The legumain McPAL1 from Momordica cochinchinensis is a highly stable Asx-specific splicing enzyme

Legumains, also known as asparaginyl endopeptidases (AEPs), cleave peptide bonds after Asn/Asp (Asx) residues. In plants, certain legumains also have ligase activity that catalyzes biosynthesis of Asx-containing cyclic peptides. An example is the biosynthesis of MCoTI-I/II, a squash family-derived cyclic trypsin inhibitor, which involves splicing to remove the N-terminal prodomain and then N-to-C-terminal cyclization of the mature domain. To identify plant legumains responsible for the maturation of these cyclic peptides, we have isolated and characterized a legumain involved in splicing, McPAL1, from Momordica cochinchinensis (Cucurbitaceae) seeds. Functional studies show that recombinantly expressed McPAL1 displays a pH-dependent, trimodal enzymatic profile. At pH 4 to 6, McPAL1 selectively catalyzed Asp-ligation and Asn-cleavage, but at pH 6.5 to 8, Asn-ligation predominated. With peptide substrates containing N-terminal Asn and C-terminal Asp, such as is found in precursors of MCoTI-I/II, McPAL1 mediates proteolysis at the Asn site and then ligation at the Asp site at pH 5 to 6. Also, McPAL1 is an unusually stable legumain that is tolerant of heat and high pH. Together, our results support that McPAL1 is a splicing legumain at acidic pH that can mediate biosynthesis of MCoTI-I/II. We purport that the high thermal and pH stability of McPAL1 could have applications for protein engineering.     

Legumains and their functions in plants

Legumains are a family of plant and animal Asn-specific cysteine proteinases with extra-cytoplasmic localization in vacuoles or cell walls. Plant legumains are involved in Asn-specific propolypeptide processing during, for example, storage-protein deposition in maturing seeds, when these proteins are resistant against degradation by legumains. With the transition to germination and subsequent seedling growth, storage proteins are opened to unlimited cleavage by legumains, which now contribute to protein mobilization. Here, we suggest a hypothesis that unifies both functions of legumains. Their action as propolypeptide-processing or protein-degrading enzymes is naturally controlled by the conformational state of their substrates, which undergo development- or environment-dependent changes. The suggested substrate conformation-dependent differential roles of legumains might not be restricted to seeds but could also apply to cells of different tissues in vegetative organs.     

A VPE family supporting various vacuolar functions in plants

Vacuolar processing enzyme (VPE) is a cysteine protease that has substrate specificity toward Asn and Asp residues, and found in various eukaryotic organisms including higher plants and mammals. Plant VPEs are separated into three subfamilies: seed-type, vegetative-type and uncharacterized-type. VPE was originally identified as a protease responsible for the maturation of seed storage proteins, and recent research has shown that it is a key protease responsible for the maturation of various vacuolar proteins not only in maturating cotyledons, but also in vegetative tissues. Thus, the VPE-mediated processing system is important for various vacuolar functions in the plant. Vegetative-type VPEs are expressed during senescence or pathogen-induced hypersensitive response. A VPE-deficiency abolished programmed cell death during hypersensitive response in tobacco leaves after TMV infection. This suggests that vegetative-type VPEs are involved in vacuolar-organized programmed cell death.     

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.     

An internal signal sequence directs intramembrane proteolysis of a cellular immunoglobulin domain protein

Precursor proteolysis is a crucial mechanism for regulating protein structure and function. Signal peptidase (SP) is an enzyme with a well defined role in cleaving N-terminal signal sequences but no demonstrated function in the proteolysis of cellular precursor proteins. We provide evidence that SP mediates intraprotein cleavage of IgSF1, a large cellular Ig domain protein that is processed into two separate Ig domain proteins. In addition, our results suggest the involvement of signal peptide peptidase (SPP), an intramembrane protease, which acts on substrates that have been previously cleaved by SP. We show that IgSF1 is processed through sequential proteolysis by SP and SPP. Cleavage is directed by an internal signal sequence and generates two separate Ig domain proteins from a polytopic precursor. Our findings suggest that SP and SPP function are not restricted to N-terminal signal sequence cleavage but also contribute to the processing of cellular transmembrane proteins.     

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.     

Processing enzyme specificity is a consequence of pro-hormone precursor protein conformation.

Peptide-hormones are synthesized as higher molecular weight, precursor proteins which must initially undergo limited endoproteolysis to yield the bioactive peptide(s). The ability of two different endoproteinases, gonadotropin-associated peptide (GAP)-releasing enzyme and atrial granule serine proteinase (which are likely to be the physiologically relevant processing enzymes of bovine hypothalamic pro-gonadotropin-releasing hormone/gonadotropin-associated peptide and bovine pro-atrial natriuretic factor precursor proteins, respectively), to act at their own recognition sequences within their relevant pro-hormone proteins has now been contrasted with their ability to act at the recognition sequence for the alternate enzyme or to act at their own recognition sequence when it is placed within the protein framework of the alternate precursor protein. The results show that each enzyme acts with specificity at its own recognition sequence even when it is placed within the framework of the alternate pro-hormone. However, the enzymes fail to act (or act in a non-specific manner) at the alternate recognition sequence even if it is placed within the peptide framework of its own pro-hormone protein. Thus, despite the fact that both recognition sequences are similar in sequence and residue composition and that both contain a doublet of basic amino acids, it appears that sequence and the local conformation assumed by the processing site within the pro-hormone protein are essential for each endoproteinase to act with fidelity. As part of our continuing work, we now also report several newly determined physicochemical properties of hypothalamic GAP-releasing enzyme, the processing enzyme of pro-gonadotropin-releasing hormone/GAP protein.     

Conformational analysis and proteolytic processing of synthetic pre-pro-GnRH/GAP protein

Homogeneous pre-pro-GnRH/GAP protein was recently synthesized in 100 mg quantities by solid-phase methods and surprisingly, the synthetic pre-pro-protein, which normally does not escape the endoplasmic recticulum, was found to inhibit the release of prolactin from cultured pituitary cells. This is the first demonstration of significant biological activity associated with a precursor protein and provides the rationale for its further study. We now report the results of our initial examination of the conformational properties of pre-pro-GnRH/GAP protein as a prelude to solving its solution phase conformation by homonuclear¹H-NMR protocols. Thermal andpH titration fluorescence and circular dichroism spectroscopies reveal that the protein is resistant to thermal-induced conformational changes but is particularly sensitive topH-induced conformational changes; while Asp/Glu and Arg residues may contribute to structural stability, His and Lys residues predominate. Pre-pro-GnRH/GAP is about 30% helix in the range of 2–40°C; however, even at 90°C, the peptide retains nearly 50% of its helix character. There is no evidence for a cooperative transition; for this reason, differential scanning calorimetry failed to yield a defined transition thermogram. Pre-pro-GnRH/GAP apparently does not pass through a transition state as a function of temperature but appears to flex and retain a high percentage of helix structure, resulting in subtle changes in secondary structure. There is no discernible isodichroic point. On either side of the neutralpH range, however, there are dramatic changes in structure that result in nonreversible denaturation of the protein. Relative to N(Ac)Trp-amide, the emission position of intrinsic Trp fluorescence of pre-pro-GnRH/GAP is blue shifted to 338 nm, indicating that the microenvironment(s) encompassing the 2 Trp residues are buried within the protein structure. Synthetic pre-pro-GNRH/GAP is a substrate for GAP-releasing enzyme (the proposed physiologically relevant processing enzyme of the precursor protein) and yields GAP peptide (D14–I69). Of the other serine proteinases tested (trypsin, plasmin, kallikrein), only GAP-releasing enzyme shows this specificity of cleavage. Hierarchical cleavage observed in the time course of proteolysis with trypsin, however, suggests that other peptide products might be formed from GAP once it is processed from the precursor protein by cleavage at sites other than the primary processing site catalyzed by enzymes other than GAP-releasing enzyme. The primary processing site for GAP-releasing enzyme (GLRPGGKR) is thus accessible in the precursor protein, consistent with our hypothesis that the recognition sequence is located at the surface of the protein and acts as a recognition element for the processing endoproteinase. The conformation of the precursor protein is dynamic, supporting the idea that intracellular (and/or intragranular) conditions may play a role in regulation of endoproteolysis. Conformational flexing of the pro-hormone in response to intracellular conditions may serve to differentially expose various processing sites which may help explain tissue specificity of processing.     

Limited proteolysis of ribonuclease A with thermolysin in trifluoroethanol.

We have examined the proteolysis of bovine pancreatic ribonuclease A (RNase) by thermolysin when dissolved in aqueous buffer, pH 7.0, in the presence of 50% (v/v) trifluoroethanol (TFE). Under these solvent conditions, RNase acquires a conformational state characterized by an enhanced content of secondary structure (helix) and reduced tertiary structure, as given by CD measurements. It was found that the TFE-resistant thermolysin, despite its broad substrate specificity, selectively cleaves the 124-residue chain of RNase in its TFE state (20-42 degrees C, 6-24 h) at peptide bond Asn 34-Leu 35, followed by a slower cleavage at peptide bond Thr 45-Phe 46. In the absence of TFE, native RNase is resistant to proteolysis by thermolysin. Two nicked RNase species, resulting from cleavages at one or two peptide bonds and thus constituted by two (1-34 and 35-124) (RNase Th1) or three (1-34, 35-45 and 46-124) (RNase Th2) fragments linked covalently by the four disulfide bonds of the protein, were isolated to homogeneity by chromatography and characterized. CD measurements provided evidence that RNase Th1 maintains the overall conformational features of the native protein, but shows a reduced thermal stability with respect to that of the intact species (-delta Tm 16 degrees C); RNase Th2 instead is fully unfolded at room temperature. That the structure of RNase Th1 is closely similar to that of the intact protein was confirmed unambiguously by two-dimensional NMR measurements. Structural differences between the two protein species are located only at the level of the chain segment 30-41, i.e., at residues nearby the cleaved Asn 34-Leu 35 peptide bond. RNase Th1 retained about 20% of the catalytic activity of the native enzyme, whereas RNase Th2 was inactive. The 31-39 segment of the polypeptide chain in native RNase forms an exposed and highly flexible loop, whereas the 41-48 region forms a beta-strand secondary structure containing active site residues. Thus, the conformational, stability, and functional properties of nicked RNase Th1 and Th2 are in line with the concept that proteins appear to tolerate extensive structural variations only at their flexible or loose parts exposed to solvent. We discuss the conformational features of RNase in its TFE-state that likely dictate the selective proteolysis phenomenon by thermolysin.     

Crystal structures of penicillin acylase enzyme-substrate complexes: structural insights into the catalytic mechanism

The crystal structure of penicillin G acylase from Escherichia coli has been determined to a resolution of 1.3 A from a crystal form grown in the presence of ethylene glycol. To study aspects of the substrate specificity and catalytic mechanism of this key biotechnological enzyme, mutants were made to generate inactive protein useful for producing enzyme-substrate complexes. Owing to the intimate association of enzyme activity and precursor processing in this protein family (the Ntn hydrolases), most attempts to alter active-site residues lead to processing defects. Mutation of the invariant residue Arg B263 results in the accumulation of a protein precursor form. However, the mutation of Asn B241, a residue implicated in stabilisation of the tetrahedral intermediate during catalysis, inactivates the enzyme but does not prevent autocatalytic processing or the ability to bind substrates. The crystal structure of the Asn B241 Ala oxyanion hole mutant enzyme has been determined in its native form and in complex with penicillin G and penicillin G sulphoxide. We show that Asn B241 has an important role in maintaining the active site geometry and in productive substrate binding, hence the structure of the mutant protein is a poor model for the Michaelis complex. For this reason, we subsequently solved the structure of the wild-type protein in complex with the slowly processed substrate penicillin G sulphoxide. Analysis of this structure suggests that the reaction mechanism proceeds via direct nucleophilic attack of Ser B1 on the scissile amide and not as previously proposed via a tightly H-bonded water molecule acting as a "virtual" base.     

One-step site-directed mutagenesis of the Kex2 protease oxyanion hole

BACKGROUND: Members of the subtilisin family of serine proteases usually have a conserved asparagine residue that stabilizes the oxyanion transition state of peptide-bond hydrolysis. Yeast Kex2 protease is a member of the subtilisin family that differs from the degradative subtilisin proteases in its high substrate specificity, it processes pro-alpha-factor, the precursor of the alpha-factor mating pheromone of yeast, and also removes the pro-peptide from its own precursor by an intramolecular cleavage reaction. Curiously, the mammalian protease PC2, a Kex2 homolog that is likely to be required for pro-insulin processing, has an aspartate in place of asparagine at the 'oxyanion hole'. RESULTS: We have tested the effect of making substitutions of the conserved oxyanion-hole asparagine (Asn 314) of the Kex2 protease. To do this, we have developed a rapid method of site-directed mutagenesis, involving homologous recombination of a polymerase chain reaction product in yeast. Using this method, we have substituted alanine or aspartate for Asn 314 in a form of Kex2 engineered for secretion. Transformants expressing the two mutant enzymes could be identified by failure either to produce mature alpha-factor or to mate. The Ala 314 enzyme was unstable but the Asp 314 enzyme accumulated to a high level, so that it could be purified and its activity towards various substrates tested in vitro. We found that, with three peptides that are good substrates of wild-type Kex2, the k(cal) of the Asp 314 enzyme was reduced approximately 4500-fold and its K(M) approximately 4-fold, relative to the wild-type enzyme. For the peptide substrate corresponding to the cleavage site of pro-alpha-factor, however, k(cat) of the Asp 314 enzyme was reduced only 125-fold, while the K(m) was increased 3-fold. Despite its reduced catalytic activity, however, processing of the mutant enzyme in vivo - by the intramolecular cleavage that removes its amino-terminal pro-domain - occurs at an unchanged rate. CONCLUSIONS: The effects of the Asn 314-Asp substitution reveal contributions to the reaction specificity of the Kex2 protease of substrate residues amino-terminal to the pair of basic residues at the cleavage site. Aspartate at the oxyanion hole appears to confer k(caf) discrimination between substrates by raising the energy barrier for productive substrate binding: this may have implications for pro-insulin processing by the PC2 protease, which has an aspartate at the equivalent position. The rate of intramolecular cleavage of pro-Kex2 may be limited by a step other than catalysis, presumably protein folding.     

Repeat sequence of Epstein-Barr virus-encoded nuclear antigen 1 protein interrupts proteasome substrate processing

The Epstein-Barr virus thwarts immune surveillance through a Gly-Ala repeat (GAr) within the viral Epstein-Barr virus-encoded nuclear antigen 1 protein. The GAr inhibits proteasome processing, an early step in antigen peptide presentation, but the mechanism of proteasome inhibition has been unclear. By embedding a GAr within ornithine decarboxylase, a natural proteasome substrate that does not require ubiquitin conjugation, we now demonstrate inhibition in a purified system, excluding involvement of ubiquitin conjugation or of proteins extraneous to substrate and proteasome. We show further that the GAr acts as a stop-transfer signal in proteasome substrate processing, resulting in vivo in partial proteolysis that halts just short of the GAr. Similarly, introducing a GAr into green fluorescent protein destabilized by the ornithine decarboxylase degradation domain also stops the progress of proteolysis, leading to the accumulation of partial degradation products. We postulate that the ATP motor of the proteasome slips when it encounters the GAr, impeding further insertion and, in this way, halting degradation.     

Participation of proteolytic enzymes in the interaction of plants with phytopathogenic microorganisms

Different forms of participation of proteolytic enzymes in pathogenesis and plant defense are reviewed. Together with extracellular proteinases, phytopathogenic microorganisms produce specific effectors with proteolytic activity and are able to act on proteins inside the plant cell. In turn, plants use both extracellular and intracellular proteinases for defense against phytopathogenic microorganisms. Among the latter, a special role belongs to vacuolar processing enzymes (legumains), which perform the function of caspases in the plant cell.     

Soluble Chloroplast Enzyme Cleaves preLHCP Made in Escherichia coli to a Mature Form Lacking a Basic N-Terminal Domain

We have investigated the specificity of a chloroplast soluble processing enzyme that cleaves the precursor of the major light-harvesting chlorophyll a/b binding protein (LHCP). The precursor of LHCP (preLHCP) was synthesized in Escherichia coli and recovered from inclusion-like bodies. It was found to be a substrate for proteolytic cleavage by the soluble enzyme in an organelle-free reaction, yielding a 25 kilodalton peptide. This peptide co-migrated during sodium dodecyl sulfate-polyacrylamide gel electrophoresis with the smaller of the forms (25 and 26 kilodalton) produced when either the E. coli-synthesized precursor, or preLHCP made in a reticulocyte lysate, was imported into chloroplasts. N-Terminal sequence analysis of the E. coli-generated precursor showed that it lacked an N-terminal methionine. N-Terminal sequencing of the 25 kilodalton peptide produced in the organelle-free reaction indicated that processing occurred between residues 40 and 41, removing a basic domain (RKTAAK) thought to be at the N-terminus of all LHCP molecules of type I associated with photosystem II. To determine if the soluble enzyme involved also cleaves other precursor polypeptides, or is specific to preLHCP, it was partially purified, and the precursors for Rubisco small subunit, plastocyanin, Rubisco activase, heat shock protein 21, and acyl carrier protein were tested as substrates. All of these precursors were cleaved by the same chromatographic peak of activity that processes preLHCP in the organelle-free reaction.     

Evaluation of cardosin A as a proteolytic probe in the presence of organic solvents

This investigation showed that cardosin A not only is active in media with organic solvents, cleaving the β-chain of oxidised insulin at three susceptible peptide bonds, but also maintains its specificity in all media tested. Additionally, the presence of organic solvents in the reaction media led to modifications of enzyme selectivity, which enabled the detection of intermediate products. While solvents like ethyl acetate induced a decrease in enzymatic activity, both by reducing the amount of active enzyme and presumably due to an inhibiting effect of ethyl acetate (which might compete with the substrate for the active site of the enzyme), n-hexane caused an increase in the hydrolysis velocity of one peptide bond. In view of the activity and specificity of cardosin A (which shows high preference for hydrophobic residues), it is proposed as a reliable probe for limited proteolysis in the presence of organic solvents. This may become particularly useful for structural characterisation of membrane proteins.     

Genomic isolation of genes encoding starch branching enzyme II (SBEII) in apple: toward characterization of evolutionary disparity in <Emphasis Type="Italic">Sbe</Emphasis>II genes between monocots and eudicots

Reproductive and storage tissues of many plants produce large amounts of serine proteinase inhibitors (PIs). The ornamental tobacco, Nicotiana alata, produces a series of 6 kDa chymotrypsin and trypsin inhibitors that accumulate to up to 30% of soluble protein in the stigma. These inhibitors are derived by proteolytic processing of two closely related multidomain precursor proteins. Using immunogold electron microscopy, we find that the stigmatic PIs accumulate in both the central vacuole and in the extracellular mucilage. Labelling with antibodies specific for the C-terminal vacuolar targeting peptide (VTS) of each precursor confirms earlier biochemical data showing that the VTS is removed during passage through the secretory pathway. We have isolated and characterised the extracellular population of PIs, which are largely identical to PIs isolated from whole stigmas and are functional inhibitors of serine proteases. Subcellular fractionation of immature stigmas reveals that a sub-population of the PI precursor protein is proteolytically processed within the endoplasmic reticulum. This proteolysis results in the removal of the vacuolar sorting information, causing secretion of this PI population. We propose a novel mechanism whereby a single gene product may be simultaneously trafficked to two separate compartments mediated by proteolysis early in the secretory pathway.     

Role of glutamine-169 in the substrate recognition of human aminopeptidase B

Background

Aminopeptidase B (EC 3.4.11.6, APB) preferentially hydrolyzes N-terminal basic amino acids of synthetic and peptide substrates. APB is involved in the production and maturation of peptide hormones and neurotransmitters such as miniglucagon, cholecystokinin and enkephalin by cleaving N-terminal basic amino acids in extended precursor proteins. Therefore, the specificity for basic amino acids is crucial for the biological function of APB.

Methods

Site-directed mutagenesis and molecular modeling of the S1 site were used to identify amino acid residues of the human APB responsible for the basic amino acid preference and enzymatic efficiency.

Results

Substitution of Gln169 with Asn caused a significant decrease in hydrolytic activity toward the fluorescent substrate Lys-4-methylcoumaryl-7-amide (MCA). Substantial retardation of enzyme activity was observed toward Arg-MCA and substitution with Glu caused complete loss of enzymatic activity of APB. Substitution with Asn led to an increase in IC₅₀ values of inhibitors that interact with the catalytic pocket of APB. The EC₅₀ value of chloride ion binding was also found to increase with the Asn mutant. Gln169 was required for maximal cleavage of the peptide substrates. Molecular modeling suggested that interaction of Gln169 with the N-terminal Arg residue of the substrate could be bridged by a chloride anion.

Conclusion

Gln169 is crucial for obtaining optimal enzymatic activity and the unique basic amino acid preference of APB via maintaining the appropriate catalytic pocket structure and thus for its function as a processing enzyme of peptide hormones and neurotransmitters.     

Molecular cloning and functional characterization of a snake venom metalloprotease.

A cDNA clone, MT-d, encoding metalloprotease precursor was isolated from snake (Agkistrodon halys brevicaudus) venom gland cDNA library. MT-d-I protein containing both metalloprotease and disintegrin domains, and MT-d-II protein containing the metalloprotease domain only were expressed in Escherichia coli and refolded successfully into their functional forms. Each of the refolded enzyme species exhibited distinct substrate specificity. Proteolytic activity of the MT-d-1 was able to hydrolyse type I gelatin, type-III and V collagens in contrast with the catalytic function of MT-d-II. MT-d-I protein having metalloprotease activity was also able to inhibit platelet aggregation. Functionally active MT-d-I protein underwent autoproteolytic processing in vitro to produce metalloprotease and disintegrin; this processing was accompanied by significant changes in the substrate specificity of the enzyme activity. Experimental evidence strongly suggests that the disintegrin domain in the metalloprotease precursor modulates the catalytic function of the enzyme in hydrolysing extracellular matrix proteins.     

Evidence for the in vivo deamidation and isomerization of an asparaginyl residue in cytosolic serine hydroxymethyltransferase

Rabbit liver cytosolic serine hydroxymethyltransferase exists in several subforms which have different isoelectric points. Incubation of the purified enzyme with chymotrypsin cleaves the enzyme at Trp14. The released amino-terminal 14-mer peptide was shown to exist in three forms of equal concentration. The peptides differ in structure only at the asparaginyl residue at position 5. In addition to asparagine at this position we found both aspartyl and isoaspartyl residues. The deamidation of Asn5 does not appear to occur during the purification of the enzyme. The in vitro rate of deamidation of Asn5 in the enzyme is more than 5-fold slower than the rate of deamidation of this residue in the free 14-mer peptide. The isoaspartyl residue at position 5 serves as a substrate for protein carboxyl methyltransferase both in the free 14-mer peptide and the native enzyme. The enzyme which has had the amino-terminal 14 residues removed by digestion with chymotrypsin still exists in several forms with different isoelectric points. Reaction of peptides from this enzyme with carboxyl methyltransferase suggests that there is at least one more asparaginyl residue in this enzyme other than Asn5 which has undergone deamidation with the formation of isoaspartyl bonds.     

Evaluation of the CFP-substrate-YFP system for protease studies: advantages and limitations

A protease can be defined as an enzyme capable of hydrolyzing peptide bonds. Thus, characterization of a protease involves identification of target peptide sequences, measurement of activities toward these sequences, and determination of kinetic parameters. Biological protease substrates based on fluorescent protein pairs, which allow for use of fluorescence resonance energy transfer (FRET), have been recently developed for in vivo protease activity detection and represent a very interesting alternative to chemical substrates for in vitro protease characterization. Here, we analyze a FRET system consisting of cyan and yellow fluorescent proteins (CFP and YFP, respectively), which are fused by a peptide linker serving as protease substrate. Conditions for CFP-YFP fusion protein production in Escherichia coli and purification of proteins were optimized. FRET between CFP and YFP was found to be optimum at a pH between 5.5 and 10.0, at low concentrations of salt and a temperature superior to 25 degrees C. For efficient FRET to occur, the peptide linker between CFP and YFP can measure up to 25 amino acids. The CFP-substrate-YFP system demonstrated a high degree of resistance to nonspecific proteolysis, making it suitable for enzyme kinetic analysis. As with chemical substrates, substrate specificity of CFP-substrate-YFP proteins was tested towards different proteases and kcat/Km values were calculated.