Molecular Identification of a Malaria Merozoite Surface Sheddase

Harris, Philippa K; Yeoh, Sharon; Dluzewski, Anton R.; O’Donnell, Rachel; Withers‐Martinez, Chrislaine; Hackett, Fiona; Bannister, L. H.; Mitchell, G. H.; Blackman, Michael J.

doi:10.1371/journal.ppat.0010029

Cited by 194 publications

(281 citation statements)

References 71 publications

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“…SUB1 executes the specific processing of proteins involved in the egress of Plasmodium merozoites (Mz) from host hepatocytes or erythrocytes 11,14 , as well as Mz protein surface maturation 15 . SUB2 carries out processing of proteins involved in Mz invasion into erythrocytes 8,16 . This key multi-step process is considered the Achille's heal of the parasite life cycle and a promising vaccine and/or drug target 17 .…”

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A novel Plasmodium-specific prodomain fold regulates the malaria drug target SUB1 subtilase

et al. 2014

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The Plasmodium subtilase SUB1 plays a pivotal role during the egress of malaria parasites from host hepatocytes and erythrocytes. Here we report the crystal structure of full-length SUB1 from the human-infecting parasite Plasmodium vivax, revealing a bacterial-like catalytic domain in complex with a Plasmodium-specific prodomain. The latter displays a novel architecture with an amino-terminal insertion that functions as a 'belt', embracing the catalytic domain to further stabilize the quaternary structure of the pre-protease, and undergoes calcium-dependent autoprocessing during subsequent activation. Although dispensable for recombinant enzymatic activity, the SUB1 'belt' could not be deleted in Plasmodium berghei, suggesting an essential role of this domain for parasite development in vivo. The SUB1 structure not only provides a valuable platform to develop new anti-malarial candidates against this promising drug target, but also defines the Plasmodium-specific 'belt' domain as a key calcium-dependent regulator of SUB1 during parasite egress from host cells.

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A novel Plasmodium-specific prodomain fold regulates the malaria drug target SUB1 subtilase

et al. 2014

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“…Upon schizont rupture PfAMA1 66 (but not its PfAMA1 83 precursor) is released from the micronemes to distribute across the surface of the free merozoite (38,39). At or around the point of invasion the molecule is then quantitatively shed by a membrane-bound subtilisin-like "sheddase" called PfSUB2, which translocates across the parasite surface, possibly in association with the moving junction (40,41). Shedding is mediated by a single cleavage just 29 residues distal to the transmembrane domain, resulting in release of essentially the entire AMA1 ectodomain in the form of a 48-kDa polypeptide called PfAMA1 48 ; an additional low level processing event within this molecule generates two disulfide-linked fragments, the larger of which is called PfAMA1 44 (41).…”

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Fine Mapping of an Epitope Recognized by an Invasion-inhibitory Monoclonal Antibody on the Malaria Vaccine Candidate Apical Membrane Antigen 1

Collins¹,

Withers‐Martinez²,

Bentley

et al. 2007

Journal of Biological Chemistry

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Antibodies that inhibit red blood cell invasion by the Plasmodium merozoite block the erythrocytic cycle responsible for clinical malaria. The invasion-inhibitory monoclonal antibody (mAb) 4G2 recognizes a conserved epitope in the ectodomain of the essential Plasmodium falciparum microneme protein and vaccine candidate, apical membrane antigen 1 (PfAMA1). Here we demonstrate that purified Fab fragments of 4G2 inhibit invasion markedly more efficiently than the intact mAb, suggesting that the invasion-inhibitory activity of this mAb is not due solely to steric effects and that the epitope lies within a functionally critical region of the molecule. We have taken advantage of a synthetic gene encoding a modified form of PfAMA1, and existing x-ray crystal structure data, to fully characterize this epitope. We first validate the gene by demonstrating that it fully complements the function of the authentic gene in P. falciparum. We then use it to identify a group of residues within the previously described domain II loop of PfAMA1 that are critical for recognition by mAb 4G2 and demonstrate that the epitope lies exclusively within this loop with no contributions from residues in other domains of the molecule. This is the first complete characterization of a conserved invasion-inhibitory epitope on PfAMA1. Our results will aid in the design of subunit vaccines designed to generate a broadly effective, focused anti-PfAMA1 protective immune response and may help elucidate the function of PfAMA1.Over half of the world's population is exposed to malaria (1). Until recently, the disease was controlled in or eradicated from a number of areas. However, the emergence of insecticide-resistant mosquito vectors and multidrug-resistant forms of the causative agent has contributed to resurgences of the disease, which in some cases have resulted in near catastrophic epidemics. As a result malaria remains a global problem, affecting many of the poorest nations and representing a serious threat to travelers. The development and implementation of effective new drugs and a vaccine is of paramount importance.Clinical malaria results from replication of protozoan parasites of the genus Plasmodium in circulating erythrocytes. Like most apicomplexan pathogens, the malaria merozoite invades its host cell in a multistep process initiated by reversible binding to receptors on the erythrocyte surface, followed by high affinity attachment via the apical end of the merozoite, and finally entry into a parasitophorous vacuole. Invasion is facilitated by the discharge of apical secretory organelles called micronemes and rhoptries. The type I integral membrane microneme protein apical membrane antigen 1 (AMA1) 2 is widely regarded as a leading candidate for inclusion in a malaria vaccine (2-5). Identified initially in the simian malaria species Plasmodium knowlesi as a target of a monoclonal antibody (mAb) that prevented erythrocyte invasion (6), homologues of AMA1 have been identified in all species of Plasmodium (6 -13) and in all other apicomplexa...

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“…MSP1 is a GPI anchored 190kDa glycoprotein that is cleaved into several polypeptides that non-covalently associate with each other [15,16]. The 42 kDa C-terminal domain of MSP1 is a substrate for PfSUB2 [17], a serine protease that may be similar to the furin-like serine protease that cleaves gp40/15 [11]. Cleavage of the 42kDa fragment is necessary for merozoite invasion into erythrocytes [18].…”

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confidence: 99%

Cryptosporidium parvum glycoprotein gp40 localizes to the sporozoite surface by association with gp15

O’Connor

Wanyiri

Cevallos

et al. 2007

Molecular and Biochemical Parasitology

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Cryptosporidium spp. are ubiquitous waterborne parasites responsible for outbreaks of diarrheal disease worldwide [1]. The infection is self-limiting in immunocompetent individuals, but in immunocompromised individuals the infection can develop into a chronic, debilitating, and sometimes life-threatening disease [2]. In malnourished children, cryptosporidiosis is associated with growth and developmental delays [1]. Currently, there are no vaccines to prevent cryptosporidiosis, and nitazoxanide, the only approved drug in the US [3] is not effective in AIDS patients [4]. Because the parasite cannot be propagated in vitro or genetically manipulated, data that would permit targeted drug design or vaccine development are sorely lacking.Ingested Cryptosporidium oocysts excyst in the intestine, releasing sporozoites that attach to and invade intestinal epithelial cells, initiating the lifecycle [5]. The parasite undergoes two rounds of asexual reproduction, in each cycle producing merozoites that invade new epithelial cells, before entering the sexual cycle and producing oocysts. One research focus has been to identify the antigens on the invasive zoite stages that allow the parasite to attach to and invade the epithelial cell with the goal of preventing these parasite-host cell interactions. The best characterized of the zoite antigens is Cpgp40/15, (also called Cp17, gp15/45/60 or S60) [6][7][8][9][10], a mucin like glycoprotein antigen that is synthesized as a single precursor protein and proteolytically cleaved into the mature glycoproteins, gp40 and gp15 [11]. gp15 is anchored in the sporozoite membrane by a glycosylphosphatidyl inositol (GPI) moiety [12], while the gp40 glycoprotein does not contain any predicted transmembrane domains or GPI anchors and is predicted to be soluble [7]. However, gp40 has been shown to bind intestinal epithelial cells in a dose dependent and saturable manner [7] suggesting that this antigen recognizes a host cell receptor. If this interaction is important for zoite attachment and invasion, then gp40 must have some mechanism of associating with the parasite membrane. In these studies we explore the possibility that gp40 and gp15 associate to form a protein complex capable of linking zoite and host cell surfaces.* Corresponding Authors NEMC Box 041, 750 Washington St, Boston, MA 02111, e-mail: roconnor@tufts-nemc.org; hward@tufts-nemc.org, tel ROC: 617 636 2684, HW: 617 636 7022, fax: 617 636 5292. Publisher's Disclaimer: This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. To generate gp40 specific antiserum, recombinant (r)gp40 fusion protein [7] was purified via the His...

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Molecular Identification of a Malaria Merozoite Surface Sheddase

Cited by 194 publications

References 71 publications

A novel Plasmodium-specific prodomain fold regulates the malaria drug target SUB1 subtilase

A novel Plasmodium-specific prodomain fold regulates the malaria drug target SUB1 subtilase

Fine Mapping of an Epitope Recognized by an Invasion-inhibitory Monoclonal Antibody on the Malaria Vaccine Candidate Apical Membrane Antigen 1

Cryptosporidium parvum glycoprotein gp40 localizes to the sporozoite surface by association with gp15

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