Barry K. Ely scite author profile

Serine proteases play crucial roles in erythrocyte invasion by merozoites of the malaria parasite. Plasmodium falciparum subtilisin-like protease-1 (PfSUB-1) is synthesized during maturation of the intraerythrocytic parasite and accumulates in a set of merozoite secretory organelles, suggesting that it may play a role in host cell invasion or post-invasion events. We describe the production, purification, and characterization of recombinant PfSUB-1 and comparison with the authentic protease detectable in parasite extracts. The recombinant protease requires high levels of calcium for optimum activity and has an alkaline pH optimum. Using a series of decapeptide and protein substrates, PfSUB-1 was found to have a relaxed substrate specificity with regard to the P1 position but is unable to efficiently cleave substrates with a P1 leucine residue. Similarly, replacement of a P4 valine with alanine severely reduced cleavage efficiency, whereas its replacement with lysine abolished cleavage. In all respects investigated, the recombinant protease was indistinguishable from parasite-derived enzyme. Three-dimensional homology modeling of the PfSUB-1 catalytic domain based on an alignment with closely related bacterial subtilisins and an orthologue from the rodent malaria Plasmodium yoelii suggests that the protease has at least three potential calcium ion-binding sites, three intramolecular disulfide bridges, and a single free cysteine within the enzyme S1 pocket. A predicted highly polar S1 pocket and a hydrophobic S4 subsite are in broad agreement with the experimentally determined substrate specificity.Malaria is caused by protozoon parasites of the genus Plasmodium. In humans, the clinical disease is caused by replication of the blood stages of the parasite. The invasive blood stage form, the merozoite, recognizes and binds a circulating erythrocyte, invades it with the concomitant formation of a parasitophorous vacuole, and then undergoes mitotic replication within this vacuole. Eventual rupture of the host cell releases a new wave of merozoites to repeat the cycle. Erythrocyte invasion and a number of the macromolecular modifications associated with it are sensitive to serine protease inhibitors, and there is a large body of evidence indicating an important role for parasite serine proteases in this critical stage of the parasite life cycle (1). Several putative malarial serine protease genes have been identified, some of which are expressed in the blood stages (1), but in no case is the biological function of the respective gene product known. PfSUB-1 1 is a Plasmodium falciparum protease belonging to the subtilisin-like superfamily of serine proteases or subtilases (2). The primary structure of the PfSUB-1 putative catalytic domain (MEROPS identification number S08.012; Ref.3) defines it phylogenetically as probably belonging to a relatively small group of bacterial-like eukaryotic enzymes in the subtilisin or pyrolysin subtilase families (2, 3). PfSUB-1 is synthesized during maturation of the intracellular meroz...

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Transforming activity of polyoma virus middle-T antigen probed by site-directed mutagenesis

Oostra¹,

Harvey²,

Ely³

et al. 1983

Nature

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The ability of polyoma virus to transform cells results primarily from the action of one of the virus-coded early proteins, called middle-T antigen. Middle-T has an associated tyrosine-specific protein kinase activity that can be measured in vitro and results in the phosphorylation of middle-T itself. Almost all mutants so far tested that lack the ability to transform cells, also lack associated kinase activity. Attempts to map within middle-T the tyrosine residue(s) that are phosphorylated in vitro suggest that a likely site of phosphorylation is tyrosine 315 (refs 8-10 and unpublished results). The amino acid sequence preceding Tyr 315 includes a tract of six contiguous glutamic acid residues and bears some homology with that preceding the tyrosine phosphorylated in vivo in pp60v-src, the transforming protein of Rous sarcoma virus, and with a region in the polypeptide hormone, gastrin, preceding a tyrosine that is sulphated. Furthermore, although surprisingly large tracts of middle-T may be removed without affecting its transforming activity, mutants that lack the sequences corresponding to amino acids 311-318 inclusive are transformation defective. Because the likely site of phosphorylation, the homology with pp60v-src and gastrin and the sequence apparently required for transformation all overlap, it has generally been accepted that this region of middle-T may form part of an essential region, possibly an active site on the protein. Here we have used techniques of site-directed and site-specific mutagenesis to probe the sequence requirements in more detail. Contrary to expectation, the results obtained strongly suggest that Tyr 315 and conservation of the surrounding amino acid sequence are not essential for transformation.

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PCR-based gene synthesis as an efficient approach for expression of the A+T-rich malaria genome

Withers‐Martinez¹,

Carpenter²,

Hackett³

et al. 1999

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The A+T-rich genome of the human malaria parasite Plasmodium falciparum encodes genes of biological importance that cannot be expressed efficiently in heterologous eukaryotic systems, owing to an extremely biased codon usage and the presence of numerous cryptic polyadenylation sites. In this work we have optimized an assembly polymerase chain reaction (PCR) method for the fast and extremely accurate synthesis of a 2.1 kb Plasmodium falciparum gene (pfsub-1) encoding a subtilisin-like protease. A total of 104 oligonucleotides, designed with the aid of dedicated computer software, were assembled in a single-step PCR. The assembly was then further amplified by PCR to produce a synthetic gene which has been cloned and successfully expressed in both Pichia pastoris and recombinant baculovirus-infected High Five(TM) cells. We believe this strategy to be of special interest as it is simple, accessible and has no limitation with respect to the size of the gene to be synthesized. Used as a systematic approach for the malarial genome or any other A + T-rich organism, the method allows the rapid synthesis of a nucleotide sequence optimized for expression in the system of choice and production of sufficiently large amounts of biological material for complete molecular and structural characterization.

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Deletion loop mutagenesis: a novel method for the construction of point mutations using deletion mutants

Kalderon¹,

Oostra²,

Ely³

et al. 1982

Nucl Acids Res

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Deletion loop mutagenesis is a new, general method for site-directed mutagenesis that allows point mutations to the introduced within a sequence of DNA defined by a previously isolated deletion mutant. Wild type and deletion mutant DNA are cloned into a bacterial plasmid and each is cleaved with a different single cut restriction enzyme. Heteroduplexes are formed between the two DNAs to produce circular molecules containing a nick in each strand and a single-stranded deletion loop. The deletion loops are mutagenised using sodium bisulphite and the DNA transfected directly into a uracil repair deficient strain of Escherichia coli. Up to half of the resultant clones contain DNA produced by replication of the wild-type length strand and bear mutations exclusively within the target area. An example is given in which a deletion mutant lacking 21 nucleotides from the region coding for SV40 large-T was used. Eight of the possible nine target cytosine residues were mutagenised. The method described is specific, efficient and simple.

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Barry K. Ely

Introduction of intersubunit disulfide bonds in the membrane-distal region of the influenza hemagglutinin abolishes membrane fusion activity

Expression of Recombinant Plasmodium falciparumSubtilisin-like Protease-1 in Insect Cells

Transforming activity of polyoma virus middle-T antigen probed by site-directed mutagenesis

PCR-based gene synthesis as an efficient approach for expression of the A+T-rich malaria genome

Deletion loop mutagenesis: a novel method for the construction of point mutations using deletion mutants

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