Recombinant expression and enzymatic subsite characterization of plasmepsin 4 from the four Plasmodium species infecting man

Plasmepsin 4 from Plasmodium falciparum and orthologs from Plasmodium malariae, Plasmodium ovale and Plasmodium vivax have been expressed in recombinant form, and properties of the active site of each enzyme characterized by kinetic analysis. A panel of chromogenic peptide substrates systematically substituted at the P3, P2, P2' and P3' positions was used to estimate enzyme/ligand interactions in the corresponding enzyme subsites based upon kinetic data. The kinetic parameters kcat, Km and kcat/Km were measured to identify optimal substrates for each enzyme and also sequences that were readily cleaved by the plasmepsins but poorly by host aspartic peptidases. Computer generated models were utilized to compare enzyme structures and interpret kinetic results. The orthologous plasmepsins share highly similar subsite specificities. In the S3 and S2 subsites, the plasmepsin 4 orthologs all preferred hydrophobic amino acid residues, Phe or Ile, but rejected charged residues such as Lys or Asp. In S2' and S3' subsites, these plasmepsins tolerated both hydrophobic and hydrophilic residues. Subsite specificities of the plasmepsin 4 family of orthologs are similar to those of human cathepsins D and E, except in S3' where the plasmepsins accept substrates containing Ser significantly better than either of these human aspartic proteases. Peptidomimetic methyleneamino reduced-peptide inhibitors, which have inhibition constants in the picomolar range, were prepared for each plasmepsin 4 ortholog based upon substrate preferences. A peptidomimetic inhibitor designed for plasmepsin 4 from P. falciparum having Ser in P3' had the lowest Ki of the series of inhibitors prepared, but did not significantly improve the selectivity of the inhibitor for plasmepsin 4 versus human cathepsin D.     

T-Helper-Cell Determinants in Protein Antigens are Preferentially Located in Cysteine-Rich Antigen Segments Resistant to Proteolytic Cleavage by Cathepsin B, L, and D

We report on a computer algorithm capable of predicting the location of T-helper-cell epitopes in protein antigen (Ag) by analysing the Ag amino acid sequence. The algorithm was constructed with the aim of identifying segments in Ag which are resistant to proteolytic degradation by the enzymes cathepsin B, L, and D. These are prominent enzymes in the endocytic pathway through which soluble protein Ag enter APC, and resistant segments in Ag may, therefore, be expected to contain more T-cell determinants than susceptible segments. From information available in the literature on the substrate specificity of the three enzymes, it is clear that a cysteine is not accepted in any of the S2, S1, S1', and S2' subsites of cathepsin B and L, and not in the S1 and S1' subsites of cathepsin D. Moreover, we have noticed that cysteine-containing T-cell determinants in a number of protein Ag are particularly rich in the amino acids alanine, glycine, lysine, leucine, serine, threonine, and valine. By searching protein Ag for clusters of amino acids containing cysteine and two of the other amino acids we were able to predict 17 out of 23 empirically known T-cell determinants in the Ag with a relatively low number of false (positive) predictions. Furthermore, we present a new principle for searching Ag for potential amphipatic alpha-helical protein segments. Such segments accord well with empirically known T-cell determinants and our algorithm produces a lower number of false positive predictions than the principle based on discrete Fourier transformations previously described.     

Expression and substrate specificity of a recombinant cysteine proteinase B of Leishmania braziliensis

The cysteine proteinase B of Leishmania parasites is an important virulence factor. In this study we have expressed, isolated and characterized for the first time a recombinant CPB from Leishmania braziliensis, the causative agent of mucocutaneous leishmaniosis. The mature region of the recombinant CPB shares a high percentage identity with its Leishmania mexicana CPB2.8 (rCPB2.8DeltaCTE) counterpart (76.36%) and has identical amino acid residues at the S(1), catalytic triad and [Formula: see text] subsites. Nevertheless, when the kinetics of substrate hydrolysis was measured using a combinatorial library of internally quenched fluorescent peptides based upon the lead sequence Abz-KLRSSKQ-EDDnp, significant differences were obtained. These results suggest that the differences in substrate utilization observed between the L. mexicana and L. braziliensis CPs must be related to amino acid modifications outside the core of the active site cleft. Moreover, a potent inhibitor with Pro at P1 and high affinity for L. braziliensis recombinant CPB showed less affinity to L. mexicana CPB 2.8, which preferred Phe, Leu, and Asn at the same position.     

The extended cleavage specificity of the rodent beta-chymases rMCP-1 and mMCP-4 reveal major functional similarities to the human mast cell chymase

In rat and mouse the phylogenetic homologues of the human mast cell alpha-chymase (rMCP-5 and mMCP-5) have lost their chymase activity and instead become elastases. To investigate whether rodents hold enzymes with equivalent function as the primate alpha-chymases, we have determined the extended cleavage specificity of the major connective tissue mast cell beta-chymases in rat and mouse, rMCP-1 and mMCP-4. By using a phage display approach we determined the enzyme/substrate interaction in seven positions, both N- and C-terminal of the cleaved bond. The two proteases were found to display rather similar specificities. Both enzymes prefer Phe in position P1, and aliphatic amino acids are favoured N-terminal of the cleaved bond, i.e. Leu in P2 and Val in P3 and P4. Val and Leu are overrepresented also in positions P1' and P3'. The two enzymes differ clearly only in one position, the P2' residue, where mMCP-4 strongly prefers negatively charged amino acids while rMCP-1 favours Ser. Interestingly, Asp and Glu are often present in position P2' of known substrates for the human chymase. Overall, these two rodent beta-chymases have very similar amino acid preferences as the human chymase, particularly mMCP-4, which most likely have a very similar function as the human chymase. This finding indicates that rodent and primate connective tissue mast cells seem to have relatively similar proteolytic repertoires, although they express different sets of serine proteases.     

Proteolysis of human hemoglobin by schistosome cathepsin D

Schistosomes feed on human blood. They employ proteases to degrade hemoglobin from ingested erythrocytes, using the residues released for amino acid metabolism. However, the identity and the role of the participating protease(s) are unclear and controversial. Confocal microscopy localized schistosomal cathepsin D to the parasite gastrodermis, and revealed elevated protease expression in females. At sub-cellular level, cathepsin D was localized to superficial digestive vacuoles of the gut and to cisternae of the gastrodermal rough endoplasmic reticulum. Schistosome cathepsin D, expressed in insect cells, autoactivated at pH 3.6 to a approximately 40 kDa form that cleaved the substrates o-aminobenzoyl-Ile-Glu-Phe-nitroPhe-Arg-leu-NH(2) and hemoglobin. The NH(2)-terminal residues of mature cathepsin D of Schistosoma japonicum and Schistosoma mansoni were Asn1 and Gly1, respectively, revealing that the proregion peptide was comprised of 35 residues. The proteases cleaved hemoglobin at pH 2.5--4.6, releasing numerous fragments. S. Japonicum cathepsin D cleaved at 13 sites, S. mansoni cathepsin D at 15 sites. Early cleavage sites were alpha Phe33-Leu34 and beta Phe41-Phe42, while others included alpha Leu109-Ala-110 and beta Leu14-Trp15, demonstrating a preference for bulky hydrophobic residues at P1 and P1'. Most of the schistosomal cathepsin D cleavage sites were discrete from those of human cathepsin D. The gastrodermal location, elevated expression in females, acidic pH optima, similar substrate preferences in two species, and the discrete substrate preferences compared with human cathepsin D together provide compelling support for the hypothesis that schistosomal cathepsin D plays an integral role in hemoglobin proteolysis, and might be selectively targeted by drugs based on protease inhibition.     

Design and use of highly specific substrates of neutrophil elastase and proteinase 3

We have exploited differences in the structures of S2' subsites of proteinase 3 (Pr3) and human neutrophil elastase (HNE) to prepare new fluorogenic substrates specific for each of these proteases. The positively charged residue at position 143 in Pr3 prevents it from accommodating an arginyl residue at S2' and improves the binding of P2' aspartyl-containing substrates, as judged by the decreased K(m). As a result, the k(cat)/K(m) for Abz-VADCADQ-EDDnp is over 500 times greater for Pr3 than for HNE, and that for Abz-APEEIMRRQ-EDDnp is over 500 times greater for HNE than for Pr3. This allows each protease activity to be measured in the presence of a large excess of the other, as might occur in vivo. Placing a prolyl residue in position P2' greatly impaired substrate binding to both HNE and Pr3, which further emphasizes the importance of S' subsites in these proteases. HNE and Pr3 activities were measured with these substrates at the surface of fixed polymorphonuclear leukocytes (PMNs) before and after activation. This demonstrated that their active site remains accessible when they are exposed to the cell surface. Both membrane-bound proteases were strongly inhibited by low M(r) serine protease inhibitors, but only partially by inhibitors of larger M(r) such as alpha1-protease inhibitor, the main physiologic inhibitor in lung secretions. Most of membrane-bound HNE and Pr3 can be released from the membrane surface of fixed cells by a buffer containing detergent, suggesting that hydrophobic interactions are involved in membrane binding.     

The amino and carboxyl domains of the infectious bronchitis virus nucleocapsid protein interact with 3' genomic RNA

Previous studies indicated that the nucleocapsid (N) protein of infectious bronchitis virus (IBV) interacted with specific sequences in the 3' non-coding region of IBV RNA. In order to identify domains in the N protein that bind to RNA, the whole protein (409 amino acids) and six overlapping fragments were expressed as fusion polypeptides with six histidine-tags. Using gel shift assays, the intact N protein and amino polypeptides, from residues 1 to 171 and residues 1 to 274, and carboxyl polypeptides, extending from residues 203 to 409 and residues 268 to 407, were found to interact with positive-stranded IBV RNA representing the 3' end of the genome. The two 32P-labeled probes that interacted with N and the amino and carboxyl fragments of N were RNA consisting of the IBV N gene and adjacent 3' non-coding terminus, and RNA consisting of the 155-nucleotide sequences at the 3' end of the 504-nt 3' untranslated region. In contrast, the polypeptide fragment from the middle region, residues 101-283, did not interact with these 3' IBV RNAs. The binding site in the amino region of N was either not present or only partially present in the first 91 residues because no interaction with RNA was observed with the polypeptide incorporating these residues. Cache Valley virus N expressed with a histidine tag, bovine serum albumin, and the basic lysozyme protein did not shift the IBV RNA. The lower molarities of the carboxyl fragment compared with residue 1-274 fragment needed for equivalent shifts suggested that the binding avidity for RNA at the carboxyl domain was greater than the amino domain.     

Crystal structure of the serine protease domain of Sesbania mosaic virus polyprotein and mutational analysis of residues forming the S1-binding pocket

Sesbania mosaic virus (SeMV) polyprotein is processed by its N-terminal serine protease domain. The crystal structure of the protease domain was determined to a resolution of 2.4 A using multiple isomorphous replacement and anomalous scattering. The SeMV protease domain exhibited the characteristic trypsin fold and was found to be closer to cellular serine proteases than to other viral proteases. The residues of the S1-binding pocket, H298, T279 and N308 were mutated to alanine in the DeltaN70-Protease-VPg polyprotein, and the cis-cleavage activity was examined. The H298A and T279A mutants were inactive, while the N308A mutant was partially active, suggesting that the interactions of H298 and T279 with P1-glutamate are crucial for the E-T/S cleavage. A region of exposed aromatic amino acids, probably essential for interaction with VPg, was identified on the protease domain, and this interaction could play a major role in modulating the function of the protease.     

IgG antibody response against Plasmodium falciparum aminopeptidase 1 antigen in Gabonese children living in Makokou and Franceville

The search for novel chemical classes of anti-malarial compounds to cope with the current state of chemoresistance of malaria parasites has led to the identification of Plasmodium falciparum aminopeptidase 1 (PfA-M1) as a new therapeutic target. PfA-M1, known to be involved in the hemoglobin digestion cascade which helps to provide most of the amino acids necessary to the parasite’s metabolism, is currently considered as a promising target for anti-malarial chemotherapy. However, its immunogenic properties have not yet been tested in the Gabonese population. In Gabon, the prevalence of malaria remains three times higher in semi-urban areas (60·12%) than in urban areas (17·06%). We show that malaria-specific PfA-M1 antibodies are present in children and increase with the level of infection. Children living in semi-urban areas have higher anti-PfA-M1 antibody titers (0·14 ± 0·02 AU) than those living in urban areas (0·08 ± 0·02 AU, P = 0·03), and their antibody titers increase with age (P < 0·0001). Moreover, anti-PfA-M1 antibody titers decrease in children with hyperparasitemia (0·027 ± 0·055 AU) but they remain high in children with low parasite density (0·21 ± 0·034 AU, P = 0·034). In conclusion, our results suggest that malaria-specific PfA-M1 antibodies may play an important role in the immune response of the host against P. falciparum in Gabonese children. Further studies on the role of PfA-M1 during anemia are needed.     

Assignment of functional domains involved in ADP-ribosylation and B-oligomer binding within the carboxyl terminus of the S1 subunit of pertussis toxin.

The roles of the carboxyl terminus of the S1 subunit (composed of 235 amino acids) of pertussis toxin in the ADP-ribosylation of transducin (Gt) and in B-oligomer binding were defined by analysis of two carboxyl-terminal deletion mutants of the recombinant S1 (rS1) subunit: C204, which is composed of amino acids 1 through 204 of S1, and C219, which is composed of amino acids 1 through 219 of S1. C204 was expressed in Escherichia coli as a stable, soluble peptide that had an apparent molecular mass of 23.4 kDa. In a linear velocity assay, the specific activity of C180 was 2% and that of C204 was 80% of the activity displayed by rS1 in catalyzing the ADP-ribosylation of Gt. In addition, C204 possessed catalytic efficiencies (kcat/Km) that were 110% at variable Gt concentrations and 40% at variable NAD concentrations of those reported for rS1. These data showed that the catalytic activity of C204 approached the activity of S1. C204 and C219 were unable to associate with the B oligomer under conditions which promoted association of rS1 with the B oligomer. Consistent with these results, mixtures of C204 or C219 with the B oligomer did not elicit a clustering phenotype in CHO cells, whereas rS1 which had associated with the B oligomer was as cytotoxic as native pertussis toxin. These data indicate that residues between 219 and 235 are important in the association of the S1 subunit with the B oligomer. These data allow the assignment of functional regions to the carboxyl terminus of S1. Residues 195 to 204 are required for optimal ADP-ribosyltransferase activity, residues 205 to 219 link the catalytic region of S1 and a B-oligomer-binding region of S1, and residues 220 to 235 are required for association of S1 with the B oligomer.     

Complete nucleotide sequence of the M RNA segment of Uukuniemi virus encoding the membrane glycoproteins G1 and G2

We have determined the complete nucleotide sequence of the virion M RNA segment of Uukuniemi virus (Uukuvirus genus, Bunyaviridae) from cloned cDNA. The RNA that encodes the two membrane glycoproteins G1 and G2 is 3231 residues long (mol wt 1.1 X 10(6)). The 5' and 3' ends of the RNA are partially complementary to each other for some 30 bp, enabling the formation of a stable panhandle structure (delta G = -40 kcal/mol) and the circularization of the molecule. The extreme 5' and 3' terminal nucleotides are identical for 10 to 13 residues to those of the M RNA of Punta Toro and Rift Valley fever viruses, two members of the Phlebovirus genus. A single open reading frame comprising 1008 amino acid residues (mol wt 113,588) was found in the mRNA-sense strand between nucleotides 18 and 3042. This probably corresponds to the previously identified 110,000-Da precursor (p110) of G1 and G2. By comparing the partial aminoterminal sequences of purified G1 and G2 with the deduced protein sequence we confirmed that the gene order is NH2-G1-G2-COOH. Both mature G1 and G2 are preceded by a stretch of 17 predominantly hydrophobic amino acids likely to represent the signal sequences. At their COOH-terminal ends, G1 and G2 have a hydrophobic stretch of amino acids, 19 and 27 residues, respectively, that probably anchors the proteins to the lipid bilayer. The sequence indicates that mature G2 is 495 amino acids long (mol wt 54,869), whereas the exact size of G1 is unclear, since the location of the COOH-terminus of G1 is not known. An upper value of 479 amino acids (mol wt 55,181) can, however, be suggested. Both G1 and G2 contain four potential glycosylation sites for Asn-linked glycans and both are unusually rich in cysteines, 6.1% in G1 and 5.4% in G2. Comparison of the amino acid sequence of the M RNA product of Uukuniemi virus with that of Punta Toro and Rift Valley fever viruses showed in both cases a weak homology that was more pronounced for the proteins located at the COOH-terminal end of the precursor. This suggests a distant evolutionary relationship between the Phlebo- and Uukuvirus genera.     

Location of the amino acid differences in the S1 spike glycoprotein subunit of closely related serotypes of infectious bronchitis virus

Four UK strains of three different serotypes were found to differ by only 2-3% of their S1 amino acids. The S1 sequences were also very similar to those of three Dutch isolates (D207, D274 and D3896), the greatest difference between two of the seven isolates being 4.4%. The few amino acid differences between the seven isolates were located largely between residues 19-122 and 251-347 of the mature S1 subunit. The seven isolates could be differentiated using 16 monoclonal antibodies in an enzyme-linked immunosorbent assay. Some virus neutralizing (VN) antibody-inducing epitopes were common to all seven isolates even though the strains had been differentiated into three serotypes by polyclonal sera. The results indicate that the most antigenic of the VN antibody-inducing epitopes are formed by very few amino acids and that these occur in the first and third quarters of the S1 subunit. We suggest that serology-based epizootiological studies of IBV should, therefore, be augmented by the inclusion of nucleic acid sequencing and/or monoclonal antibody analysis.     

Extended substrate specificity of opossum chymase--implications for the origin of mast cell chymases

Serine proteases are major granule constituents of mast cells, neutrophils, T cells and NK cells. The genes encoding these proteases are arranged in different loci. The mast cell chymase locus e.g. comprises at least one alpha-chymase, one cathepsin G, and two granzyme genes in almost all mammalian species investigated. However, in the gray, short-tailed opossum (Monodelphis domestica) this locus contains only two genes. Phylogenetic analyses place one of them clearly with the alpha-chymases, whereas the other gene is equally related to cathepsin G and the granzymes. To study the function of opossum chymase, and to explore the evolutionary origin of mast cell chymases, we have analyzed the cleavage specificity of this enzyme. The protease was expressed in mammalian cells and the extended substrate specificity was determined using a randomized phage-displayed nonapeptide library. A strong preference for the aromatic amino acids Trp over Phe and Tyr in the P1 position was observed. This is in contrast to human chymase and mouse mast cell protease-4, which prefer Phe over Tyr and Trp in this position. However, in most other positions this enzyme shows amino acid preferences very similar to human chymase and mouse mast cell protease-4, i.e. aliphatic amino acids in positions P4, P3, P2 and P1', and acidic amino acids (Glu and Asp) in the P2' position. The overall specificity of MC chymase thereby seems to have been conserved over almost 200 million years of mammalian evolution, indicating a strong selective pressure in maintaining this specificity and an important role for these enzymes in mast cell biology.     

Sequence analyses and structural predictions of double-stranded RNA segment S1 and VP7 from United States prototype bluetongue virus serotypes 13 and 10

The nucleotide sequence of segment S1 and the deduced amino acid sequence of VP7 from bluetongue virus (BTV) serotype 13 was determined. Sequences were obtained by use of standard dideoxy DNA sequencing and by direct sequencing of genomic double-stranded RNA (dsRNA). The dsRNA was sequenced with a new dideoxy protocol that produces 300 to 350 bases per set of reactions. Segment S1 is 1156 bp long and contains one long open reading frame capable of coding for 349 amino acids. The protein, VP7, is rather hydrophobic, and has a calculated molecular weight of 38,619 and a net charge of +1.5 at pH 7.0. Segment S1 of BTV-13 has 79.6% of its nucleotides conserved when compared with segment S1 of BTV-10. While most of these differences occur at the third codon position of the open reading frame, the differences between the 89-base-long, 3' noncoding regions occur predominantly in pockets at positions 1092-1098, 1112-1114, and 1125-1129. Potential stem-loop structures encompassing the stop codon of the open reading frame are proposed for both serotypes. Comparisons of VP7 from BTV-13 and BTV-10 indicate that 93.7% of the amino acid residues are conserved, including a single lysine at position 255. Secondary structure predictions infer an eight-stranded beta-barrel structure between residues 150 and 250. This putative beta-barrel may serve as a target for the development of drugs to combat bluetongue disease. Comparable structures detected in the core proteins of single-stranded RNA viruses from both plants and animals suggest that these viruses and BTV had a common origin.     

Crystal structure of the human natural killer cell inhibitory receptor KIR2DL1-HLA-Cw4 complex

Inhibitory natural killer (NK) cell receptors down-regulate the cytotoxicity of NK cells upon recognition of specific class I major histocompatibility complex (MHC) molecules on target cells. We report here the crystal structure of the inhibitory human killer cell immunoglobulin-like receptor 2DL1 (KIR2DL1) bound to its class I MHC ligand, HLA-Cw4. The KIR2DL1-HLA-Cw4 interface exhibits charge and shape complementarity. Specificity is mediated by a pocket in KIR2DL1 that hosts the Lys80 residue of HLA-Cw4. Many residues conserved in HLA-C and in KIR2DL receptors make different interactions in KIR2DL1-HLA-Cw4 and in a previously reported KIR2DL2-HLA-Cw3 complex. A dimeric aggregate of KIR-HLA-C complexes was observed in one KIR2DL1-HLA-Cw4 crystal. Most of the amino acids that differ between human and chimpanzee KIRs with HLA-C specificities form solvent-accessible clusters outside the KIR-HLA interface, which suggests undiscovered interactions by KIRs.     

Nucleotide sequences of genome segments S6, S7 and S10 of Dendrolimus punctatus cypovirus 1

The nucleotide sequences of genome segments S6, S7 and S10 of Dendrolimus punctatus cypovirus 1 Hunan I (DpCPV-HN(I)) and DpCPV-HN(I)-Se(3) (DpCPV-HN(I) passed three times in Spodoptera exigua) were determined. Segment S10 was 944 nucleotides in length and encoded a polyhedrin of 248 amino acids (28,439 Da). Only two nucleotide mutations were found between DpCPV-HN(I) S10 and DpCPV-HN(I)-Se3 S10, and the deduced amino acid sequences of the polyhedrin proteins were identical. Segment S7, 1 501 nucleotides, encoded a protein of 448 amino acids ( approximately 50 kDa; p50). Thirty-one nucleotide mutations were found between DpCPV-HN(I) S7 and DpCPV-HN(I)-Se3 S7, but these resulted in only four amino acid changes. DpCPV-HN(I) S6 encoded a protein of 561 amino acids (63,688 Da; p64). The amino acid sequence of p64, had a high leucine content (10%), and contained a leucine zipper motif and one ATP/GTP-binding site motif.     

Conserved structures among the nucleocapsid proteins of the paramyxoviridae: complete nucleotide sequence of human parainfluenza virus type 3 NP mRNA

The nucleotide sequence of the mRNA coding for the nucleocapsid protein (NP) of the paramyxovirus, human parainfluenza virus type 3 (PIV-3), has been determined. The NP mRNA was found to contain 1642 bases, excluding poly(A), and encode a protein of 515 amino acids, with a molecular weight of 57,823. Amino acid residues 1 through 420 of PIV-3 NP protein showed extensive sequence homology with the corresponding amino acids of Sendai virus nucleocapsid protein. There was virtually no homology between the last 95 amino acids. Comparison of the NP proteins of PIV-3, Sendai virus, measles virus, and canine distemper virus revealed, from amino acid residues 160 through 390, some conserved areas between the corresponding proteins of these paramyxoviruses. The 5' terminal sequence of PIV-3 NP mRNA (5'-AGGATTAAAG-3') was similar to the conserved sequence (formula; see text) found at the 5' termini of Sendai virus mRNAs. Both PIV-3 NP and Sendai virus mRNAs had a common 3' terminal tetranucleotide (5'-TAAG-3') preceding the poly (A) tail.     

Extended cleavage specificity of mMCP-1, the major mucosal mast cell protease in mouse-high specificity indicates high substrate selectivity

Mucosal mast cells are in the mouse predominantly found in the epithelium of the gastrointestinal tract. They express the beta-chymases mMCP-1 and mMCP-2. During nematode infections these intraepithelial mast cells increase in numbers and high amounts of mMCP-1 appear in the jejunal lumen and in the circulation. A targeted deletion of this enzyme leads to decreased ability to expel the intraepithelial nematode Trichinella spiralis. A suggested role for mMCP-1 is alteration of epithelial permeability by direct or indirect degradation of epithelial and endothelial targets, however, no such substrates have yet been identified. To enable a screening for natural substrates we performed a detailed analysis of the extended cleavage specificity of mMCP-1, using substrate phage display technology. In positions P1 and P1' distinct preferences for Phe and Ser, respectively, were observed. In position P2 a high selectivity for large hydrophobic amino acids Phe, Trp and Leu was detected, and in position P2' aliphatic amino acids Leu, Val and Ala was preferred. In positions P3 and P4, N-terminal of the cleaved bond, mMCP-1 showed specificity for aliphatic amino acids. The high selectivity in the P2, P1, P1' and P2' positions indicate that mMCP-1 has a relatively narrow set of in vivo substrates. The consensus sequence was used to screen the mouse protein database for potential substrates. A number of mouse extracellular or membrane proteins were identified and cell adhesion and connective tissue components were a dominating subfamily. This information, including the exact position of potential cleavage sites, can now be used in a more focused screening to identify which of these target molecules is/are responsible for the increased intestinal permeability observed in parasite infected mice.     

The P2/P2′ sites affect the substrate cleavage of TNF-α converting enzyme (TACE)

Tumor necrosis factor-alpha converting enzyme (TACE) is a proteinase that releases over eighty soluble proteins from their membrane-bound forms, and it has long been an intriguing therapeutic target in auto-immune diseases, and recently, in cancers. However, a haunting question is how TACE recognizes its substrates. In this work, we applied computational and experimental methods to study the role of the P2 site and the P2′ site of the substrate peptide in the substrate cleavage of TACE. In the computational complex model, the sidechains of these residues do not form key interactions with TACE, but experimentally, the mutations at these two positions largely affect the peptide cleavage efficiency in the enzymatic assay. We then showed that the P2/P2′ sites could affect the efficiency of the conformation search for the correct peptide orientation, which in turn affects the substrate cleavage efficiency. Our result provides new information to the better understanding of the enzymatic mechanism of TACE, and could be useful in the design of novel TACE inhibitors.