Active-Site Specificity of Digestive Aspartic Peptidases from the Four Species of <i>Plasmodium</i> that Infect Humans Using Chromogenic Combinatorial Peptide Libraries

Beyer, Brian M.; Johnson, Jodie V.; Chung, Alfred; Li, Tang; Madabushi, Amrita; Agbandje‐McKenna, Mavis; McKenna, Robert; Dame, John B.; Dunn, Ben M.

doi:10.1021/bi047886u

Cited by 37 publications

(56 citation statements)

References 43 publications

(83 reference statements)

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“…For the other malarial enzymes, the K i values for the F2A mutant were no more than 3-fold higher or lower than wild-type. Current structural and substrate studies are consistent with the results of the F2A mutant (35). The structure of the uncomplexed PfPM2 revealed that the active site of PfPM2 is larger than commonly assumed based on structures of the enzyme in complex with inhibitors (36).…”

Section: N-terminal Mutationssupporting

confidence: 76%

Analysis of Binding Interactions of Pepsin Inhibitor-3 To Mammalian and Malarial Aspartic Proteases

et al. 2007

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The nematode Ascaris suum primarily infects pigs, but also causes disease in humans. As part of its survival mechanism in the intestinal tract of the host, the worm produces a number of protease inhibitors, including pepsin inhibitor-3 (PI3), a 17 kDa protein. Recombinant PI3 expressed in E. coli has previously been shown to be a competitive inhibitor of a sub-group of aspartic proteinases: pepsin, gastricsin and cathepsin E. The previously determined crystal structure of the complex of PI3 with porcine pepsin (p. pepsin) showed that there are two regions of contact between PI3 and the enzyme. The first three N-terminal residues (QFL) bind into the prime side of the active site cleft and a polyproline helix (139)(140) in the C-terminal domain of PI3 packs against residues 289-295 that form a loop in p. pepsin. Mutational analysis of both inhibitor regions was conducted to assess their contributions to the binding affinity for p. pepsin, human pepsin (h. pepsin) and several malarial aspartic proteases, the plasmepsins. Overall, the polyproline mutations have a limited influence on the K i values for all the enzymes tested, with the values for p. pepsin remaining in the low nanomolar range. The largest effect was seen with a Q1L mutant, with a 200-fold decrease in K i for plasmepsin 2 from Plasmodium falciparum (PfPM2). Thermodynamic measurements of the binding of PI3 to p. pepsin and PfPM2 showed that inhibition of the enzymes is an entropy-driven reaction. Further analysis of the Q1L mutant showed that the increase in binding affinity to PfPM2 was due to improvements in both entropy and enthalpy.There are over 300 million cases of malaria every year, resulting in at least one million deaths annually (World Health Organization, 2006). Malaria is found in tropical and sub-tropical regions of the world and is caused by one of four species of the plasmodium parasite: P. falciparum, P. vivax, P. ovale, and P. malariae. P. falciparum is the deadliest of the four species and P. vivax is the most common, responsible for 40% to 50% of cases in Latin America and Asia.During the intraerythrocytic stage of the plasmodium parasite's lifecycle in the human host, up to 75% of host cell hemoglobin is degraded (1). In P. falciparum several proteases have been identified in the food vacuole that are involved in hemoglobin degradation, including a family of aspartic proteases known as the plasmepsins (2,3). The four plasmepsins found in the food vacuole of P. falciparum are PfPM1, PfPM2, PfPM4, and the histoaspartic protease (HAP) (3,4). It is now believed that the enzymes from P. vivax (PvPM4), P. ovale (PoPM4), and P. malariae (PmPM4) are orthologs of PfPM4 (5 (3,(6)(7)(8)(9). Therefore, the PfPM4 orthologs would be excellent targets for a single drug therapy directed at all four plasmodium species (4).Most large, proteinaceous inhibitors of aspartic proteases have been isolated from plants (10)(11)(12)(13)(14)(15)(16)(17)(18)(19)(20). For this study, we have analyzed the inhibition of aspartic proteases by a 17 kD inhi...

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Section: N-terminal Mutationssupporting

confidence: 76%

Analysis of Binding Interactions of Pepsin Inhibitor-3 To Mammalian and Malarial Aspartic Proteases

et al. 2007

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“…The peptide specificity assay was described in more detail elsewhere (18). Briefly, an aliquot of each pool of the P1 and P1Ј libraries giving a total peptide concentration of ϳ100 M was used in a spectrophotometric assay.…”

Section: Methodsmentioning

confidence: 99%

Activation, Proteolytic Processing, and Peptide Specificity of Recombinant Cardosin A

Castanheira

Samyn

Sergeant

et al. 2005

Journal of Biological Chemistry

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Cardosins are model plant aspartic proteases, a group of proteases that are involved in cell death events associated with plant senescence and stress responses. They are synthesized as single-chain zymogens, and subsequent conversion into two-chain mature enzymes is a crucial step in the regulation of their activity. Here we describe the activation and proteolytic processing of recombinant procardosin A. The cleavage sites involved in this multi-step autocatalytic process were determined, some of them using a novel method for C-terminal sequence analysis. Even though the two-chain recombinant enzyme displayed similar properties as natural cardosin A, a single-chain mutant form was engineered based on the processing results and produced in Escherichia coli. Determination of its primary specificity using two combinatorial peptide libraries revealed that this mutant form behaved like the natural enzyme. The primary specificity of the enzyme closely resembles those of cathepsin D and plasmepsins, suggesting that cardosin A shares the same peptide scissile bond preferences of its vacuolar/lysosomal mammalian and protozoan homologues.Sequencing of the Arabidopsis genome unveiled over 50 genes coding for aspartic proteases of the pepsin type (1, 2). These genes have been assigned to three different categories: typical, nucellin-like, and atypical proteases (2). With the exception of the products of cnd41 (3-5) and cdr1 (6) genes, very little is known about the nucellin and the atypical subgroups. In fact, most of the knowledge acquired during the last decade relates to the typical subgroup of plant aspartic proteases and has been generated predominantly from the study of phytepsin from barley seeds and cardosins from the flowers of cardoon (7).Typical plant aspartic proteases constitute a set of enzymes that share many structural and functional features not only among them but also with some of their mammalian and microbial homologues. They display activity at acidic pH and are inhibited by pepstatin A, a natural hexapeptide from Streptomyces. Common features also include the overall three-dimensional structure of mature enzymes, the catalytic apparatus, and a conserved DT/SG motif. A distinguishing feature of typical plant aspartic proteases is the occurrence of an extra 100-amino acid-long internal segment, known as the plant-specific insert (PSI), in the sequence of their precursors. This domain displays structural and functional similarities to saposins (8, 9), sphingolipid-activating proteins from animals, and some antimicrobial peptides such as NK-lysin, granulysin, and amoebapores (10); it folds as an independent domain in the precursor form (11) and is subsequently excised to generate the mature two-chain form (7). Even though the function of PSI 1 is not yet fully elucidated, it seems to play an important role in targeting plant aspartic protease precursors to the vacuole (11,12).Little is known regarding the function of typical plant aspartic proteases. Colocalization studies with putative substrates and thei...

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“…Like these HIV-1 aspartyl protease inhibitors, most Plm I and II inhibitors mimic the tetrahedral intermediate formed during the aspartyl protease catalysis. There are several transition state analogue cores used for the design of Plm inhibitors [35,[51][52][53][54][55][56][57][58][59][60][61][62][63][64][65], but the most important include the statine core [54,56,57,64], the reversed-statine core [53,54], or a hydroxyethylamine motif (Fig. 4) [56,61,62].…”

Section: Aspartyl Proteases (Plasmepsins)mentioning

confidence: 99%

“…(4). Transition-state mimicking groups in peptidomimetic plasmepsin inhibitors: reduced amine [52,59], statine [54,56,57,64], hydroxypropylamine [51], reversed-statine [53,54], dihydroxyethylene (C-and N-duplicated) [35,55,63], norstatine [58,60,65], and hydroxyethylamine [56,61,62].…”

Section: Aspartyl Proteases (Plasmepsins)mentioning

confidence: 99%

Development of Plasmodium falciparum Protease Inhibitors in the Past Decade (2002–2012)

Pérez

Teixeira

Gomes³

et al. 2013

CMC

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New drug targets for the development of antimalarial drugs have emerged after the unveiling of the Plasmodium falciparum genome in 2002. Potential antimalarial drug targets can be broadly classified into three categories according to their function in the parasite's life cycle: (i) biosynthesis, (ii) membrane transport and signaling, and (iii) hemoglobin catabolism. The latter plays a key role, as inhibition of hemoglobin degradation impairs maturation of bloodstage malaria parasites, ultimately leading to remission or even cure of the most severe stage of the infection. Intraerythrocytic Plasmodia parasites have limited capacity to biosynthesize amino acids which are vital for their growth. Therefore, the parasites obtain those essential amino acids via degradation of host cell hemoglobin, making this a crucial process for parasite survival. Several plasmodial proteases are involved in hemoglobin catabolism, among which plasmepsins and falcipains are well-known examples. Hence, development of P. falciparum protease inhibitors is a promising approach to antimalarial chemotherapy, as highlighted by the present review which is focused on the Medicinal Chemistry research effort recorded in the past decade in this particular field.

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Active-Site Specificity of Digestive Aspartic Peptidases from the Four Species of Plasmodium that Infect Humans Using Chromogenic Combinatorial Peptide Libraries

Cited by 37 publications

References 43 publications

Analysis of Binding Interactions of Pepsin Inhibitor-3 To Mammalian and Malarial Aspartic Proteases

Analysis of Binding Interactions of Pepsin Inhibitor-3 To Mammalian and Malarial Aspartic Proteases

Activation, Proteolytic Processing, and Peptide Specificity of Recombinant Cardosin A

Development of Plasmodium falciparum Protease Inhibitors in the Past Decade (2002–2012)

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