Sequence features of substrates required for cleavage by GlpG, an Escherichia coli rhomboid protease

Rhomboids are a family of serine proteases belonging to intramembrane cleaving proteases, which are supposed to catalyse proteolysis of a substrate protein within the membrane. It remains unclear whether substrates of the rhomboid proteases have a common sequence feature that allows specific cleavage by rhomboids. We showed previously that GlpG, the Escherichia coli rhomboid, can cleave a type I model membrane protein Bla-LY2-MBP having the second transmembrane region of lactose permease (LY2) at the extramembrane region in vivo and in vitro, and that determinants for proteolysis reside within the LY2 sequence. Here we characterized sequence features in LY2 that allow efficient cleavage by GlpG and identified two elements, a hydrophilic region encompassing the cleavage site and helix-destabilizing residues in the downstream hydrophobic region. Importance of the positioning of helix-destabilizers relative to the cleavage site was suggested. These two elements appear to co-operatively promote proteolysis of substrates by GlpG. Finally, random mutagenesis of the cleavage site residues in combination with in vivo screening revealed that GlpG prefers residues with a small side chain and a negative charge at the P1 and P1' sites respectively.     

The role of L1 loop in the mechanism of rhomboid intramembrane protease GlpG

Intramembrane proteases are important enzymes in biology. The recently solved crystal structures of rhomboid protease GlpG have provided useful insights into the mechanism of these membrane proteins. Besides revealing an internal water-filled cavity that harbored the Ser-His catalytic dyad, the crystal structure identified a novel structural domain (L1 loop) that lies on the side of the transmembrane helices. Here, using site-directed mutagenesis, we confirmed that the L1 loop is partially embedded in the membrane, and showed that alanine substitution of a highly preferred tryptophan (Trp136) at the distal tip of the L1 loop near the lipid:water interface reduced GlpG proteolytic activity. Crystallographic analysis showed that W136A mutation did not modify the structure of the protease. Instead, the polarity for a small and lipid-exposed protein surface at the site of the mutation has changed. The crystal structure, now refined at 1.7 Å resolution, also clearly defined a 20-Å-wide hydrophobic belt around the protease, which likely corresponded to the thickness of the compressed membrane bilayer around the protein. This improved structural model predicts that all critical elements of the catalysis, including the catalytic serine and the L5 cap, need to be positioned within a few angstroms of the membrane surface, and may explain why the protease activity is sensitive to changes in the protein:lipid interaction. Based on these findings, we propose a model where the end of the substrate transmembrane helix first partitions out of the hydrophobic core region of the membrane before it bends into the protease active site for cleavage.     

Proteolytic action of GlpG, a rhomboid protease in the Escherichia coli cytoplasmic membrane

We characterized Escherichia coli GlpG as a membrane-embedded protease and a possible player in the regulated intramembrane proteolysis in this organism. From the sequence features, it belongs to the widely conserved rhomboid family of membrane proteases. We verified the expected topology of GlpG, and it traverses the membrane six times. A model protein having an N-terminal and periplasmically localized beta-lactamase (Bla) domain, a LacY-derived transmembrane region, and a cytosolic maltose binding protein (MBP) mature domain was found to be GlpG-dependently cleaved in vivo. This proteolytic reaction was reproduced in vitro using purified GlpG and purified model substrate protein, and the cleavage was shown to occur between Ser and Asp in a region of high local hydrophilicity, which might be located in a juxtamembrane rather than an intramembrane position. The conserved Ser and His residues of GlpG were essential for the proteolytic activities. Our results using several variant forms of the model protein suggest that GlpG recognizes features of the transmembrane regions of substrates. These results point to a detailed molecular mechanism and cellular analysis of this interesting class of membrane-embedded proteases.     

Environment of the active site region of RseP, an Escherichia coli regulated intramembrane proteolysis protease, assessed by site-directed cysteine alkylation

Regulated intramembrane proteolysis (RIP) plays crucial roles in both prokaryotic and eukaryotic organisms. Proteases for RIP cleave transmembrane regions of substrate membrane proteins. However, the molecular mechanisms for the proteolysis of membrane-embedded transmembrane sequences are largely unknown. Here we studied the environment surrounding the active site region of RseP, an Escherichia coli S2P ortholog involved in the sigma(E) pathway of extracytoplasmic stress responses. RseP has two presumed active site motifs, HEXXH and LDG, located in membrane-cytoplasm boundary regions. We examined the reactivity of cysteine residues introduced within or in the vicinity of these two active site motifs with membrane-impermeable thiol-alkylating reagents under various conditions. The active site positions were inaccessible to the reagents in the native state, but many of them became partially modifiable in the presence of a chaotrope, while requiring simultaneous addition of a chaotrope and a detergent for full modification. These results suggest that the active site of RseP is not totally embedded in the lipid phase but located within a proteinaceous structure that is partially exposed to the aqueous milieu.     

Structure of the E. coli bifunctional GlmU acetyltransferase active site with substrates and products

The biosynthesis of UDP-GlcNAc in bacteria is carried out by GlmU, an essential bifunctional uridyltransferase that catalyzes the CoA-dependent acetylation of GlcN-1-PO(4) to form GlcNAc-1-PO(4) and its subsequent condensation with UTP to form pyrophosphate and UDP-GlcNAc. As a metabolite, UDP-GlcNAc is situated at a branch point leading to the biosynthesis of lipopolysaccharide and peptidoglycan. Consequently, GlmU is regarded as an important target for potential antibacterial agents. The crystal structure of the Escherichia coli GlmU acetyltransferase active site has been determined in complexes with acetyl-CoA, CoA/GlcN-1-PO(4), and desulpho-CoA/GlcNAc-1-PO(4). These structures reveal the enzyme groups responsible for binding the substrates. A superposition of these complex structures suggests that the 2-amino group of GlcN-1-PO(4) is positioned in proximity to the acetyl-CoA to facilitate direct attack on its thioester by a ternary complex mechanism.     

Substrate recognition and binding by RseP, an Escherichia coli intramembrane protease

Escherichia coli RseP belongs to the S2P family of intramembrane cleaving proteases. RseP catalyzes proteolytic cleavage of the membrane-bound anti-sigma(E) protein RseA as an essential step in transmembrane signal transduction in the sigma(E) extracytoplasmic stress response pathway. RseP cleaves transmembrane segments of membrane proteins, but the molecular mechanisms of its substrate recognition and proteolytic action remain largely unknown. Here we analyzed interaction between RseP and substrate membrane proteins. Co-immunoprecipitation assays showed that helix-destabilizing residues in a substrate transmembrane segment, which were previously shown to be required for efficient proteolysis of the substrate by RseP, stabilize the substrate-RseP interaction. Substitutions of certain amino acid residues, including those evolutionarily conserved, in the third transmembrane region (TM3) of RseP weakened the RseP-substrate interaction. Specific combinations of Cys substitutions in RseP TM3 and in the RseA transmembrane segment led to the formation of disulfide bonds upon oxidation, suggesting that TM3 of RseP directly binds the substrate. These results provide insights into the mechanism of membrane protein proteolysis by RseP.     

Functional characterization of Escherichia coli GlpG and additional rhomboid proteins using an aarA mutant of Providencia stuartii

The Providencia stuartii AarA protein is a member of the rhomboid family of intramembrane serine proteases and required for the production of an extracellular signaling molecule that regulates cellular functions including peptidoglycan acetylation, methionine transport, and cysteine biosynthesis. Additional aarA-dependent phenotypes include (i) loss of an extracellular yellow pigment, (ii) inability to grow on MacConkey agar, and (iii) abnormal cell division. Since these phenotypes are easily assayed, the P. stuartii aarA mutant serves as a useful host system to investigate rhomboid function. The Escherichia coli GlpG protein was shown to be functionally similar to AarA and rescued the above aarA-dependent phenotypes in P. stuartii. GlpG proteins containing single alanine substitutions at the highly conserved catalytic triad of asparagine (N154A), serine (S201A), or histidine (H254A) residues were nonfunctional. The P. stuartii aarA mutant was also used as a biosensor to demonstrate that proteins from a variety of diverse sources exhibited rhomboid activity. In an effort to further investigate the role of a rhomboid protein in cell physiology, a glpG mutant of E. coli was constructed. In phenotype microarray experiments, the glpG mutant exhibited a slight increase in resistance to the beta-lactam antibiotic cefotaxime.     

Rapid purification of active gamma-secretase, an intramembrane protease implicated in Alzheimer's disease

γ-Secretase is an unconventional aspartyl protease that processes many type 1 membrane proteins within the lipid bilayer. Because its cleavage of amyloid-β precursor protein generates the amyloid-β protein (Aβ) of Alzheimer's disease, partially inhibiting γ-secretase is an attractive therapeutic strategy, but the structure of the protease remains poorly understood. We recently used electron microscopy and single particle image analysis on the purified enzyme to generate the first 3D reconstruction of γ-secretase, but at low resolution (15 Å). The limited amount of purified γ-secretase that can be produced using currently available cell lines and procedures has prevented the achievement of a high resolution crystal structure by X-ray crystallography or 2D crystallization. We report here the generation and characterization of a new mammalian cell line (S-20) that overexpresses strikingly high levels of all four γ-secretase components (presenilin, nicastrin, Aph-1 and Pen-2). We then used these cells to develop a rapid protocol for the high-grade purification of proteolytically active γ-secretase. The cells and purification methods detailed here provide a key step towards crystallographic studies of this ubiquitous enzyme.     

Mapping the active site of meprin-A with peptide substrates and inhibitors

The extended substrate-binding site of meprin-A, a tetrameric metalloendopeptidase from brush border membranes of mouse kidney proximal tubules, was mapped with a series of peptide substrates. Previous studies led to the development of the chromogenic substrate Phe5(4-nitro)bradykinin for meprin-A. With this substrate, several biologically active peptides were screened as alternate substrate inhibitors, and, of these, bradykinin (RPPGFSPFR) was found to be the best substrate with a single cleavage site (Phe5-Ser6). Three types of bradykinin analogues were used for a systematic investigation of substrate specificity: (1) nonchromogenic bradykinin analogues with substitutions in the P3 to P3' subsites were used as alternative substrate inhibitors of nitrobradykinin hydrolysis, (2) analogues of nitrobradykinin with variations in the P1' position were tested as substrates, and (3) intramolecularly quenched fluorogenic bradykinin analogues with substitutions in the P1 to P3 sites were tested as substrates. A wide variety of substitutions in P1' had little effect on KM (174-339 microM) but markedly affected kcat (51.5 s-1 = A greater than S greater than R greater than F greater than K greater than T greater than E = 0). Substitutions in P1 had a greater effect on KM (366 microM-2.46 mM) and also strongly affected kcat (98.5 s-1 = A greater than F much greater than L greater than E greater than K = 2.4 s-1). The variety of allowed cleavages indicates that meprin-A does not have strict requirements for residues adjacent to the cleavage site. Substitutions farther from the scissle bond also affected binding and hydrolysis, demonstrating that multiple subsite interactions are involved in meprin-A action.(ABSTRACT TRUNCATED AT 250 WORDS)     

The peptide bond between E292-A293 of Escherichia coli leucyl-tRNA synthetase is essential for its activity.

Escherichia coli leucyl-tRNA synthetase (LeuRS) is a class I aminoacyl-tRNA synthetase that contains a large connecting polypeptide (CP1) inserted into its nucleotide binding fold, or active site. In this study, purified leucyl-tRNA synthetase was found to be cleaved between E292 and A293 in its CP1 domain. SDS-PAGE analysis showed peptides of 63 and 34 kDa in addition to the native 97.3 kDa synthetase. By internal complementation, the two peptides could form a 97.3 kDa complex similar to the native LeuRS. This complex could support the ATP approximately PP(i) exchange activity of LeuRS, but could not complement for aminoacylation. To study the function of the region around the bond of E292 and A293, four pairs of peptides resulting from different cleavage sites in CP1 were reconstituted in vivo. With the exception of the enzyme assembled from the E292-A293 cleavage site, all the reassembled LeuRSs catalyzed the aminoacylation of tRNA(Leu). Although the E292-A293-cleaved LeuRS could not catalyze aminoacylation, fluorescence titration revealed that its tRNA binding ability was almost identical to that of wild-type LeuRS. These results suggest that the region around E292-A293 may be responsible for maintaining the proper conformation of LeuRS required for the tRNA charging activity.     

Proteolysis of an active site peptide of lactate dehydrogenase by human immunodeficiency virus type 1 protease.

The muscle and heart lactate dehydrogenase (LDHs) of rabbit and pig are specifically cleaved at a single position by HIV-1 protease, resulting in the conversion of 36-kDa subunits of the oligomeric enzymes into 21- and 15-kDa protein bands as analyzed by SDS-PAGE. While the proteolysis was observed at neutral pH, it became more pronounced at pH 6.0 and 5.0. The time courses of the cleavage of the 36-kDa subunits were commensurate with the time-dependent loss of both quaternary structure and enzymatic activity. These results demonstrated that deoligomerization of rabbit muscle LDH at acidic pH rendered its subunits more susceptible to proteolysis, suggesting that a partially denatured form of the enzyme was the actual substrate. Proteolytic cleavage of the rabbit muscle enzyme occurred at a decapeptide sequence, His-Gly-Trp-Ile-Leu*Gly-Glu-His-Gly-Asp (scissile bond denoted throughout by an asterisk), which constitutes a "strand-loop" element in the muscle and heart LDH structures and contains the active site histidyl residue His-193. The kinetic parameters Km, Vmax/KmEt, and Vmax/Et for rabbit muscle LDH and the synthetic decapeptide Ac-His-Gly-Trp-Ile-Leu*Gly-Glu-His-Gly-Asp-NH2 were nearly identical, suggesting that the decapeptide within the protein substrate is conformationally mobile, as would be expected for the peptide substrate in solution. Insertion of part of this decapeptide sequence into bacterial galactokinase likewise rendered this protein susceptible to proteolysis by HIV-1 protease, and site-directed mutagenesis of this peptide in galactokinase revealed that the Glu residue at the P2' was important to binding to HIV-1 protease. Crystallographic analysis of HIV-1 protease complexed with a tight-binding peptide analogue inhibitor derived from this decapeptide sequence revealed that the "strand-loop" structure of the protein substrate must adopt a beta-sheet structure upon binding to the protease. The Glu residue in the P2' position of the inhibitor likely forms hydrogen-bonding interactions with both the alpha-amide and gamma-carboxylic groups of Asp-30 in the substrate binding site.     

The purification of protease IV of E.coli and the demonstration that it is an endoproteolytic enzyme

A strong proteolytic activity is unmasked and solubilized when $\text{E. coli}$ outer membrane fragments are preincubated with 0.083% sodium dodecyl sulfate. This proteolytic activity cleaves αS1 casein into the same degradation products as protease IV, a recently described protease of $\text{E.coli}$ located in the outer membrane (Ph. Régnier, preceding paper), it is concluded that sodium dodecyl sulfate solubilizes the same protease. Protease IV has been purified 11,200 fold, probably to homogenetiy, by sodium dodecyl sulfate polyacrylamide gel electrophoresis followed by elution of the protein from gel slices. The purified enzyme is fully active, its molecular weight, determined from its migration in denaturating gels is 23,500. αS1 casein is cleaved by protease IV into two large polypeptides which are not further degraded and some small peptides of about 5,000 daltons. The production of discrete polypeptide species suggests that protease IV is an endoproteolytic enzyme.     

E. coli propionyl-CoA synthetase is regulated in vitro by an intramolecular disulfide bond

The E. coli propionyl-CoA synthetase (PCS) was cloned, expressed, purified, and analyzed. Kinetic analyses suggested that the enzyme preferred propionate as substrate but would also use acetate. The purified, stored protein had relatively low activity but was activated up to about 10-fold by incubation with dithiothreitol (DTT). The enzyme activation by DTT was reversed by diamide. This suggests that the protein contains a regulatory disulfide bond and that the reduction to two sulfhydryl groups activates PCS while the oxidation to a disulfide leads to its inactivation. This idea was tested by sequential mutagenesis of the 9 Cys in the protein to Ala. It was revealed that the C128A and C315A mutants had wildtype enzyme activity but were no longer activated by DTT or inhibited by diamide. The data obtained indicate that two Cys residues could be involved in redox-regulated system through formation of an intramolecular disulfide bridge in PCS.     

E. coli propionyl-CoA synthetase is regulated in vitro by an intramolecular disulfide bond

The E. coli propionyl-CoA synthetase (PCS) was cloned, expressed, purified, and analyzed. Kinetic analyses suggested that the enzyme preferred propionate as substrate but would also use acetate. The purified, stored protein had relatively low activity but was activated up to about 10-fold by incubation with dithiothreitol (DTT). The enzyme activation by DTT was reversed by diamide. This suggests that the protein contains a regulatory disulfide bond and that the reduction to two sulfhydryl groups activates PCS while the oxidation to a disulfide leads to its inactivation. This idea was tested by sequential mutagenesis of the 9 Cys in the protein to Ala. It was revealed that the C128A and C315A mutants had wildtype enzyme activity but were no longer activated by DTT or inhibited by diamide. The data obtained indicate that two Cys residues could be involved in redox-regulated system through formation of an intramolecular disulfide bridge in PCS.     

Structure of peptide from active site region of Escherichia coli L-asparaginase.

The L-asparagine analogue 5-diazo-4-oxo-L-[5-14C]norvaline binds irreversibly to the active site of Escherichia coli L-asparaginase. Conditions for optimal labeling in buffers containing 50% dimethylsulfoxide have been developed and kinetic parameters of the inactivation have been determined. After reduction, alkylation and subsequent degradation of the modified enzyme with alpha-chymotrypsin, the principal radioactive decapeptide of sequence Val-Gly-Ala-Met-Arg-Pro-Ser-Thr-Ser-Met was isolated. A second radioactive hexapeptide Arg-Pro-Ser-Thr-Ser-Met resulting from chymotryptic digestion of the decapeptide was also isolated. Evidence is presented for the attachment of the 5-diazo-4-oxo-L-norvaline residue to serine-9 in the decapeptide via an acid-labile linkage.     

The active site of the Escherichia coli glycogen synthase is similar to the active site of retaining GT-B glycosyltransferases

Bacterial glycogen synthases transfer a glucosyl unit, retaining the anomeric configuration, from ADP-glucose to the non-reducing end of glycogen. We modeled the Escherichia coli glycogen synthase based on three glycosyltransferases with a GT-B fold. Comparison between the model and the structure of the active site of crystallized retaining GT-B glycosyltransferases identified conserved residues with the same topology. To confirm the importance of these residues predicted by the model, we studied them in E. coli glycogen synthase by site-directed mutagenesis. Mutations D137A, R300A, K305A, and H161A decreased the specific activity 8100-, 2600-, 1200-, and 710-fold, respectively. None of these mutations increased the Km for glycogen and only H161A and R300A had a higher Km for ADP-Glc of 11- and 8-fold, respectively. These residues were essential, validating the model that shows a strong similarity between the active site of E. coli glycogen synthase and the other retaining GT-B glycosyltransferases known to date.     

Trypsin-specific acyl-4-guanidinophenyl esters for alpha-chymotrypsin-catalysed reactions computational predictions, hydrolyses, and peptide bond formation.

The function of acyl-4-guanidinophenyl esters as substrate mimetics for the serine protease alpha-chymotrypsin was investigated by protein-ligand docking, hydrolysis, and acyl transfer experiments. On the basis of protein-ligand docking studies, the binding and hydrolysis properties of these artificial substrates were estimated. The predictions of the rational approach were confirmed by steady-state hydrolysis studies on 4-guanidinophenyl esters derived from coded amino acids (which alpha-chymotrypsin is not specific for), noncoded amino acids, and even simple carboxylic acid moieties. Enzymatic peptide syntheses qualify these esters as suitable acyl donors for the coupling of acyl components far from the natural enzyme specificity, thus considerably expanding the synthetic utility of alpha-chymotrypsin.     

Binding of puromycin to E. coli ribosomes. Effects of puromycin analogues and peptide bond formation inhibitors

³H-puromycin binds to bacterial ribosomes, in the presence of ethanol, under the experimental conditions of the fragment reaction assay. The binding is feeble, takes place at 0°C, is partially inhibited by chloramphenicol and lincomycin and totally by sparsomycin. ³H-puromycin binding is hardly affected by the 3 aminonucleoside of puromycin, is well inhibited by the L-Phenylalanine and L-Leucine analogues of puromycin and totally blocked by L-Phenylalanyl-adenosine.     

The active site of the ribosome is composed of two layers of conserved nucleotides with distinct roles in peptide bond formation and peptide release

Peptide bond formation and peptide release are catalyzed in the active site of the large subunit of the ribosome where universally conserved nucleotides surround the CCA ends of the peptidyl- and aminoacyl-tRNA substrates. Here, we describe the use of an affinity-tagging system for the purification of mutant ribosomes and analysis of four universally conserved nucleotides in the innermost layer of the active site: A2451, U2506, U2585, and A2602. While pre-steady-state kinetic analysis of the peptidyl transferase activity of the mutant ribosomes reveals substantially reduced rates of peptide bond formation using the minimal substrate puromycin, their rates of peptide bond formation are unaffected when the substrates are intact aminoacyl-tRNAs. These mutant ribosomes do, however, display substantial defects in peptide release. These results reveal a view of the catalytic center in which an inner shell of conserved nucleotides is pivotal for peptide release, while an outer shell is responsible for promoting peptide bond formation.