The construction and characterization of two xylan-degrading chimeric enzymes

Degradation of xylan requires several enzymes. Two chimeric enzymes, xyln-ara and xyln-xylo, were constructed by linking the catalytic portion of a xylanase (xyln) to either an arabinofuranosidase (ara) or a xylosidase (xylo) with a flexible peptide linker. The recombinant parental enzymes and chimeras were produced in E. coli at high levels and purified for characterization of their enzymatic and kinetic properties as well as activities on natural substrates. The chimeras closely resemble the parental enzymes or their mixtures with regard to protein properties. They share similar temperature profiles and have similar catalytic efficiencies as the parental enzymes when assayed using substrates 4-nitrophenyl-alpha-L-arabinofuranoside or 2-nitrophenyl- beta-D-xylopyranoside. The chimeras also show unique enzymatic characteristics. In xylanase activity assays using Remazol Brilliant Blue-xylan, while the parental xylanase has a pH optimum of pH 8, the chimeras showed shifted pH optima as a consequence of significantly increased activity at pH 6 (the optimal pH for ara and xylo). Both chimeras exhibited additive effects of the parental enzymes when assayed at wide ranges of pH and temperatures. The xyln-xylo chimera had the same activities as the xyln/xylo mixture in hydrolyzing the natural substrates oat spelt xylan and wheat arabinoxylan. Compared to the xyln/ara mixture, the xyln-ara chimera released the same amounts of xylose from oat spelt xylan and approximately 30% more from wheat arabinoxylan at pH 6. Our results demonstrate the feasibility and advantages of generating bifunctional enzymes for the improvement of xylan bioconversion.     

Domain exchange between isoforms of ferredoxin-NADP+ reductase produces a functional enzyme

Two isoforms of ferredoxin-NADP(+) reductase (FNR) exist in higher plants, the leaf (or photosynthetic) and the root (or non-photosynthetic) isoform, which have 48% amino acid sequence identity and display specific structural and functional features. With the aim to gain further insight into the structure-function relationship of this enzyme, we designed two novel chimeric flavoenzymes by swapping the structural domains between the leaf and the root isoforms. Characterization of the chimeras would allow dissection of the contribution of the individual domains to catalysis. The chimera obtained by grafting together the FAD-binding domain of the root-isoform and the NADP-binding domain of the leaf-isoform was inactive when expressed in Escherichia coli. On the other hand, the chimera assembled in the opposite way (leaf FAD-binding domain and root NADP-binding domain) was functional and was produced in the bacterial host to a level threefold higher than that of the parent enzymes. The protein was purified and found to be as stable as the natural isoforms. Limited proteolysis excluded the presence in the chimera of misfolded regions. The affinity of the chimera for ferredoxin I (Fd I) was similar to that of the leaf isoform, although interprotein electron-transfer was partially impaired. As occurs with the root isoform, the chimera bound NADP(+) with high affinity, while spectroscopic evidence suggested that the conformation adopted by the nicotinamide moiety bound to the chimera was similar to that observed in the leaf enzyme. Interestingly, the chimera, by combining favorable features from both parent isoforms, acquired a catalytic efficiency (k(cat)/K(m)), as an NADPH-dependent diaphorase, higher than those of both the root ( approximately 2-fold) and the leaf enzyme ( approximately 5-fold). Thus, molecular breeding between isozymes has improved the catalytic properties of FNR.     

Catalytically functional flavocytochrome chimeras of P450 BM3 and nitric oxide synthase

P450 BM3 and the nitric oxide synthases are related classes of flavocytochrome mono-oxygenase enzymes, containing NADPH-dependent FAD- and FMN-containing oxidoreductase modules fused to heme b-containing oxygenase domains. Domain-swap hybrids of these two multi-domain enzymes were created by genetic engineering of different segments of reductase and heme domains from neuronal nitric oxide synthase and P450 BM3, as a means of investigating the catalytic competence and substrate-binding properties of the fusions and the influence of tetrahydrpbiopterin and calmodulin binding regions on the electron transfer kinetics of the chimeras. Despite marked differences in hybrid stability and solubility, four catalytically functional chimeras were created that retained good reductase activity and which could be expressed successfully in Escherichia coli and purified. All of the BM3 reductase domain chimeras (chimeras I-III) exhibited inefficient flavin-to-heme inter-domain electron transfer, diminishing their oxygenase activity. However, the chimera containing the neuronal nitric oxide synthase reductase domain (chimera IV) showed good oxygenase domain activity, indicating that the flavin-to-heme electron transfer reaction is relatively efficient in this case. The data reinforce the importance of the nature of inter-domain linker constitution in multi-domain enzymes, and the difficulties posed in attempts to create chimeric enzymes with enhanced catalytic properties.     

Defining requirements for collagenase cleavage in collagen type III using a bacterial collagen system

Degradation of fibrillar collagens is important in many physiological and pathological events. These collagens are resistant to most proteases due to the tightly packed triple-helical structure, but are readily cleaved at a specific site by collagenases, selected members of the matrix metalloproteinases (MMPs). To investigate the structural requirements for collagenolysis, varying numbers of GXY triplets from human type III collagen around the collagenase cleavage site were inserted between two triple helix domains of the Scl2 bacterial collagen protein. The original bacterial CL domain was not cleaved by MMP-1 (collagenase 1) or MMP-13 (collagenase 3). The minimum type III sequence necessary for cleavage by the two collagenases was 5 GXY triplets, including 4 residues before and 11 residues after the cleavage site (P4-P11'). Cleavage of these chimeric substrates was not achieved by the catalytic domain of MMP-1 or MMP-13, nor by full-length MMP-3. Kinetic analysis of the chimeras indicated that the rate of cleavage by MMP-1 of the chimera containing six triplets (P7-P11') of collagen III was similar to that of native collagen III. The collagenase-susceptible chimeras were cleaved very slowly by trypsin, a property also seen for native collagen III, supporting a local structural relaxation of the triple helix near the collagenase cleavage site. The recombinant bacterial-human collagen system characterized here is a good model to investigate the specificity and mechanism of action of collagenases.     

Domain exchange between isoforms of ferredoxin-NADP+ reductase produces a functional enzyme

Two isoforms of ferredoxin-NADP⁺ reductase (FNR) exist in higher plants, the leaf (or photosynthetic) and the root (or non-photosynthetic) isoform, which have 48% amino acid sequence identity and display specific structural and functional features. With the aim to gain further insight into the structure–function relationship of this enzyme, we designed two novel chimeric flavoenzymes by swapping the structural domains between the leaf and the root isoforms. Characterization of the chimeras would allow dissection of the contribution of the individual domains to catalysis. The chimera obtained by grafting together the FAD-binding domain of the root-isoform and the NADP-binding domain of the leaf-isoform was inactive when expressed in Escherichia coli. On the other hand, the chimera assembled in the opposite way (leaf FAD-binding domain and root NADP-binding domain) was functional and was produced in the bacterial host to a level threefold higher than that of the parent enzymes. The protein was purified and found to be as stable as the natural isoforms. Limited proteolysis excluded the presence in the chimera of misfolded regions. The affinity of the chimera for ferredoxin I (Fd I) was similar to that of the leaf isoform, although interprotein electron-transfer was partially impaired. As occurs with the root isoform, the chimera bound NADP⁺ with high affinity, while spectroscopic evidence suggested that the conformation adopted by the nicotinamide moiety bound to the chimera was similar to that observed in the leaf enzyme. Interestingly, the chimera, by combining favorable features from both parent isoforms, acquired a catalytic efficiency (k_cat/K_m), as an NADPH-dependent diaphorase, higher than those of both the root (～2-fold) and the leaf enzyme (～5-fold). Thus, molecular breeding between isozymes has improved the catalytic properties of FNR.     

Chimeric aspartic proteinases and active site binding

Two chimeric enzymes were constructed by exchanging domains between porcine pepsinogen and rhizopuspepsinogen in order to examine the contributions of the subsites present on different domains toward enzymatic specificity. Both chimeras exhibited the characteristic features of aspartic proteinases, such as auto-activation at low pH and abrogation of enzymatic activity by pepstatin. The activity of the chimera containing the N-terminal domain of rhizopuspepsinogen and the C-terminal domain of porcine pepsinogen (rhzNppC) could be observed by HPLC after prolonged incubation with the substrates. In contrast, the reciprocal chimera, ppNrhzC, containing the N-terminal domain of porcine pepsinogen and the C-terminal domain of rhizopuspepsinogen exhibited catalytic activity, measurable by a spectrophotometric assay. Kinetic data and inhibitor analyses strongly suggest that interdependency may exist between adjacent subsites contributed by different domains. Therefore, in order to develop an optimal substrate or inhibitor, the effect of adjacent residues of the ligand has to be examined along with the preferences for each subsite.     

Structural Basis for Dimerization and Catalysis of a Novel Esterase from the GTSAG Motif Subfamily of the Bacterial Hormone-sensitive Lipase Family

Hormone-sensitive lipases (HSLs) are widely distributed in microorganisms, plants, and animals. Microbial HSLs are classified into two subfamilies, an unnamed new subfamily and the GDSAG motif subfamily. Due to the lack of structural information, the detailed catalytic mechanism of the new subfamily is not yet clarified. Based on sequence analysis, we propose to name the new subfamily as the GTSAG motif subfamily. We identified a novel HSL esterase E25, a member of the GTSAG motif subfamily, by functional metagenomic screening, and resolved its structure at 2.05 Å. E25 is mesophilic (optimum temperature at 50 °C), salt-tolerant, slightly alkaline (optimum pH at 8.5) for its activity, and capable of hydrolyzing short chain monoesters (C2–C10). E25 tends to form dimers both in the crystal and in solution. An E25 monomer contains an N-terminal CAP domain, and a classical α/β hydrolase-fold domain. Residues Ser¹⁸⁶, Asp²⁸², and His³¹² comprise the catalytic triad. Structural and mutational analyses indicated that E25 adopts a dimerization pattern distinct from other HSLs. E25 dimer is mainly stabilized by an N-terminal loop intersection from the CAP domains and hydrogen bonds and salt bridges involving seven highly conserved hydrophilic residues from the catalytic domains. Further analysis indicated that E25 also has some catalytic profiles different from other HSLs. Dimerization is essential for E25 to exert its catalytic activity by keeping the accurate orientation of the catalytic Asp²⁸² within the catalytic triad. Our results reveal the structural basis for dimerization and catalysis of an esterase from the GTSAG motif subfamily of the HSL family.     

Engineering of a multifunctional hemicellulase

To engineer a multifunctional xylan-degrading enzyme, a chimera was created by fusing the xylanase domain of the Clostridium thermocellum xylanase (xynZ) and a dual functional arabinofuranosidase/xylosidase (DeAFc; from a compost starter mixture) through a flexible peptide linker. The xylanase domain of xynZ possesses previously unreported endoglucanase activity. The chimera, possessing the activities of xylanase, endoglucanase, arabinofuranosidase and xylosidase, was expressed in E. coli and purified. The chimera closely resembled the parental enzymes in pH, temperature optima and kinetics, and was more active than the parental enzyme mixture in the hydrolysis of natural xylans and corn stover. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Domain exchange: chimeras of Thermus aquaticus DNA polymerase, Escherichia coli DNA polymerase I and Thermotoga neapolitana DNA polymerase

The intervening domain of the thermostable Thermus aquaticus DNA polymerase (TAQ: polymerase), which has no catalytic activity, has been exchanged for the 3'-5' exonuclease domain of the homologous mesophile Escherichia coli DNA polymerase I (E.coli pol I) and the homologous thermostable Thermotoga neapolitana DNA polymerase (TNE: polymerase). Three chimeric DNA polymerases have been constructed using the three-dimensional (3D) structure of the Klenow fragment of the E.coli pol I and 3D models of the intervening and polymerase domains of the TAQ: polymerase and the TNE: polymerase: chimera TaqEc1 (exchange of residues 292-423 from TAQ: polymerase for residues 327-519 of E.coli pol I), chimera TaqTne1 (exchange of residues 292-423 of TAQ: polymerase for residues 295-485 of TNE: polymerase) and chimera TaqTne2 (exchange of residues 292-448 of TAQ: polymerase for residues 295-510 of TNE: polymerase). The chimera TaqEc1 showed characteristics from both parental polymerases at an intermediate temperature of 50 degrees C: high polymerase activity, processivity, 3'-5' exonuclease activity and proof-reading function. In comparison, the chimeras TaqTne1 and TaqTne2 showed no significant 3'-5' exonuclease activity and no proof-reading function. The chimera TaqTne1 showed an optimum temperature at 60 degrees C, decreased polymerase activity compared with the TAQ: polymerase and reduced processivity. The chimera TaqTne2 showed high polymerase activity at 72 degrees C, processivity and less reduced thermostability compared with the chimera TaqTne1.     

The catalytic properties of Thermus thermophilus SG0.5JP17-16 laccase were regulated by the conformational dynamics of pocket loop 6

BackgroundLaccase is one member of the blue multicopper oxidase family. It can catalyze the oxidation of various substrates. The Thermus thermophilus SG0.5JP17-16 laccase (lacTT) is thermostable, pH-stable, and high tolerance to halides, and can decolorize the synthetic dyes. In lacTT, the function of the loop 6 constructing the substrate-binding pocket wasn't clear.MethodsThe residues Asp394 and Asp396 located in loop 6, and were used to probe how the loop 6 influenced catalytic properties of the laccase. Site-directed mutagenesis was performed for two amino acids. Kinetic assay was utilized to characterize the catalytic efficiency of mutants. Mutants with different catalytic activities were used to decolorize the synthetic dyes to clarify the relationship between the catalytic efficiency and dye decolorization. Redox potential, structural and spectral analyses were performed to explain the differences in laccase activity between wild type and mutant enzymes.ResultsD394M, D394E and D394R mutants with the lower laccase activity displayed a decreased decolorization efficiency, while D396A, D396M and D396E mutant enzymes with higher catalytic efficiency decolorized the synthetic dye more efficiently than the wild type enzyme.ConclusionsThe pocket loop 6 might experience a conformational dynamics. The D394 residue controlled this conformation change by amino acid interaction networks containing the D396 residue at the entrance of substrate channel.General significancesThese studies may provide clues to improve the activity of the laccase for the better use in industrial applications, and/or contribute to further understanding the mechanism of laccase oxidation on the substrate.     

Construction and characterization of a bifunctional fusion enzyme of Bacillus-sourced beta-glucanase and xylanase expressed in Escherichia coli

A chimeric gene, Glu-Xyl, encoding Bacillus amyloliquefaciens glucanase (Glu, 24.4 kDa) and Bacillus subtilis xylanase (Xyl, 21.2 kDa), was constructed via end-to-end fusion and expressed successfully in Escherichia coli. The purified fusion protein (46.1 kDa) exhibited both glucanase and xylanase activities. Compared with parental enzymes, the Glu moiety was characterized by kinetic parameters of decreased K(m) (0.66-fold) and increased K(cat) (2.75-fold), whereas the Xyl moiety had an increased K(m) (1.37-fold) and decreased K(cat) (0.79-fold). These indicate a 3.15-fold net increase and a 31% decrease in catalytic efficiency (K(cat)/K(m)) of the Glu and Xyl moieties. Activities and stabilities of both moieties at 40-90 degrees C or pH 3.0-10.0 were compared with those of the parental enzymes. Despite some variations, common optima were 40 degrees C and pH 9.0 for the Glu moiety and parent, and 50-60 degrees C and pH 9.0 for the Xyl counterparts. Thus, the fusion enzyme Glu-Xyl was bifunctional, with greatly enhanced glucanase activity associated with a decrease in xylanase activity.     

Purification and characterization of T cell protein tyrosine phosphatase reveals significant functional homology to protein tyrosine phosphatase-1B

We have developed a protocol for rapid purification of T cell protein tyrosine phosphatase (TCPTP) and the structurally related protein tyrosine phosphatase-1B (PTP-1B) from bacterial cells. The pH profile for TCPTP was bell-shaped with an optimum of 5.5. The catalytic domain and full-length versions of TCPTP bound a potent inhibitor with affinities similar to those of PTP-1B. The K(m) values for the catalytic domains of TCPTP and PTP-1B increased with increasing ionic strength, whereas the k(cat) values remained unchanged. Arrhenius plots revealed that TCPTP and PTP-1B possess similar activation energies of 25.3+/-1.2 and 18.4+/-3.0 kJ/mol, respectively. Increasing solvent microviscosity (up to 40% (w/v) sucrose) did not affect k(cat)/K(m) of either enzyme. However, high sucrose concentrations protected both enzymes from thermal inactivation. These studies show that, although they share a 72% amino acid sequence identity within their catalytic domains, TCPTP and PTP-1B are functionally very similar in vitro.     

Determinants of ligand binding specificity of the alpha(1)beta(1) and alpha(2)beta(1) integrins.

The alpha(1)beta(1) and alpha(2)beta(1) integrins are cell surface collagen receptors. Cells expressing the alpha(1)beta(1) integrin preferentially adhere to collagen IV, whereas cells expressing the alpha(2)beta(1) integrin preferentially adhere to collagen I. Recombinant alpha(1) and alpha(2) integrin I domains exhibit the same collagen type preferences as the intact integrins. In addition, the alpha(2) integrin I domain binds echovirus 1; the alpha(1) I domain does not. To identify the structural components of the I domains responsible for the varying ligand specificities, we have engineered several alpha(1)/alpha(2) integrin I domain chimeras and evaluated their virus and collagen binding activities. Initially, large secondary structural components of the alpha(2) I domain were replaced with corresponding regions of the alpha(1) I domain. Following analysis in echovirus 1 and collagen binding assays, chimeras with successively smaller regions of alpha(1) I were constructed and analyzed. The chimeras were analyzed by ELISA with several different alpha(2) integrin monoclonal antibodies to assess their proper folding. Three different regions of the alpha(1) I domain, when present in the alpha(2) I domain, conferred enhanced collagen IV binding activity upon the alpha(2) I domain. These include the alpha3 and alpha5 helices and a portion of the alpha6 helix. Echovirus 1 binding was lost in a chimera containing the alphaC-alpha6 loop; higher resolution mapping identified Asn(289) as playing a critical role in echovirus 1 binding. Asn(289) had not been implicated in previous echovirus 1 binding studies. Taken together, these data reveal the existence of multiple determinants of ligand binding specificities within the alpha(1) and alpha(2) integrin I domains.     

Activin A/bone morphogenetic protein (BMP) chimeras exhibit BMP-like activity and antagonize activin and myostatin

Activins and bone morphogenetic proteins (BMPs) are members of the transforming growth factor-beta family of growth and differentiation factors that induce signaling in target cells by assembling type II and type I receptors at the cell surface. Ligand residues involved in type II binding are located predominantly in the C-terminal region that forms an extended beta-sheet, whereas residues involved in type I binding are located in the alpha-helical and preceding loop central portion of the molecule. To test whether the central residues are sufficient to determine specificity toward type I receptors, activin A/BMP chimeras were constructed in which the central residues (45-79) of activin A were replaced with corresponding residues of BMP2 and BMP7. The chimeras were assessed for activin type II receptor (Act RII) binding, activin-like bioactivity, and BMP-like activity as well as antagonistic properties toward activin A and myostatin. ActA/BMP7 chimera retained Act RII binding affinity comparable with wild type activin A, whereas ActA/BMP2 chimera showed a slightly reduced affinity toward Act RII. Both the chimeras were devoid of significant activin bioactivity in 293T cells in the A3 Lux reporter assay up to concentrations 10-fold higher than the minimal effective activin A concentration (approximately 4 nM). In contrast, these chimeras showed BMP-like activity in a BRE-Luc assay in HepG2 cells as well as induced osteoblast-like phenotype in C2C12 cells expressing alkaline phosphatase. Furthermore, both the chimeras activated Smad1 but not Smad2 in C2C12 cells. Also, both the chimeras antagonized ligands that signal via activin type II receptor, such as activin A and myostatin. These data indicate that activin residues in the central region determine its specificity toward type I receptors. ActA/BMP chimeras can be useful in the study of receptor specificities and modulation of transforming growth factor-beta members, activins, and BMPs.     

Construction of a tailor-made L (2S,3S)-butanediol dehydrogenase by exchanging domains between native structural analogs

The development of a stable L-BDH chimera was attempted by exchanging whole domains between two native structural analogs, L-BDH and meso-BDH, because the S-configuration specificity of L-BDH is valuable from the standpoint of its application but its activity is unstable, whereas meso-BDH is stable. The domain chimeras obtained indicated that the leaf-like structures constituting three domains were likely to be mainly associated with chiral recognition, and the fourth domain, the basic domain, is likely to be mainly associated with enzyme stability. A combination of the leaf domains of L-BDH and the basic domain of meso-BDH attained a sufficient level of practical use as an artificial L-BDH chimera, because the resulting enzyme had both stability and S-configuration specificity. However, the levels of stability and specificity were slightly lower than those of the respective enzymes from which they were derived.     

Improved germline transmission in chicken chimeras produced by transplantation of gonadal primordial germ cells into recipient embryos

In the avian species, germline chimera production could be possible by transfer of donor germ cells into the blood vessel of recipient embryos. This study was conducted to establish an efficient transfer system of chicken gonadal primordial germ cells (gPGCs) for producing the chimeras having a high capacity of germline transmission. Gonadal PGCs retrieved from 5.5-day-old embryos (stage 28) of Korean Ogol chicken (KOC with i/i gene) were transferred into the dorsal aorta of 2.5-day-old embryos (stage 17) of White Leghorn chicken (WL with I/I gene). Prospective evaluations of whether culture duration (0, 5, or 10 days) and subsequent Ficoll separation of gPGCs before transfer affected chimera production and germline transmission in the chimeras were made while retrospective analysis was conducted for examining the effect of chimera sexuality. A testcross analysis by artificial insemination of presumptive chimeras with adult KOC was performed for evaluating each treatment effect. First, comparison was made for evaluating whether experimental treatments could improve chimera production, but none of the treatments were significantly (P = 0.6831) influenced (5.1%-14.4%). Second, it was determined whether each treatment could enhance germline transmission in produced chimeras. More (P < 0.0001) progenies with black feathers (i/i) were produced in the germline chimeras derived from the transfer of 10-day-cultured gPGCs than from the transfer of 0- or 5-day-cultured gPGCs (0.6%-7.8% vs. 10.7%-49.7%). Ficoll separation was negatively affected (P < 0.0001), whereas there was no effect in chimera sexuality (P = 0.6011). In conclusion, improved germline transmission of more than a 45% transmission rate was found in chicken chimeras produced by transfer of 10-day-cultured gPGCs being separated without Ficoll treatment.     

Structure and function of an arabinoxylan-specific xylanase

The enzymatic degradation of plant cell walls plays a central role in the carbon cycle and is of increasing environmental and industrial significance. The enzymes that catalyze this process include xylanases that degrade xylan, a β-1,4-xylose polymer that is decorated with various sugars. Although xylanases efficiently hydrolyze unsubstituted xylans, these enzymes are unable to access highly decorated forms of the polysaccharide, such as arabinoxylans that contain arabinofuranose decorations. Here, we show that a Clostridium thermocellum enzyme, designated CtXyl5A, hydrolyzes arabinoxylans but does not attack unsubstituted xylans. Analysis of the reaction products generated by CtXyl5A showed that all the oligosaccharides contain an O3 arabinose linked to the reducing end xylose. The crystal structure of the catalytic module (CtGH5) of CtXyl5A, appended to a family 6 noncatalytic carbohydrate-binding module (CtCBM6), showed that CtGH5 displays a canonical (α/β)(8)-barrel fold with the substrate binding cleft running along the surface of the protein. The catalytic apparatus is housed in the center of the cleft. Adjacent to the -1 subsite is a pocket that could accommodate an l-arabinofuranose-linked α-1,3 to the active site xylose, which is likely to function as a key specificity determinant. CtCBM6, which adopts a β-sandwich fold, recognizes the termini of xylo- and gluco-configured oligosaccharides, consistent with the pocket topology displayed by the ligand-binding site. In contrast to typical modular glycoside hydrolases, there is an extensive hydrophobic interface between CtGH5 and CtCBM6, and thus the two modules cannot function as independent entities.     

Distribution and biochemical properties of an M1-family aminopeptidase in Plasmodium falciparum indicate a role in vacuolar hemoglobin catabolism

Aminopeptidases catalyze N-terminal peptide bond hydrolysis and occupy many diverse roles across all domains of life. Here we present evidence that an M1-family aminopeptidase, PfA-M1, has been recruited to specialized roles in the human malaria parasite Plasmodium falciparum. PfA-M1 is abundant in two subcellular compartments in asexual intraerythrocytic parasites; that is, the food vacuole, where the catabolism of host hemoglobin takes place, and the nucleus. A unique N-terminal extension contributes to the observed dual targeting by providing a signal peptide and putative alternate translation initiation sites. PfA-M1 exists as two major isoforms, a nuclear 120-kDa species and a processed species consisting of a complex of 68- and 35-kDa fragments. PfA-M1 is both stable and active at the acidic pH of the food vacuole lumen. Determination of steady-state kinetic parameters for both aminoacyl-β-naphthylamide and unmodified dipeptide substrates over the pH range 5.0-8.5 reveals that k(cat) is relatively insensitive to pH, whereas K(m) increases at pH values below 6.5. At the pH of the food vacuole lumen (5.0-5.5), the catalytic efficiency of PfA-M1 remains high. Consistent with the kinetic data, the affinity of peptidic competitive inhibitors is diminished at acidic pH. Together, these results support a catalytic role for PfA-M1 in the food vacuole and indicate the importance of evaluating the potency of peptidic inhibitors at physiologically relevant pH values. They also suggest a second, distinct function for this enzyme in the parasite nucleus.