwp13 mutant cleaved the SlpA precursor normally and had a wild-type-like colony phenotype. Both Cwp84 and Cwp13 are produced as proenzymes which are processed by cleavage to produce mature enzymes. In the case of Cwp84, this cleavage does not appear to be autocatalytic, whereas in Cwp13 autocatalysis was demonstrated as a Cys109Ala mutant did not undergo processing. Cwp13 appears to have a role in processing of Cwp84 but is not essential for Cwp84 activity. Cwp13 cleaves SlpA in the HMW SLP domain, which we suggest may reflect a role in cleavage and degradation of misfolded proteins at the cell surface.     

Biosynthesis and secretion of pullulanase, a lipoprotein from Klebsiella aerogenes

We constructed, by site-directed mutagenesis, a mutant pullulanase gene in which the cysteine residue in a pentapeptide sequence, Leu16-Leu-Ser-Gly-Cys20 within the NH2-terminal region of pullulanase from Klebsiella aerogenes, is replaced by serine (Ser20). The modification, processing, and subcellular localization of the mutant pullulanase were studied. Labeling studies with [3H]palmitate and immunoprecipitation with mouse antiserum raised against pullulanase showed that the wild form of both the extracellular and intracellular pullulanases contained lipids, whereas the mutant enzyme was not modified with lipids. Only the Cys20 was modified with glyceryl lipids. The bulk of the mutant pullulanase was located in the periplasm, but a portion of the unmodified, mutant pullulanase was secreted into the medium. Mutant pullulanases from the extracellular and the periplasm were purified and their NH2-terminal sequences were determined. Both the mutant pullulanases were cleaved between residues of Ser13 and Leu14 which is 6-amino acid residues upstream of the lipid modified pullulanase cleavage site. This new cleavage was resistant to globomycin, an inhibitor of the prolipoprotein signal peptidase of Escherichia coli. These results indicate that the pentapeptide sequence plays an important role in maturation and translocation of pullulanase in K. aerogenes. However, the modification of pullulanase with lipids seems to be not essential for export of the enzyme across the outer membrane.     

Identification of a calcium-dependent microsomal proteinase responsible for monobasic cleavage of chicken proalbumin

The location and nature of the endoproteolytic activity involved in processing of proproteins has been studied in chicken liver microsomes. A membrane-bound, calcium-dependent proteinase was found to cleave chicken proalbumin with a monobasic cleavage site approx. 10-times faster than human proalbumin, which has a dibasic cleavage site. The mutant (human) proalbumin Christchurch (Arg(-1)----Gln), with a potential monobasic site, was not processed. The enzyme, which had a pH optimum of between 5.0 and 7.0, was not inhibited by serine or aspartyl proteinase inhibitors but was affected by some inhibitors of cysteine proteinases. The convertase was specifically inhibited by the reactive centre variant alpha 1-antitrypsin Pittsburgh, but not by normal alpha 1-antitrypsin.     

Lipoprotein nature of the colicin A lysis protein: effect of amino acid substitutions at the site of modification and processing.

The colicin A lysis protein (Cal) is required for the release of colicin A to the medium by producing bacteria. This protein is produced in a precursor form that contains a cysteine at the cleavage site (-Leu-Ala-Ala-Cys). The precursor must be modified by the addition of lipid before it can be processed. The maturation is prevented by globomycin, an inhibitor of signal peptidase II. Using oligonucleotide-directed mutagenesis, the alanine and cystein residues in the -1 and +1 positions of the cleavage site were replaced by proline and threonine residues, respectively, in two different constructs. Both substitutions prevented the normal modification and cleavage of the protein. The marked activation of the outer membrane detergent-resistant phospholipase A observed with wild-type Cal was not observed with the Cal mutants. Both Cal mutants were also defective for the secretion of colicin A. In one mutant, the signal peptide appeared to be cleaved off by an alternative pathway involving signal peptidase I. Electron microscope studies with immunogold labeling of colicin A on cryosections of pldA and cal mutant cells indicated that the colicin remains in the cytoplasm and is not transferred to the periplasmic space. These results demonstrate that Cal must be modified and processed to activate the detergent-resistant phospholipase A and to promote release of colicin A.     

Cloning and functional expression of Dfurin2, a subtilisin-like proprotein processing enzyme of Drosophila melanogaster with multiple repeats of a cysteine motif.

Production of a variety of regulatory eukaryotic proteins, such as growth factors and polypeptide hormones, often involves endoproteolytic processing of proproteins at cleavage sites consisting of paired basic residues. The first known mammalian proprotein processing enzyme with such specificity is the human fur gene product furin. Structurally and functionally, furin is related to the subtilisin-like serine endoprotease kexin (EC 3.4.21.61) of yeast Saccharomyces cerevisiae; unlike kexin, it contains a cysteine-rich region with an unknown function. Here, we describe cloning and sequencing of a 5.8-kbp cDNA of the Dfur2 gene, a fur-like gene of Drosophila melanogaster, which we found expressed during various stages of development. This Dfur2 cDNA has an open reading frame for a 1680-residue protein, called Dfurin2. Dfurin2 contains similar protein domains as mammalian furin, however, it has an extended amino-terminal region and its cysteine-rich region is much larger than that of mammalian furin. Because of this latter phenomenon, we were able to identify a particular cysteine motif that was repeated multiple times in Dfurin2 but present only twice in mammalian furin. Furthermore, we show that Dfur2 encodes an endoproteolytic enzyme with specificity for paired basic amino acid residues as, in cotransfection experiments, correct cleavage was demonstrated of the precursor of the von Willebrand factor but not of a cleavage mutant. Finally, Dfur2 was mapped to region 14C of the X chromosome of D. melanogaster.     

Functional requirements for the lysosomal thiol reductase GILT in MHC class II-restricted antigen processing

Ag processing and presentation via MHC class II is essential for activation of CD4(+) T lymphocytes. gamma-IFN-inducible lysosomal thiol reductase (GILT) is present in the MHC class II loading compartment and has been shown to facilitate class II Ag processing and recall responses to Ags containing disulfide bonds such as hen egg lysozyme (HEL). Reduction of proteins within the MHC class II loading compartment is hypothesized to expose residues for class II binding and protease trimming. In vitro analysis has shown that the active site of GILT involves Cys(46) and Cys(49), present in a CXXC motif that shares similarity with the thioredoxin family. To define the functional requirements for GILT in MHC class II Ag processing, a GILT-deficient murine B cell lymphoma line was generated and stably transduced with wild-type and cysteine mutants of GILT. Intracellular flow cytometric, immunoblotting, and immunofluorescence analyses demonstrated that wild-type and mutant GILT were expressed and maintained lysosomal localization. Transduction with wild-type GILT reconstituted MHC class II processing of a GILT-dependent HEL epitope. Mutation of either Cys(46) or Cys(49) abrogated MHC class II processing of a GILT-dependent HEL epitope. In addition, biochemical analysis of these mutants suggested that the active site facilitates processing of precursor GILT to the mature form. Precursor forms of GILT-bearing mutations in Cys(200) or Cys(211), previously found to display thiol reductase activity in vitro, could not mediate Ag processing. These studies demonstrate that the thiol reductase activity of GILT is its essential function in MHC class II-restricted Ag processing.     

Site-directed alteration of serine 82 causes nonproductive chain cleavage in prohistidine decarboxylase

Prohistidine decarboxylase from Lactobacillus 30a normally autoactivates by cleavage of the Ser-81-Ser-82 peptide bond, converting Ser-82 to a pyruvoyl moiety which serves as the enzymatic cofactor. We have used site-directed methods to make two conservative mutations, converting Ser-82 to cysteine (S82C) and threonine (S82T). Both mutant proteins autoactivate, although dramatically (20- to 80-fold), more slowly than wild type. Roughly 55% of the mutant protein in each case undergoes a nonproductive chain cleavage which does not result in cofactor production. This finding suggests that an important feature in the enzyme's evolution has been development of an activation scheme which minimizes nonproductive side reactions. Catalytic constants are also affected by the mutations, particularly kcat which drops 8-fold in S82C and 450-fold in S82T. In addition, the S82T protein activates to produce a novel alpha-ketobutyroyl cofactor.     

Structure of a slow processing precursor penicillin acylase from Escherichia coli reveals the linker peptide blocking the active-site cleft

Penicillin G acylase is a periplasmic protein, cytoplasmically expressed as a precursor polypeptide comprising a signal sequence, the A and B chains of the mature enzyme (209 and 557 residues respectively) joined by a spacer peptide of 54 amino acid residues. The wild-type AB heterodimer is produced by proteolytic removal of this spacer in the periplasm. The first step in processing is believed to be autocatalytic hydrolysis of the peptide bond between the C-terminal residue of the spacer and the active-site serine residue at the N terminus of the B chain. We have determined the crystal structure of a slowly processing precursor mutant (Thr263Gly) of penicillin G acylase from Escherichia coli, which reveals that the spacer peptide blocks the entrance to the active-site cleft consistent with an autocatalytic mechanism of maturation. In this mutant precursor there is, however, an unexpected cleavage at a site four residues from the active-site serine residue. Analyses of the stereochemistry of the 260-261 bond seen to be cleaved in this precursor structure and of the 263-264 peptide bond have suggested factors that may govern the autocatalytic mechanism.     

Effect of amino acid substitutions at the signal peptide cleavage site of the Escherichia coli major outer membrane lipoprotein

The requirement for the glycine residue at the COOH terminus of the signal peptide of the precursor of the major Escherichia coli outer membrane lipoprotein was examined. Using oligonucleotide-directed site-specific mutagenesis, this residue was replaced by residues of increasing side chain size. Substitution by serine had no effect on the modification or processing of the prolipoprotein. Substitution by valine or leucine resulted in the accumulation of the unmodified precursor, whereas threonine substitution resulted in slow lipid modification and no detectable processing of the lipid modified precursor. The results indicate that serine is the upper limit on size for the residue at the cleavage site. Larger residues at this position prevent the action of both the glyceride transferase and signal peptidase II enzymes, indicating that the cleavage site residue plays a role in events prior to proteolytic cleavage. The upper limit on size of the cleavage site residue is similar to that found for exported proteins cleaved by signal peptidase I, as well as eucaryotic exported proteins. The possibility that the cleavage site residue may have a role other than active site recognition by the signal peptidase is discussed.     

Amide bonds to the nitrogen atoms of cysteine and serine as "weak points" in the backbones of proteins

During the initial event in protein self-splicing, a peptide bond to the nitrogen atom of an internal cysteine or serine residue is usually cleaved by the side chain -SH or -OH group to yield a thioester or oxyester intermediate that undergoes further reactions. Self-splicing reactions also accompany the maturation of hedgehog signaling proteins, plant-type asparaginases, and pyruvoyl enzymes. It would be of interest to know whether peptide bonds that involve the nitrogen atoms of cysteine or serine are more susceptible to cleavage than peptide bonds to amino acids that lack reactive side chains. Extrapolations of the results of model reactions conducted at elevated temperatures indicate that the -SH group of N-acetylcysteine enhances the rate of its hydrolysis by a factor of 70, while the OH group of N-acetylserine enhances the rate of its hydrolysis 12-fold, compared with the rate of hydrolysis of N-acetylalanine in neutral solution at 25 °C. Several lines of evidence suggest that the rate-enhancing effects of these -SH and -OH side chains arise from their ability to act as intramolecular general acid-base catalysts for hydrolysis, rather than as nucleophilic catalysts. The protein environment within self-splicing proteins appears to redirect the actions of these side chains to nucleophilic attack, generating rate enhancements that approach the rate enhancements generated by conventional enzymes.     

Role of cysteine residues in Pseudomonas mevalonii 3-hydroxy-3-methylglutaryl-CoA reductase. Site-directed mutagenesis and characterization of the mutant enzymes

Each of the four identical subunits of Pseudomonas mevalonii 3-hydroxy-3-methylglutaryl (HMG)-CoA reductase contains two cysteine residues, Cys156 and Cys296 (Beach, M. J., and Rodwell, V. W. (1989) J. Bacteriol. 171, 2994-3001). Both are accessible to modification by sulfhydryl reagents under nondenaturing conditions (Jordan-Starck, T. C., and Rodwell, V. W. (1989) J. Biol. Chem. 264, 17913-17918). We used site-directed mutagenesis to construct three mutant enzymes in which alanine replaced either or both cysteine residues. Mutant enzymes C156A, C296A, and C156/296A were over-expressed in Escherichia coli and were found to be fully active. Following their purification, all four forms of the enzyme were compared with respect to their catalytic efficiency, their affinities for the substrates of all four catalyzed reactions, and for their sensitivity to inactivation by sulfhydryl reagents. Replacement of cysteine residues with alanine residues had no major effect on either the specific activity or the affinity of the enzymes for any substrate. The mutants catalyzed all four HMG-CoA reductase reactions as efficiently as did the wild-type enzyme, and coenzyme A stimulated mevaldehyde reduction to the same extent as for wild-type HMG-CoA reductase. Mutant C156A and the cysteine-free mutant C156/296A were not inactivated by 5,5'-dithiobis(2-nitrobenzoate). By contrast, mutant C296A was inactivated to the same extent as was the wild-type enzyme. Following treatment of the mutant enzymes with N-ethylmaleimide, the four reductase reactions catalyzed by mutant C296A were inactivated to the same extent as for the wild-type enzyme. Neither mutant C156A nor C156/296A was affected by this reagent. We conclude that the sulfhydryl reagent-reactive group whose derivatization leads to loss of enzymatic activity is Cys156. However, this residue is not an essential active site residue since neither substrate binding nor catalysis was affected when it was replaced by alanine. Possible roles of cysteine in maintaining structural stability are discussed.     

The MUC1 SEA module is a self-cleaving domain

MUC1, a glycoprotein overexpressed by a variety of human adenocarcinomas, is a type I transmembrane protein (MUC1/TM) that soon after its synthesis undergoes proteolytic cleavage in its extracellular domain. This cleavage generates two subunits, alpha and beta, that specifically recognize each other and bind together in a strong noncovalent interaction. Proteolysis occurs within the SEA module, a 120-amino acid domain that is highly conserved in a number of heavily glycosylated mucin-like proteins. Post-translational cleavage of the SEA module occurs at a site similar to that in MUC1 in the glycoproteins IgHepta and MUC3. However, as in the case of other proteins containing the cleaved SEA module, the mechanism of MUC1 proteolysis has not been elucidated. Alternative splicing generates two transmembrane MUC1 isoforms, designated MUC1/Y and MUC1/X. We demonstrated here that MUC1/X, whose extracellular domain is comprised solely of the SEA module in addition to 30 MUC1 N-terminal amino acids, undergoes proteolytic cleavage at the same site as the MUC1/TM protein. In contrast, the MUC1/Y isoform, composed of an N-terminally truncated SEA module, is not cleaved. Cysteine or threonine mutations of the MUC1/X serine residue (Ser-63) immediately C-terminal to the cleavage site generated cleaved proteins, whereas mutation of the Ser-63 residue of MUC1/X to any other of 17 amino acids did not result in cleavage. In vitro incubation of highly purified precursor MUC1/X protein resulted in self-cleavage. Furthermore, addition of hydroxylamine, a strong nucleophile, markedly enhanced cleavage. Both these features are signature characteristics of self-cleaving proteins, and we concluded that MUC1 undergoes autoproteolysis mediated by an N --> O-acyl rearrangement at the cleavage site followed by hydrolytic resolution of the unstable ester and concomitant cleavage. It is likely that all cleaved SEA module-containing proteins follow a similar route.     

Molecular cloning and characterization of a cDNA encoding asparaginyl endopeptidase from sweet potato (Ipomoea batatas (L.) Lam) senescent leaves

Asparaginyl endopeptidase is a cysteine endopeptidase that has strict substrate specificity toward the carboxyl side of asparagine residues, and is possibly involved in the post-translational processing of proproteins. In this report one full-length cDNA, SPAE, was isolated from senescent leaves of sweet potato (Ipomoea batatas (L.) Lam). SPAE contained 1479 nucleotides (492 amino acids) in the open reading frame, and exhibited high amino acid sequence homologies (c. 61-68%) with asparaginyl endopeptidases of Vicia sativa, Phaseolus vulgaris, Canavalia ensiformis, and Vigna mungo. SPAE probably encoded a putative precursor protein. Via cleavage of the N- and C-termini, it produced a mature protein containing 325 amino acids (from the 51st to the 375th amino acid residues), the conserved catalytic residues (the 173rd His and 215th Cys amino acid residues), and the putative N-glycosylation site (the 332nd Asn amino acid residue). Semi-quantitative RT-PCR and western blot hybridization showed that SPAE gene expression was enhanced significantly in natural senescent leaves and in dark- and ethephon-induced senescent leaves, but was much less in mature green leaves, stems, and roots. Phylogenic analysis showed that SPAE displayed close association with vacuolar processing enzymes (legumains/asparaginyl endopeptidases), which function via cleavage for proprotein maturation in the protein bodies during seed maturation and germination. In conclusion, sweet potato SPAE is probably a functional, senescence-associated gene and its mRNA and protein levels were significantly enhanced in natural and induced senescent leaves. The possible role and function of SPAE associated with bulk protein degradation and mobilization during leaf senescence were also discussed.     

Molecular characterization of a vacuolar processing enzyme related to a putative cysteine proteinase of Schistosoma mansoni.

Proproteins of various vacuolar proteins are post-translationally processed into mature forms by the action of a unique vacuolar processing enzyme. If such a processing enzyme is transported to vacuoles together with proprotein substrates, the enzyme must be a latent form. Immunocytochemical localization of a vacuolar processing enzyme, a 37-kD cysteine proteinase, in the endosperm of maturing castor bean seeds places the enzyme in the vacuolar matrix, where a variety of proproteins is also present. To characterize a molecular structure of vacuolar processing enzyme, we isolated a cDNA for the enzyme. Deduced primary structure of a 55-kD precursor is 33% identical to a putative cysteine proteinase of the human parasite Schistosoma mansoni. The precursor is composed of a signal peptide, a 37-kD active processing enzyme domain, and a propeptide fragment. Although the precursor expressed in Escherichia coli has no vacuolar processing activity, a 36-kD immunopositive protein expressed in E. coli is active. These results suggest that the activation of the vacuolar processing enzyme requires proteolytic cleavage of a 14-kD C-terminal propeptide fragment of the precursor.     

A microsomal endopeptidase from liver with substrate specificity for processing proproteins such as the vitamin K-dependent proteins of plasma.

The microsomal fraction of rabbit liver contains an endopeptidase that cleaves synthetic peptides that mimic the amino acid sequences of the processing sites of many proproteins, including the vitamin K-dependent proteins. The endopeptidase (M(r) 69,000) was extracted from liver microsomes with 1% Lubrol and purified about 2,700-fold. The substrate employed for isolation and characterization of the enzyme was the decapeptide acetyl-Ala-Arg-Val-Arg-Arg-Ala-Asn-Ser-Phe-Leu (prothrombin peptide), in which hydrolysis occurred on the carboxyl side of the paired Arg-Arg residues. The purified enzyme, whose activity was enhanced 1.8-fold by 0.1 mM CoCl2, has a Km = 80 microM and Vmax = 21,000 nmol.min-1.mg-1 and a pH optimum of 8.7. Proteolytic cleavage of decapeptide substrates was dependent on an arginine residue at positions P1 and P4. The enzyme was completely inhibited by EDTA and 1,10-phenanthroline as well as by p-chloromercuriphenylsulfonic acid and Hg2+. Inhibitors of serine proteases and cysteine proteases had no effect. Based on the substrate preference, the endopeptidase appears to be a good candidate for the enzyme responsible for the precursor processing of the vitamin K-dependent proteins and a number of other proproteins that are synthesized via the secretory pathway in liver and other tissues.     

Structural determinant for cold inactivation of rodent L-xylulose reductase

L-Xylulose reductase (XR) is a homotetramer belonging to the short-chain dehydrogenase/reductase family. Human XR is stable at low temperature, whereas the enzymes of mouse, rat, guinea pig, and hamster are rapidly dissociated into their inactive dimeric forms. In order to identify amino acid residues that cause cold inactivation of the rodent XRs, we have here selected Asp238, Leu242, and Thr244 in the C-terminal regions of rodent XRs and performed site-directed mutagenesis of the residues of mouse XR to the corresponding residues (Glu, Trp, and Cys) of the human enzyme. Cold inactivation was prevented partially by the single mutation of L242W and the double mutation of L242W/T244C, and completely by the double mutation of D238E/L242W. The L242W and L242W/T244C mutants existed in both tetrameric and dimeric forms at low temperature and the D238E/L242W mutant retained its tetrameric structure. No preventive effect was exerted by the mutations of D238E and T244C, which were dissociated into their dimeric forms upon cooling. Crystallographic analysis of human XR revealed that Glu238 and Trp242 contribute to proper orientation of the guanidino group of Arg203 of the same subunit to the C-terminal carboxylate group of Cys244 of another subunit through the neighboring residues, Gln137 and Phe241. Thus, the determinants for cold inactivation of rodent XRs are Asp238 and Leu242 with small side chains, which weaken the salt bridges between Arg203 and the C-terminal carboxylate group, and lead to cold inactivation.     

3-hydroxy-3-methylglutaryl coenzyme A reductase is sterol-dependently cleaved by cathepsin L-type cysteine protease in the isolated endoplasmic reticulum

We have recently shown that 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase, an endoplasmic reticulum (ER) membrane protein, is degraded in ER membranes prepared from sterol pretreated cells and that such degradation is catalyzed by a cysteine protease within the reductase membrane domain. The use of various protease inhibitors suggested that degradation of HMG-CoA reductase in vitro is catalyzed by a cathepsin L-type cysteine protease. Purified ER contains E-64-sensitive cathepsin L activity whose inhibitor sensitivity was well matched to that of HMG-CoA reductase degradation in vitro. CLIK-148 (cathepsin L inhibitor) inhibited degradation of HMG-CoA reductase in vitro. Purified cathepsin L also efficiently cleaved HMG-CoA reductase in isolated ER preparations. To determine whether a cathepsin L-type cysteine protease is involved in sterol-regulated degradation of HMG-CoA reductase in vivo, we examined the effect of E-64d, a membrane-permeable cysteine protease inhibitor, in living cells. While lactacystin, a proteasome-specific inhibitor, inhibited sterol-dependent degradation of HMG-CoA reductase, E-64d failed to do so. In contrast, degradation of HMG-CoA reductase in sonicated cells was inhibited by E-64d, CLIK-148, and leupeptin but not by lactacystin. Our results indicate that HMG-CoA reductase is degraded by the proteasome under normal conditions in living cells and that it is cleaved by cathepsin L leaked from lysosomes during preparation of the ER, thus clarifying the apparently paradoxical in vivo and in vitro results. Cathepsin L-dependent proteolysis was observed to occur preferentially in sterol-pretreated cells, suggesting that sterol treatment results in conformational changes in HMG-CoA reductase that make it more susceptible to such cleavage.     

Identification of the acyl transfer site of fatty acyl-protein synthetase from bioluminescent bacteria

Fatty acid activation, transfer, and reduction by the fatty acid reductase multienzyme complex from Photobacterium phosphoreum to generate fatty aldehydes for the luminescence reaction is regulated by the interaction of the synthetase and reductase subunits of this complex. Identification of the specific site involved in covalent transfer of the fatty acyl group between the sites of activation and reduction on the synthetase and reductase subunits, respectively, is a critical step in understanding how subunit interactions modulate the flow of fatty acyl groups through the fatty acid reductase complex. To accomplish this goal, the nucleotide sequence of the luxE gene coding for the acyl-protein synthetase subunit (373 amino acid residues) was determined and the conserved cysteinyl residues implicated in fatty acyl transfer identified. Using site-specific mutagenesis, each of the five conserved cysteine residues was converted to a serine residue, the mutated synthetases expressed in Escherichia coli, and the properties of the mutant proteins examined. On complementation of four of the mutants with the reductase subunit, the synthetase subunit was acylated and the acyl group could be reversibly transferred between the reductase and synthetase subunits, and fatty acid reductase activity was fully regenerated. As well, sensitivity of the acylated synthetases to hydroxylamine cleavage (under denaturation conditions to remove any conformational effects on reactivity) was retained, showing that a cysteine and not a serine residue was still acylated. However, substitution of a cysteine residue only ten amino acid residues from the carboxyl terminal (C364S) prevented acylation of the synthetase and regeneration of fatty acid reductase activity. Moreover, this mutant protein preserved its ability to activate fatty acid to fatty acyl-AMP but could not accept the acyl group from the reductase subunit, demonstrating that the C364S synthetase had retained its conformation and specifically lost the fatty acylation site. These results provide evidence that the flow of fatty acyl groups in the fatty acid reductase complex is modulated by interaction of the reductase subunit with a cysteine residue very close to the carboxyl terminal of the synthetase, which in turn acts as a flexible arm to transfer acyl groups between the sites of activation and reduction.     

Properties of the cysteine residues and the iron-sulfur cluster of the assimilatory 5'-adenylyl sulfate reductase from Enteromorpha intestinalis

The 5'-adenylyl sulfate (APS) reductase from the marine macrophytic green alga Enteromorpha intestinalis uses reduced glutathione as the electron donor for the reduction of APS to 5'-AMP and sulfite. The E. intestinalis enzyme (EiAPR) is composed of a reductase domain and a glutaredoxin-like C-terminal domain. The enzyme contains a single [4Fe-4S] cluster as its sole prosthetic group. Three of the enzyme's eight cysteine residues (Cys166, Cys257, and Cys260) serve as ligands to the iron-sulfur cluster. Site-directed mutagenesis experiments and resonance Raman spectroscopy are consistent with the presence of a cluster in which only three of the four ligands to the cluster irons contributed by the protein are cysteine residues. Site-directed mutagenesis experiments suggest that the thiol group of Cys250, a residue found only in algal APS reductases, is not an absolute requirement for activity. The other four cysteines that do not serve as cluster ligands, all of which are required for activity, are involved in the formation of two redox-active disulfide/dithiol couples. The couple involving Cys342 and Cys345 has an E(m) value at pH 7.0 of -140 mV, and the one involving Cys165 and Cys285 has an E(m) value at pH 7.0 of -290 mV. The C-terminal portion of EiAPR, expressed separately, exhibits the cystine reductase activity characteristic of glutaredoxins. It is proposed that the Cys342-Cys345 disulfide provides the site for entry of electrons from reduced glutathione and that the Cys166-Cys285 disulfide may serve as a structural element that is essential for keeping the enzyme in the catalytically active conformation.