Molecular cloning and amino acid sequence of human enkephalinase (neutral endopeptidase)

We have isolated a cDNA clone encoding human enkephalinase (neutral endopeptidase, EC 3.4.24.11) in a lambda gt10 library from human placenta, and present the complete 742 amino acid sequence of human enkephalinase. The human enzyme displays a high homology with rat and rabbit enkephalinase. Like the rat and rabbit enzyme, human enkephalinase contains a single N-terminal transmembrane region and is likely to be inserted through cell membranes with the majority of protein, including its carboxy-terminus, located extracellularly.     

Intact {alpha}-1,2-endomannosidase is a typical type II membrane protein

Rat endomannosidase is a glycosidic enzyme that catalyzes the cleavage of di-, tri-, or tetrasaccharides (Glc(1-3)Man), from N-glycosylation intermediates with terminal glucose residues. To date it is the only characterized member of this class of endomannosidic enzymes. Although this protein has been demonstrated to localize to the Golgi lumenal membrane, the mechanism by which this occurs has not yet been determined. Using the rat endomannosidase sequence, we identified three homologs, one each in the human, mouse, and rat genomes. Alignment of the four encoded protein sequences demonstrated that the newly identified sequences are highly conserved but differed significantly at the N-terminus from the previously reported protein. In this study we have cloned two novel endomannosidase sequences from rat and human cDNA libraries, but were unable to amplify the open reading frame of the previously reported rat sequence. Analysis of the rat genome confirmed that the 59- and 39-termini of the previously reported sequence were in fact located on different chromosomes. This, in combination with our inability to amplify the previously reported sequence, indicated that the N-terminus of the rat endomannosidase sequence previously published was likely in error (a cloning artifact), and that the sequences reported in the current study encode the intact proteins. Furthermore, unlike the previous sequence, the three ORFs identified in this study encode proteins containing a single N-terminal transmembrane domain. Here we demonstrate that this region is responsible for Golgi localization and in doing so confirm that endomannosidase is a type II membrane protein, like the majority of other secretory pathway glycosylation enzymes.     

Roles of homooligomerization and membrane association in ATPase and proteolytic activities of FtsH in vitro.

Escherichia coli FtsH is a membrane-bound and ATP-dependent protease which degrades some soluble and integral membrane proteins. The N-terminal region of FtsH mediates membrane association as well as homooligomeric interaction of this enzyme. Previously, we studied in vivo functionality of FtsH derivatives, in which the N-terminal membrane region was either deleted (FtsH(DeltaTM)), replaced by a leucine zipper (Zip-FtsH(DeltaTM)), or replaced by a lactose permease transmembrane segment (LacY-FtsH). It was indicated that homooligomerization is required for the minimum proteolytic activity, whereas a transmembrane sequence is required for membrane protein degradation. Here we characterized these proteins in vitro. Although these mutant enzymes were very low in their activities, they were significantly stimulated by dimethyl sulfoxide, which enabled us to characterize their activities. LacY-FtsH degraded both soluble and membrane proteins, but Zip-FtsH(DeltaTM) only degraded soluble proteins. These proteins also exhibited significant ATPase activities. However, FtsH(DeltaTM) remained inactive both in ATPase and in protease activities even in the presence of dimethyl sulfoxide. The monomeric FtsH(DeltaTM) was able to bind ATP and a denatured protein. These results indicate that subunit association is important for the enzymatic catalysis by FtsH and that the additional presence of the transmembrane sequence is required for this enzyme to degrade a membrane protein even under detergent-solubilized conditions.     

Human glutathione S-transferases. Characterization of the anionic forms from lung and placenta.

Anionic glutathione S-transferases were purified from human lung and placenta. Chemical and immunochemical characterization, including polyacrylamide-gel electrophoresis, gave strong evidence that the anionic lung and placental enzymes are chemically similar, if not identical, proteins. The electrophoretic mobilities of both proteins were identical in conventional alkaline gels as well as in gels containing sodium dodecyl sulphate. Gel filtration of the intact active enzyme established an Mr value of 45000; however, with sodium dodecyl sulphate/polyacrylamide-gel electrophoresis under dissociating conditions a subunit Mr of 22500 was obtained. Amino acid sequence analysis of the N-terminal region of the placental enzyme revealed a single polypeptide sequence identical with that of lung. Results obtained from immunoelectrophoresis, immunotitration, double immunodiffusion and rocket immunoelectrophoresis also indicated the anionic lung and placental enzymes to be closely similar. The chemical similarity of these two proteins was further supported by protein compositional analysis and fragment analysis after chemical hydrolysis. Immunochemical comparison of the anionic lung and placental enzymes with human liver glutathione S-transferases revealed cross-reactivity with the anionic omega enzyme, but no cross-reactivity was detectable with the cationic enzymes. Comparison of the N-terminal region of the human anionic enzyme with reported sequences of rat liver glutathione S-transferases gave strong evidence of chemical similarity, indicating that these enzymes are evolutionarily related. However, computer analysis of the 30-residue N-terminal sequence did not show any significant chemical similarity to any other reported protein sequence, pointing to the fact that the glutathione S-transferases represent a unique class of proteins.     

Molecular cloning and primary structure of rat testes metalloendopeptidase EC 3.4.24.15

The complete amino acid sequence of rat testes metalloendopeptidase (EC 3.4.24.15) was deduced from the nucleotide sequence of a cDNA clone isolated by screening a rat testes library with a polyclonal antibody raised against a homogeneous preparation of the rat testes enzyme. The correctness of the sequence was verified by N-terminal amino acid sequence analysis of the isolated enzyme and by partial amino acid sequence analysis of three tryptic peptides located near the N-terminus, the middle, and C-terminus of the native protein. The enzyme is composed of 645 amino acids with a molecular weight of 72,985. This value is close to that of the purified rat testes and brain enzyme as determined by polyacrylamide gel electrophoresis under denaturing and reducing conditions and by molecular sieving chromatography. The enzyme contains the putative active-site sequence -H-E-F-G-H- that is homologous to the sequence in the active site of thermolysin and several other related bacterial enzymes, as well as to active-site sequences of several mammalian zinc metallopeptidases. No amino acid sequence homology, beyond this active site, was found with thermolysin, a bacterial zinc metalloendopeptidase, nor with several mammalian zinc metallopeptidases. Northern blot hybridization analyses showed the presence of mRNA encoding the enzyme in rat testes, but not in other rat tissues in spite of the finding that enzyme activity is widely distributed in all tissues and that relatively high activities are present in rat brain and pituitary.     

Expression of enzymatically active enkephalinase (neutral endopeptidase) in mammalian cells

A cDNA encoding the rat enkephalinase protein (neutral endopeptidase; EC 3.4.24.11) has been constructed from overlapping lambda gt10 cDNA clones. This cDNA was inserted into an expression plasmid containing the cytomegalovirus enhancer and promoter. When transfected with this plasmid, Cos 7 cells transiently expressed the enkephalinase protein in a membrane-bound state. Recombinant enkephalinase recovered in solubilized extracts from transfected Cos 7 cells was enzymatically active and displayed properties similar to those of the native enzyme with respect to sensitivity to classical enkephalinase inhibitors.     

Arachidonate 15-lipoxygenase (omega-6 lipoxygenase) from human leukocytes. Purification and structural homology to other mammalian lipoxygenases

The enzyme responsible for 15-lipoxygenation of arachidonic acid was purified to homogeneity from human eosinophil-enriched leukocytes using a combination of ammonium sulfate precipitation, hydrophobic interaction chromatography, and high pressure liquid chromatography on hydroxyapatite and cation-exchange columns. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the purified protein revealed a single major band (apparent Mr 70,000). Amino acid sequence analysis yielded a single N-terminal sequence. Comparison of the N-terminal 15 residues reveals 71% sequence identity to the rabbit reticulocyte lipoxygenase and 36% sequence identity to the rat basophilic leukemia 5-lipoxygenase. In contrast, sequence identity to the soybean lipoxygenase-1 is not observed. These results demonstrate that human 15-lipoxygenase can be isolated from eosinophil-enriched leukocytes and is accessible for direct sequence analysis. Furthermore, we present initial evidence that the mammalian lipoxygenases constitute an homologous family of enzymes. The availability of homogeneous human 15-lipoxygenase will play a key role in elucidating other relationships in this family of enzymes.     

The transmembrane domain of N-glucosaminyltransferase I contains a Golgi retention signal.

The enzyme N-acetylglucosaminyltransferase I (NT, EC 2.4.1.101) is a resident type II transmembrane protein of the Golgi apparatus. To delineate the portion of its primary sequence that is responsible for the Golgi retention of this protein, we constructed chimeras containing different N-terminal portions of NT joined to a reporter sequence, the ectodomain of a type II surface membrane protein. These chimeric proteins were found to be retained in the Golgi apparatus as assessed by cell surface biotinylation and immunofluorescence. We found that the transmembrane domain of NT is sufficient to confer Golgi retention of the fusion proteins and propose that it contains the Golgi retention signal of the parent molecule.     

Tissue- and species-specific expression of cytochrome c oxidase isozymes in vertebrates

Cytochrome c oxidase was isolated from brown fat tissue of the rat and compared with the isozymes from rat liver and heart, which differ at least in subunits VIa and VIII. ELISA titrations of COX from the three tissues with monospecific antisera to all 13 subunits of the rat liver enzyme showed differences between the three enzymes. The N-terminal amino-acid sequence analysis of subunits VIa and VIII from SDS-PAGE gel bands of the three enzymes indicates the occurrence of three different isozymes in the rat. N-terminal amino-acid sequence analysis of subunits VIa and VIII from cytochrome c oxidase of bovine and human heart demonstrates also species-specific differences in the expression of the 'liver-type' and 'heart-type' of subunits VIa and VIII.     

Recombinant expression of N-terminal truncated mutants of the membrane bound mouse, rat and human flavoenzyme dihydroorotate dehydrogenase. A versatile tool to rate inhibitor effects?

Mammalian dihydroorotate dehydrogenase, the fourth enzyme of pyrimidine de novo synthesis is an integral protein of the inner mitochondrial membrane that faces the intermembrane space and is functionally connected to the respiratory chain via ubiquinone. Here, we describe the first cloning and analyzing of the complete cDNA of mouse dihydroorotate dehydrogenase. Based on our recent functional expression of the full-length rat and human dihydroorotate dehydrogenase, here we expressed N-terminal-truncated C-terminal-histidine-tagged constructs of the mouse, rat and human enzymes in Escherichia coli. These proteins were devoid of the N-terminal bipartite sequence consisting of the mitochondrial targeting sequence and adjacent hydrophobic domain necessary for import and proper location and fixation of the enzyme in the inner mitochondrial membrane. By employing metal-chelate affinity chromatography under native conditions, the enzymes were purified without detergents to a specific activity of more than 100 micromol x min(-1) x mg(-1) at pH optimum of 8.0--8.1. Flavin analyses by UV-visible spectrometry of the native enzymes gave fairly stoichiometric ratios of 0.6--1.2 mol flavin per mol protein. The kinetic constants of the truncated rat enzyme (K(m) = 11 microM dihydroorotate; K(m) = 7 microM ubiquinone) and human enzyme (K(m) = 10 microM dihydroorotate; K(m) = 14 microM ubiquinone) were very close to those recently reported for the full-size enzymes. The constants for the mouse enzyme, K(m) = 26 microM dihydroorotate and K(m) = 62 microM ubiquinone, were slightly elevated in comparison to those of the other species. The three truncated enzymes were tested for their efficacy with five inhibitors of topical clinical relevance against autoimmune disorders and tumors. Whereas the presence of the N-terminus of dihydroorotate dehydrogenase was essentially irrelevant for the efficacy of the malononitrilamides A77-1726, MNA715 and MNA279 with the rat and human enzyme, the N-termini were found to be important for the efficacy of the dianisidine derivative redoxal. Moreover, the complete N-terminal part of the human enzyme seemed to be of crucial importance for the 'slow-binding' features of the cinchoninic acid derivative brequinar, which was suggested to be one of the reasons for the narrow therapeutic window reported from clinical trials on its anti-proliferative and immunosuppressive action.     

The elusive third subunit IIa of the bacterial B-type oxidases: the enzyme from the hyperthermophile Aquifex aeolicus

The reduction of molecular oxygen to water is catalyzed by complicated membrane-bound metallo-enzymes containing variable numbers of subunits, called cytochrome c oxidases or quinol oxidases. We previously described the cytochrome c oxidase II from the hyperthermophilic bacterium Aquifex aeolicus as a ba(3)-type two-subunit (subunits I and II) enzyme and showed that it is included in a supercomplex involved in the sulfide-oxygen respiration pathway. It belongs to the B-family of the heme-copper oxidases, enzymes that are far less studied than the ones from family A. Here, we describe the presence in this enzyme of an additional transmembrane helix "subunit IIa", which is composed of 41 amino acid residues with a measured molecular mass of 5105 Da. Moreover, we show that subunit II, as expected, is in fact longer than the originally annotated protein (from the genome) and contains a transmembrane domain. Using Aquifex aeolicus genomic sequence analyses, N-terminal sequencing, peptide mass fingerprinting and mass spectrometry analysis on entire subunits, we conclude that the B-type enzyme from this bacterium is a three-subunit complex. It is composed of subunit I (encoded by coxA(2)) of 59000 Da, subunit II (encoded by coxB(2)) of 16700 Da and subunit IIa which contain 12, 1 and 1 transmembrane helices respectively. A structural model indicates that the structural organization of the complex strongly resembles that of the ba(3) cytochrome c oxidase from the bacterium Thermus thermophilus, the IIa helical subunit being structurally the lacking N-terminal transmembrane helix of subunit II present in the A-type oxidases. Analysis of the genomic context of genes encoding oxidases indicates that this third subunit is present in many of the bacterial oxidases from B-family, enzymes that have been described as two-subunit complexes.     

Rat ribophorin II: molecular cloning and chromosomal localization of a highly conserved transmembrane glycoprotein of the rough endoplasmic reticulum.

We report here the complete nucleotide sequence of rat ribophorin II. The predicted amino acid sequence is highly homologous to the corresponding human protein and consists of 631 amino acid residues, including a 22 amino acid N-terminal cleavable signal sequence, and a single 23 amino acid putative transmembrane domain. Northern blot analysis reveals a single -2.4 kb message expressed in a number of rat cell lines and in adult liver. The gene was mapped to mouse chromosome 2, close to the Src proto-oncogene.     

Inhibition of substance P degradation in rat brain preparations by peptide hydroxamic acids

A peptidase activity of rat diencephalon membranes, which acts on the C-terminal hexapeptide sequence of substance P, was characterized using the radiolabeled substrate N alpha-[( 125I]iododesaminotyrosyl)-substance P (6-11)-hexapeptide. This activity presents certain characteristics similar to those of the substance-P-degrading enzyme purified from human brain by Lee et al. [Eur. J. Biochem. 114, 315-327 (1981)]. It is inhibited by metal chelators and some thiol reagents, but is insensitive to inhibitors of serine proteases and aminopeptidases. The activity is different from angiotensin-converting enzyme and enkephalinase, since it is not affected by specific inhibitors of these enzymes. Substance P and substance P C-terminal fragments longer than the pentapeptide inhibited the degradation of the radiolabeled substrate with inhibition constants around 200 microM. Short fragments of the substance P sequence, such as Boc-Phe-Phe-OMe and Boc-Phe-Phe-Gly-OEt, were also found to inhibit the degradation of the substrate. When the metal-chelating hydroxamic acid moiety was attached to the carboxyl terminus of these short peptides, potent inhibitors of the substance-P-degrading activity were obtained, with inhibition constants in the micromolar range. The most potent of these compounds, iododesaminotyrosyl-Phe-Phe-Gly-NHOH (IBH-Phe-Phe-Gly-NHOH), is a competitive inhibitor, with a Ki value of 1.9 microM. The degradation of substance P by rat diencephalon slices was inhibited to the same extent (40-50%) by IBH-Phe-Phe-Gly-NHOH (20 microM) and by phosphoramidon (1 microM). A combination of both reagents reduced the degradation rate by 75-80%, suggesting that both enkephalinase and the substance-P-degrading activity are involved in the metabolism of substance P in this preparation. IBH-Phe-Phe-Gly-NHOH seems to be quite specific for the latter enzyme, since at a high concentration (0.1 mM) it did not affect the degradation of the radiolabeled substrate by alpha-chymotrypsin, papain, or thermolysin.     

In mouse alpha -methylacyl-CoA racemase, the same gene product is simultaneously located in mitochondria and peroxisomes

alpha-Methylacyl-CoA racemase, an enzyme of the bile acid biosynthesis and branched chain fatty acid degradation pathway, was studied at the protein, cDNA, and genomic levels in mouse liver. Immunoelectron microscopy and subcellular fractionation located racemase to mitochondria and peroxisomes. The enzymes were purified from both organelles with immunoaffinity chromatography. The isolated proteins were of the same size, with identical N-terminal amino acid sequences, and the existence of additional proteins with alpha-methylacyl-CoA racemase activity was excluded. A racemase gene of about 15 kilobases was isolated. Southern blot analysis and chromosomal localization showed that only one racemase gene is present, on chromosome 15, region 15B1. The putative initial ATG in the racemase gene was preceded by a functional promotor as shown with the luciferase reporter gene assay. The corresponding cDNAs were isolated from rat and mouse liver. The recombinant rat protein was overexpressed in active form in Pichia pastoris. The presented data suggest that the polypeptide encoded by the racemase gene can alternatively be targeted to peroxisomes or mitochondria without modifications. It is concluded that the noncleavable N-terminal sequence of the polypeptide acts as a weak mitochondrial and that the C-terminal sequence acts as a peroxisomal targeting signal.     

Role of aminopeptidases in enkephalin catabolism: comparative study of the regional distribution of aminopeptidases and enkephalinase A in the rat brain

In order to elucidate the role of aminopeptidases in enkephalin catabolism in rat brain, the local distribution of two types of cerebral cellular membrane aminopeptidases (puromycin-sensitive and puromycin-insensitive ones) and of the enkephalin system marker, enkephalinase A, was studied. It was found that the distribution patterns of the former enzymes differ essentially from that of enkephalinase A. Study of coupling between the enzymatic activities in different regions of rat brain revealed a strong correlation between the activities of puromycin-insensitive aminopeptidase and enkephalinase A in midbrain (including hypothalamus). It was supposed that in midbrain the role of aminopeptidase M in intrasynaptic inactivation of enkephalins is much more conspicuous than in other regions of rat brain. The puromycin-sensitive aminopeptidase activity does not seem to play a role in enkephalin catabolism.     

Enkephalinase: Selective inhibitors and partial characterization

There are at least two types of enzymes in brain, endopeptidases and aminopeptidases, which metabolize enkephalins. Evidence is presented to suggest that enkephalinase, an endopeptidase cleaving at the Gly-Phe bond, is specific for the endogenous enkephalinergic system. Selective inhibitors are described for each enzyme. These are parachloromercuriphenylsulfonic acid and puromycin in the case of aminopeptidases and various enkephalin fragments in the case of enkephalinase. Some characteristics of the two types of enzymes are described. Enkephalinase has many properties in common with the well-characterized brain angiotensin-converting enzyme. These two enzymes, however, behaved differently when tested for chloride dependance, for activity in several buffers and for susceptibility to specific inhibitors.     

Immunoaffinity purification, partial sequence, and subcellular localization of rat liver phospholipase A2

Monoclonal antibodies against rat liver mitochondrial phospholipase A2 were used to develop a rapid immunoaffinity chromatography for enzyme purification. The purified enzyme showed a single band upon sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The sequence of the N-terminal 24 amino acids was determined. This part of the sequence showed only 25% homology with that of rat pancreatic phospholipase A2 but was 96% identical to that of rat platelet and rat spleen membrane-associated phospholipase A2. These enzymes are distinguished from pancreatic phospholipases A2 by the absence of Cys-11. In rat liver phospholipase A2 activity has been reported in various subcellular fractions. All of these require Ca2+ and have a pH optimum in the alkaline region, but little is known about the structural relationship and quantitative distribution of these enzymes. We have investigated these points after solubilization of the phospholipase A2 activity from total homogenates and crude subcellular fractions by extraction with 1 M potassium chloride. Essentially all of the homogenate activity could be solubilized by this procedure indicating that the enzymes occurred in soluble or peripherally membrane-associated form. Gel filtration and immunological cross-reactivity studies indicated that phospholipases A2 solubilized from membrane fractions shared a common epitope with the mitochondrial enzyme. The quantitative distribution of the immunopurified enzyme activity among subcellular fractions followed closely that of the mitochondrial marker cytochrome c oxidase. Rat liver cytosol contained additional Ca2+-dependent and -independent phospholipase activities.     

Molecular cloning and sequencing of cDNA encoding the phosphatidylinositol kinase from rat brain.

A complementary DNA (cDNA) clone that encodes phosphatidylinositol 4-kinase (PI 4-kinase) was isolated from a rat brain cDNA library. The deduced amino acid sequence of 697 residues revealed that the protein contains two putative transmembrane sequences and that the N-terminal part of the protein has several sequences representing potential phosphorylation sites for cAMP- and calmodulin-dependent kinase. The C-terminal region is probably a phosphotransferase domain homologous to the kinase region of protein kinase family proteins. Specific antibody against the protein expressed in Escherichia coli successfully immunoprecipitated rat brain PI 4-kinase. The messenger RNA for PI 4-kinase was found predominantly in brain and rat neural cell lines. This PI kinase may play a specific role in neural signal transduction.     

Molecular cloning and nucleotide sequence of the beta-lytic protease gene from Achromobacter lyticus.

Two bacteriolytic enzymes secreted by Achromobacter lyticus M497-1 were purified and identified as being very similar (considering their amino acid composition and N-terminal sequence) to alpha- and beta-lytic proteases from Lysobacter enzymogenes. A 1.8-kb EcoRI fragment containing the structural gene for beta-lytic protease was cloned from A. lyticus chromosomal DNA. The protein sequence deduced from the nucleotide sequence was identical to the known sequence of beta-lytic protease, except for six residues. The nucleotide sequence revealed that the mature enzyme is composed of 179 amino acid residues with an additional 195 amino acids at the amino-terminal end of the enzyme, which includes the signal peptide, thus indicating that the enzyme is synthesized as a precursor protein.