Prohormone Thiol Protease and Enkephalin Precursor Processing: Cleavage at Dibasic and Monobasic Sites

Production of active enkephalin peptides requires proteolytic processing of proenkephalin at dibasic Lys-Arg, Arg-Arg, and Lys-Lys sites, as well as cleavage at a monobasic arginine site. A novel “prohormone thiol protease” (PTP) has been demonstrated to be involved in enkephalin precursor processing. To find if PTP is capable of cleaving all the putative cleavage sites needed for proenkephalin processing, its ability to cleave the dibasic and the monobasic sites within the enkephalin-containing peptides, peptide E and BAM-22P (bovine adrenal medulla docosapeptide), was examined in this study. Cleavage products were separated by HPLC and subjected to microsequencing to determine their identity. PTP cleaved BAM-22P at the Lys-Arg site between the two basic residues. The Arg-Arg site of both peptide E and BAM-22P was cleaved at the NH₂-terminal side of the paired basic residues to generate [Met]-enkephalin. Furthermore, the monobasic arginine site was cleaved at its NH₂-terminal side by PTP. These findings, together with previous results showing PTP cleavage at the Lys-Lys site of peptide F, demonstrate that PTP possesses the necessary specificity for all the dibasic and monobasic cleavage sites required for proenkephalin processing. In addition, the unique specificity of PTP for cleavage at the NH₂-terminal side of arginine at dibasic or monobasic sites distinguishes it from many other putative prohormone processing enzymes, providing further evidence that PTP appears to be a novel prohormone processing enzyme.     

Conformational studies on synthetic peptides reproducing the dibasic processing site of pro-ocytocin–neurophysin

Synthetic peptides reproducing the proteolytic processing site of pro-ocytocin were studied by different spectroscopic techniques, including circular dichroism, Fourier tranform infrared absorption, and mono and bidimensional nuclear magnetic resonance, in order to ascertain the possible role of three-dimensional structure in the recognition process by maturation enzymes. Experimental results were compared with energy minimization calculations and suggest that: (i) the region situated on the N-terminus of the Lys-Arg doublet may form a β-turn; (ii) the sequential organization of the residues participating in the β-turn determines the privileged relative orientation of the basic amino acid sidechains and the subtype of turn; and (iii) the peptide segment situated on the C-terminal side of the dibasic doublet may assume a helix arrangement. These findings, in spite of the limitations connected to the flexibility of linear peptides, seem to substantiate the hypothesis that structural motifs around the cleavage site could be important for recognition and processing. However, a straightforward correlation between details of the secondary structure and the in vitro reactivity toward a putative convertase is not yet possible.     

Prosomatostatin is processed in the Golgi apparatus of rat neural cells.

Proteolytic processing of somatostatin precursor produces several peptides including somatostatin-14 (S-14), somatostatin-28 (S-28), and somatostatin-28 (1-12) (S-28(1-12)). The subcellular sites at which these cleavages occur were identified by quantitative evaluation of these products in enriched fractions of the biosynthetic secretory apparatus of rat cortical or hypothalamic cells. Each of the major cellular compartments was obtained by discontinuous gradient centrifugation and was characterized both by specific enzyme markers and electron microscopy. The prosomatostatin-derived fragments were measured by radioimmunoassay after chromatographic separation. Two specific antibodies were used, allowing the identification of either S-28(1-12) or S-14 which results from peptide bond hydrolysis at a monobasic (arginine) and a dibasic (Arg-Lys) cleavage site, respectively. These antibodies also revealed prosomatostatin-derived forms containing at their COOH terminus the corresponding dodeca- and tetradecapeptide sequences. Whereas the reticulum-enriched fractions contained the highest levels of prosomatostatin, the proportion of precursor was significantly lower in the Golgi apparatus. In the latter fraction, other processed forms were also present, i.e. S-14 and S-28(1-12) together with the NH2-terminal domain (1-76) of prosomatostatin (pro-S(1-76). Inhibition of the intracellular transport either by monensin or by preincubation at reduced temperature resulted in an increase of prosomatostatin-derived peptides in the Golgi-enriched fractions. Finally, immunogold labeling using antibodies raised against S-28(1-12) and S-14 epitopes revealed the presence of these forms almost exclusively in the Golgi-enriched fraction mainly at the surface of saccules and vesicles. Together these data demonstrate that in rat neural cells, prosomatostatin proteolytic processing at both monobasic and dibasic sites is initiated at the level of the Golgi apparatus.     

Structural characterization of peptides derived from prosomatostatins I and II isolated from the pancreatic islets of two species of teleostean fish: the daddy sculpin and the flounder

The primary structures of three peptides from extracts from the pancreatic islets of the daddy sculpin (Cottus scorpius) and three analogous peptides from the islets of the flounder (Platichthys flesus), two species of teleostean fish, have been determined by automated Edman degradation. The structures of the flounder peptides were confirmed by fast-atom bombardment mass spectrometry. The peptides show strong homology to residues (49-60), (63-96) and (98-125) of the predicted sequence of preprosomatostatin II from the anglerfish (Lophius americanus). The amino acid sequences of the peptides suggest that, in the sculpin, prosomatostatin II is cleaved at a dibasic amino acid residue processing site (corresponding to Lys61-Arg62 in anglerfish preprosomatostatin II). The resulting fragments are further cleaved at monobasic residue processing sites (corresponding to Arg48 and Arg97 in anglerfish preprosomatostatin II). In the flounder the same dibasic residue processing site is utilised but cleavage at different monobasic sites takes place (corresponding to Arg50 and Arg97 in anglerfish preprosomatostatin II). A peptide identical to mammalian somatostatin-14 was also isolated from the islets of both species and is presumed to represent a cleavage product of prosomatostatin I.     

Dimer structure of a neuropeptide precursor established: consequences for processing

A prohormone (P1) of locust adipokinetic hormone I (AKH I) is shown here to be a homodimer of a 41 residue subunit called the A-chain. The A-chain, from the N terminal, consists of AKH I (10 amino acids starting with pyroglutamate) followed by a Gly-Lys-Arg processing site and then a 28 residues called the alpha chain containing a single cysteine and a potential Arg-Lys processing site. When processed each molecule of the homodimer precursor yields two copies of AKH I and one alpha chain homodimer. We call the alpha-alpha homodimer product of P1 processing AKH precursor related peptide 1 or APRP 1. The Arg-Lys dibasic pair found within the alpha chain is not cleaved in vivo. Our results show that neuropeptide precursors can be dimers and that dimer products can be synthesized by processing of a preformed dimer precursor rather than by dimerization of independent subunits.     

Nardilysin cleaves peptides at monobasic sites

Nardilysin (N-arginine dibasic convertase, EC 3.4.24.61) was first identified on the basis of its ability to cleave peptides containing an arginine dibasic pair, i.e., Arg-Arg or Arg-Lys. However, it was observed that an aromatic residue adjacent to the dibasic pair (i.e., Phe-Arg-Lys) could alter the cleavage site. In this study we determined whether nardilysin can cleave peptides at a single basic residue. Nardilysin cleaves beta-endorphin at the monobasic site, Phe(17)-Lys(18), with a k(cat)/K(m) of 2 x 10(8) M(-)(1) min(-)(1). This can be compared to a k(cat)/K(m) of 8.5 x 10(8) M(-)(1) min(-)(1) for cleavage between a dibasic pair in dynorphin B-13. Nardilysin also cleaves calcitonin at His-Arg and somatostatin-14 at Cys-Lys. We examined the hydrolysis of fluorogenic peptides based on the beta-endorphin 12-24 sequence, Abz-T-P-L-V-T-L-X(1)-X(2)-N-A-I-I-K-Q-EDDnp. Nardilysin hydrolyzes the peptides when X(1)-X(2) = F-K, F-R, W-K, M-K, Y-K, and L-K. The kinetics of cleavage at F-K and F-R are similar; however, K-F is not hydrolyzed. Nardilysin cleaves at two monobasic sites M-K and F-R of the kallidin model peptide Abz-MISLMKRPPGFSPFRSSRI-NH(2), releasing desArg(10) kallidin (KRPPGFSPF). However, nardilysin does not release desArg(10) kallidin from the physiological precursor low molecular weight kininogen. These studies extend the range of potential substrates for nardilysin and further substantiate that nardilysin is a true peptidase.     

Specificity of the dynorphin-processing endoprotease: comparison with prohormone convertases

The cleavage specificity of a monobasic processing dynorphin converting endoprotease is examined with a series of quench fluorescent peptide substrates and compared with the cleavage specificity of prohormone convertases. A dynorphin B-29-derived peptide, Abz-Arg-Arg-Gln-Phe-Lys-Val-Val-Thr-Arg-Ser-Glneddnp (where Abz is o-aminobenzoyl and eddnp is ethylenediamine 2,4-dinitrophenyl), that contains both dibasic and monobasic cleavage sites is efficiently cleaved by the dynorphin converting enzyme and not cleaved by two propeptide processing enzymes, furin and prohormone convertase 1. A shorter prorenin-related peptide, Dnp-Arg-Met-Ala-Arg-Leu-Thr-Leu-eddnp, that contains a monobasic cleavage site is cleaved by the dynorphin converting enzyme and prohormone convertase 1 and not by furin. Substitution of the P1' position by Ala moderately affects cleavage by the dynorphin-processing enzyme and prohormone convertase 1. It is interesting that this substitution results in efficient cleavage by furin. The site of cleavage, as determined by matrix-assisted laser desorption/ionization time of flight mass spectrometry, is N-terminal to the Arg at the P1 position for the dynorphin converting enzyme and C-terminal to the Arg at the P1 position for furin and prohormone convertase 1. Peptides with additional basic residues at the P2 and at P4 positions also serve as substrates for the dynorphin converting enzyme. This enzyme cleaves shorter peptide substrates with significantly lower efficiency as compared with the longer peptide substrates, suggesting that the dynorphin converting enzyme prefers longer peptides that contain monobasic processing sites as substrates. Taken together, these results suggest that the cleavage specificity of the dynorphin converting enzyme is distinct but related to the cleavage specificity of the prohormone convertases and that multiple enzymes could be involved in the processing of peptide hormones and neuropeptides at monobasic and dibasic sites.     

Proteolysis of ProPTHrP(1-141) by "prohormone thiol protease" at multibasic residues generates PTHrP-related peptides: implications for PTHrP peptide production in lung cancer cells

The parathyroid hormone-related protein (PTHrP) precursor requires proteolytic processing to generate PTHrP-related peptide products that possess regulatory functions in the control of PTH-like (parathyroid-like) actions and cell growth, calcium transport, and osteoclast activity. Biologically active peptide domains within the PTHrP precursor are typically flanked at their NH2- and COOH-termini by basic residue cleavage sites consisting of multibasic, dibasic, and monobasic residues. These basic residues are predicted to serve as proteolytic cleavage sites for converting the PTHrP precursor into active peptide products. The coexpression of the prohormone processing enzyme PTP ("prohormone thiol protease") in PTHrP-containing lung cancer cells, and the lack of PTP in cell lines that contain little PTHrP, implicate PTP as a candidate processing enzyme for proPTHrP. Therefore, in this study, PTP cleavage of recombinant proPTHrP(1-141) precursor was evaluated by MALDI mass spectrometry to identify peptide products and cleavage sites. PTP cleaved the PTHrP precursor at the predicted basic residue cleavage sites to generate biologically active PTHrP-related peptides that correspond to the NH2-terminal domain (residues 1-37) that possesses PTH-like and growth regulatory activities, the mid-region domain (residues 38-93) that regulates calcium transport, and the COOH-terminal domain (residues 102-141) that modulates osteoclast activity. Lack of cleavage at other types of amino acids demonstrated the specificity of PTP processing at basic residue cleavage sites. Overall, these results demonstrate the ability of PTP to cleave the PTHrP precursor at multibasic, dibasic, and monobasic residue cleavage sites to generate active PTHrP-related peptides. The presence of PTP immunoreactivity in PTHrP-containing lung cancer cells suggests PTP as a candidate processing enzyme for the PTHrP precursor.     

Isolation of histidyl peptides of the steroid-binding site of human placental estradiol 17β-dehydrogenase

Human placental estradiol 17β-dehydrogenase (E.C. 1.1.1.62) was inactivated at pH 6.3 by 3-bromo[2′-¹⁴C]acetoxy-1,3,5(10)estratrien-17-one, a known substrate. The affinity-alkylated enzyme was then hydrolyzed by trypsin. Radioactive peptides were initially isolated by gel filtration and identified according to which residue was alkylated. Tryptic peptides containing radioactive 3-carboxymethylhistidyl residues were further purified by cation-exchange chromatography. The population of these peptides varied, depending upon the conditions of enzyme inactivation. With 60 μM 3-bromo[2′-¹⁴C]acetoxy-1,3,5(10)estratrien-17-one four major peptides (a,b,c,d) each containing radioactive 3-carboxymethylhistidine, were eluted from the cation-exchange column. The alkylation of all of these peptides was completely suppressed when the enzyme was inactivated in the presence of excess estradiol-17β. The presence of equimolar NADPH during incubation greatly enhanced the alkylation of all four peptides. In the presence of NADPH, estradiol-17β most significantly decreased the formation of peptide d. Peptide d was the only peptide identified when the concentration of the alkylating steroid was lowered to 6 βM, a value approaching the Km. These observations indicate that peptide d is a histidyl-bearing peptide from the steroid-binding site which proximates the steroid A-ring. They further suggest that with the affinity labeling steroid at higher concentrations other nonspecific, hydrophobic sites on the enzyme are occupied and labeled.     

Characterization of the Kexin-Like Maturase of Aspergillus niger

Secreted yields of foreign proteins may be enhanced in filamentous fungi through the use of translational fusions in which the target protein is fused to an endogenous secreted carrier protein. The fused proteins are usually separated in vivo by cleavage of an engineered Kex2 endoprotease recognition site at the fusion junction. We have cloned the kexin-encoding gene of Aspergillus niger (kexB). We constructed strains that either overexpressed KexB or lacked a functional kexB gene. Kexin-specific activity doubled in membrane-protein fractions of the strain overexpressing KexB. In contrast, no kexin-specific activity was detected in the similar protein fractions of the kexB disruptant. Expression in this loss-of-function strain of a glucoamylase human interleukin-6 fusion protein with an engineered Kex2 dibasic cleavage site at the fusion junction resulted in secretion of unprocessed fusion protein. The results show that KexB is the endoproteolytic proprotein processing enzyme responsible for the processing of (engineered) dibasic cleavage sites in target proteins that are transported through the secretion pathway of A. niger.     

A putative prohormone processing protease in bovine adrenal medulla specifically cleaving in between Lys-Arg sequences

Paired basic residues, particularly Lys-Arg, are known as a typical site for proteolytic processing of prohormones. In this study, we confirmed the presence of a novel protease exhibiting substrate specificity toward Lys-Arg sequence. It was partially purified from the soluble fraction of bovine adrenomedullary chromaffin granules by using an affinity chromatography on soybean trypsin inhibitor-Sepharose. The enzyme, with optimal pH around 7.5-9.5, is classified into a serine-protease family by its inhibition spectrum. The enzyme specifically cleaves in between the Lys-Arg bonds of the peptides related to proenkephalins, but the sequences of Arg-Arg, Arg-Lys and a single basic residue (Arg or Lys) in the substrates are not affected by the enzyme. The unique substrate specificity of the enzyme suggests that it is distinct from pancreatic trypsin and may be physiologically involved in proenkephalin processing.     

N-terminal sequence analysis of atrial granule serine proteinase purified by affinity chromatography

Atrial granule serine proteinase is considered the leading candidate endoproteolytic processing enzyme of pro-atrial natriuretic factor. Its cleavage specificity is directed toward a monobasic amino acid processing site, and as such, the atrial enzyme is distinguished from the family of prohormone convertases which act at dibasic amino acid processing sites. To delineate the molecular mechanisms which distinguish monobasic from dibasic amino acid-directed processing enzymes, pure atrial enzyme is needed for sequence determination leading to molecular cloning, and for preparation of antisera. An affinity chromatography purification scheme seemed a logical modification of our established procedures to yield suitable amounts of enzyme for further studies. Surprisingly, pseudo-peptide bond inhibitors of the atrial enzyme [Damodaran and Harris (1995),J. Protein Chem., this issue] formed ineffective affinity ligands, even though these compounds contain essential residues on either side of what would be the scissile bond in a peptide substrate. On the other hand, tripeptide aldehydes (based on the substrate recognition sequence of the atrial enzyme) linked to Sepharose formed effective affinity matrices, permitting purification of the enzyme in a single step from a subcellular fraction enriched for atrial granules and lysosomes. Hence, the enzyme was purified 2000-fold in 90% overall yield, and subjected to N-terminal sequence analysis through 26 residues. The sequence determined, XXPEAAGLPG[R, L]GNPVP[F, G]R[Q, I]XY[G, E]XR(N, A]V, indicates that the atrial enzyme is unique, showing little sequence homology to other proteins in the database.Abbreviations AGSP atrial granule serine proteinase - ANF atrial natriuretic factor - BSA bovine serum albumin - Bz benzoyl - EACA 6()-aminocaproic acid - HEPES N-2-hydroxyethylpiperazine-N'-propanesulfonic acid - HPLC high-performance liquid chromatography - PEG polyethylene glycol-3350 - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Single-letter abbreviations are used to denote amino acids     

The Recognition of Collagen and Triple-helical Toolkit Peptides by MMP-13: SEQUENCE SPECIFICITY FOR BINDING AND CLEAVAGE*

Remodeling of collagen by matrix metalloproteinases (MMPs) is crucial to tissue homeostasis and repair. MMP-13 is a collagenase with a substrate preference for collagen II over collagens I and III. It recognizes a specific, well-known site in the tropocollagen molecule where its binding locally perturbs the triple helix, allowing the catalytic domain of the active enzyme to cleave the collagen α chains sequentially, at Gly⁷⁷⁵–Leu⁷⁷⁶ in collagen II. However, the specific residues upon which collagen recognition depends within and surrounding this locus have not been systematically mapped. Using our triple-helical peptide Collagen Toolkit libraries in solid-phase binding assays, we found that MMP-13 shows little affinity for Collagen Toolkit III, but binds selectively to two triple-helical peptides of Toolkit II. We have identified the residues required for the adhesion of both proMMP-13 and MMP-13 to one of these, Toolkit peptide II-44, which contains the canonical collagenase cleavage site. MMP-13 was unable to bind to a linear peptide of the same sequence as II-44. We also discovered a second binding site near the N terminus of collagen II (starting at helix residue 127) in Toolkit peptide II-8. The pattern of binding of the free hemopexin domain of MMP-13 was similar to that of the full-length enzyme, but the free catalytic subunit bound none of our peptides. The susceptibility of Toolkit peptides to proteolysis in solution was independent of the very specific recognition of immobilized peptides by MMP-13; the enzyme proved able to cleave a range of dissolved collagen peptides.     

Effect of signal peptide changes on the extracellular processing of streptokinase from Escherichia coli : requirement for secondary structure at the cleavage junction

Streptokinase (SK), an extracellular protein from Streptococcus equisimilis, is secreted post-translationally by Escherichia coli using both its native and E. coli-derived transport signals. In this communication we report that cleavage specificity of signal peptidase I, and thus efficiency of secretion, varies in E. coli when SK export is directed by different transport signals. The native (+1) N-terminus of mature SK was retained when it was transported under the control of its own, PelB or LamB signal peptide. However, when translocation of SK was controlled by the OmpA or MalE signal peptide, Ala2 of mature SK was preferred as a cleavage site for the pre-SK processing. Our results indicate that compatibility of the leader peptide with the mature sequences of SK, which fulfils the requirement for a given secondary structure within the cleavage region, is essential for maintaining the correct processing of pre-SK. An OmpA-SK fusion, which results in the deletion of two N-terminal amino acid residues of mature SK, was further studied with respect to the recognition of alternative cleavage site in E. coli. The alanine at +2 in mature SK was changed to glycine or its relative position was changed to +3 by introducing a methionine residue at the +1 position. Both alterations resulted in the correct cleavage of pre-SK at the original OmpA fusion site. In contrast, introduction of an additional alanine at +4, creating three probable cleavage sites (Ala-x-Ala-x-Ala-x-Ala), resulted in the recognition of all three target sites for cleavage, with varying efficiency. The results indicate that the nature of the secondary structure generated at the cleavage junction of pre-SK, resulting from the fusion of different signal peptides, modulates the cleavage specificity of signal peptidase I during extracellular processing of SK. Based on these findings it is proposed that flexibility in the interaction of the active site of signal peptidase I with the cleavage sites of signal peptides may occur when it encounters two or more juxtaposed cleavage sites. Preference for one cleavage site over another, then, may depend on fulfillment of secondary structure requirements in the vicinity of the pre-protein cleavage junction. Received: 22 September 1997 / Accepted: 17 December 1997     

Active center and subunit structure of transaldolase from Candida utilis.

Crystalline transaldolase (type III) isolated from Candida utilis is composed of two identical subunits, as shown by the following lines of evidence. 1. Tryptic digestion of the performic acid oxidized enzyme yields the number of ninhydrin- and arginine-positive peptides expected for identical subunits. 2. All attempts to separate both subunits by molecular weight or charge differences have failed. 3. Cyanogen bromide cleavage and sodium dodecyl sulfate gel electrophoresis of S-carboxymethylated transaldolase revealed four distinct peptides designated C₂ to C₅ according to their decreasing molecular weight and one additional peak, C₁, in low yield, presumably an aggregate or partially degraded peptide.By chromatography on Sephadex G-100 the maleylated cyanogen bromide digest from ¹⁴C-labeled β-giyceryl-transaldolase could be separated into four peptide peaks which have been analyzed for their amino acid composition. The largest peptide C₂ with a molecular weight of 16,800 was identified as the active site containing fragment. The four fragments together account for all amino acid residues in the entire protein.From transaldolase (type I) containing four methionine residues three cyanogen bromide peptides could be identified. By addition of the individual peptides a molecular weight of 37,100 ± 3500 could be calculated, which is half the molecular weight of the native enzyme. From experimental data presented so far both isoenzymes of transaldolase can be regarded as “half-of-the-sites” enzymes.     

Isolation and functional properties of an arginine-selective endoprotease from rat intestinal mucosa. A putative prosomatostatin convertase.

The endoproteolytic activity previously detected in rat intestinal mucosal extracts (Beinfeld M., Bourdais, J., Kuks, P., Morel, A., and Cohen, P. (1989) J. Biol. Chem. 264, 4460-4465), was purified to homogeneity as a 65-kDa molecular species. This putative proprotein-processing enzyme cleaves the peptide bond on the carboxyl side of a single arginine residue in hepta-[Leu62-Gln-Arg-Ser-Ala-Asn-Ser68] or trideca-[Asp56-Glu-Met-Arg-Leu-Glu-Leu-Gln-Arg-Ser-Ala-Asn-+ ++Ser68] peptides, reproducing the prosomatostatin sequence around Arg64, the locus for endoproteolytic release of either somatostatin-28 or its NH2-terminal fragment, somatostatin-28-(1-12), from their common precursor. This enzyme exhibits a strict selectivity for arginyl residues, as demonstrated with related substrates, and did not cleave at lysyl residues. Moreover, only arginyl residues belonging to peptides of the prosomatostatin family were cleaved, since no hydrolysis of peptides from other prohormones was detected. In addition, the arginine residue situated at position -5 on the NH2-terminal side of Arg64 not only did not function as a cleavage locus, but had no effect on the overall cleavage kinetics of the prosomatostatin-(56-68) peptide substrate. This enzyme also cleaved, but with much less efficiency, the peptide bond on the carboxyl side of an arginine in peptides containing either an Arg-Lys or a Lys-Arg doublet corresponding to prohormone cleavage sites. This enzyme was insensitive to divalent cation chelators, was completely inhibited by aprotinin and leupeptin, and was somewhat inhibited by other serine-protease inhibitors. It is concluded that this endoprotease is a serine protease and could be involved in prohormone or proprotein post-translational processing at single arginine cleavage sites.     

Cleavage specificity of a myofibril-bound serine proteinase from carp (Cyprinus carpio) muscle

Previously, we reported the purification and characterization of a myofibril-bound serine proteinase (MBP) from carp muscle (Osatomi K, Sasai H, Cao M-J, Hara K, Ishihara T. Comp Biochem Physiol 1997;116B:159–66). In the present study, the N-terminal amino acid sequence of the enzyme was determined, which showed high identity with those of other trypsin-like serine proteases. The cleavage specificity of MBP for dibasic and monobasic residues was investigated using various fluorogenic substrates and peptides. Analyses of the cleaved peptide products showed that the enzyme hydrolyzed peptides both at monobasic and dibasic amino acid residues. Monobasic amino acid residues were hydrolyzed at the carboxyl side; dibasic residues were cleaved either at the carboxyl side of the pair or between the two basic residues and the enzyme showed a cleavage preference for the Arg-Arg pair. Unexpectedly, MBP hydrolyzed lysyl-bradykinin and methionyl–lysyl–bradykinin at the carboxyl side of Gly fairly specifically and efficiently displaying a unique cleavage. Because MBP also degraded protein substrates such as casein and myofibrillar proteins, the substrate specificity of MBP appeared not to be strictly specific.     

An internal docking site stabilizes substrate binding to γ-secretase: Analysis by molecular dynamics simulations

Amyloid precursor protein (APP) is cleaved and processed sequentially by γ-secretase yielding amyloid β (Aβ) peptides of different lengths. Longer Aβ peptides are associated with the formation of neurotoxic plaques related to Alzheimer’s disease. Based on the APP substrate-bound structure of γ-secretase, we investigated the enzyme-substrate interaction using molecular dynamics simulations and generated model structures that represent the sequentially cleaved intermediates during the processing reaction. The simulations indicated an internal docking site providing strong enzyme-substrate packing interaction. In the enzyme-substrate complex, it is located close to the region where the helical conformation of the substrate is interrupted and continues toward the active site in an extended conformation. The internal docking site consists of two non-polar pockets that are preferentially filled by large hydrophobic or aromatic substrate side chains to stabilize binding. Placement of smaller residues such as glycine can trigger a shift in the cleavage pattern during the simulations or results in destabilization of substrate binding. The reduced packing by smaller residues also influences the hydration of the active site and the formation of a catalytically active state. The simulations on processed substrate intermediates and a substrate G33I mutation offer an explanation of the experimentally observed relative increase of short Aβ fragment production for this mutation. In addition, studies on a substrate K28A mutation indicate that the internal docking site opposes the tendency of substrate dissociation due to a hydrophobic mismatch at the membrane boundary caused by K28 during processing and substrate movement toward the enzyme active site. The proposed internal docking site could also be useful for the specific design of new γ-secretase modulators.     

Isolation and Characterization of a Novel Endo-β-galactofuranosidase from Bacillus sp.

A soil bacterium capable of growing on a polysaccharide containing β(1→6)galactofuranoside residues derived from the acidic polysaccharide of Fusarium sp. as a carbon source has been isolated. From various bacteriological characteristics, the organism was identified as a Bacillus sp. The bacterium produced β- galactofuranosidase inductively in the culture media. The most effective inducer for the β-galactofuranosidase production was a polysaccharide containing β(1→5) or β(1→6)-linked galactofuranoside residues, but gum arabic, gum guar, gum ghati, arabinogalactam, araban, and pectic acid did not induce the enzyme. The enzyme had three different molecular weight forms. The low molecular-weight form was purified by a combination of Toyopearl HW-55 and DEAE-Toyopearl 650S column chromatographies, and preparative polyacrylamide gel electrophoresis. The molecular weight of the enzyme was estimated to be 67,000 by SDS–polyacrylamide gel electrophoresis. The enzyme was most active at pH 6 and 37°C, and was stable between pH 4 to 8 at 5°C. The action of the enzyme was inhibited by the addition of Cd²⁺, Co²⁺, Hg²⁺, Zn²⁺, iodoacetic acid, and EDT A. The purified enzyme cleaved β(1→5) and β(1→6)-linked galactofuranosyl chains. Based upon the mode of liberation of galactofuranosyl residues from pyridylamino β(1→6)-linked galactofuranoside oligomers, the enzyme can be classified as an endo-β-galactofuranosidase that randomly hydrolyzes the linkage.     

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.