Molecular determinants of binding to the Plasmodium subtilisin-like protease 1.

PfSUB1, a subtilisin-like protease of the human malaria parasite Plasmodium falciparum, is known to play important roles during the life cycle of the parasite and has emerged as a promising antimalarial drug target. In order to provide a detailed understanding of the origin of binding determinants of PfSUB1 substrates, we performed molecular dynamics simulations in combination with MM-GBSA free energy calculations using a homology model of PfSUB1 in complex with different substrate peptides. Key interactions, as well as residues that potentially make a major contribution to the binding free energy, are identified at the prime and nonprime side of the scissile bond and comprise peptide residues P4 to P2'. This finding stresses the requirement for peptide substrates to interact with both prime and nonprime side residues of the PfSUB1 binding site. Analyzing the energetic contributions of individual amino acids within the peptide-PfSUB1 complexes indicated that van der Waals interactions and the nonpolar part of solvation energy dictate the binding strength of the peptides and that the most favorable interactions are formed by peptide residues P4 and P1. Hot spot residues identified in PfSUB1 are dispersed over the entire binding site, but clustered areas of hot spots also exist and suggest that either the S4-S2 or the S1-S2' binding site should be exploited in efforts to design small molecule inhibitors. The results are discussed with respect to which binding determinants are specific to PfSUB1 and, therefore, might allow binding selectivity to be obtained

Molecular determinants for subcellular trafficking of the malarial sheddase PfSUB2.

The malaria merozoite invades erythrocytes in the vertebrate host. Iterative rounds of asexual intraerythrocytic replication result in disease. Proteases play pivotal roles in erythrocyte invasion, but little is understood about their mode of action. The Plasmodium falciparum malaria merozoite surface sheddase, PfSUB2, is one such poorly characterized example. We have examined the molecular determinants that underlie the mechanisms by which PfSUB2 is trafficked initially to invasion-associated apical organelles (micronemes) and then across the surface of the free merozoite. We show that authentic promoter activity is important for correct localization of PfSUB2, likely requiring canonical features within the intergenic region 5' of the pfsub2 locus. We further demonstrate that trafficking of PfSUB2 beyond an early compartment in the secretory pathway requires autocatalytic protease activity. Finally, we show that the PfSUB2 transmembrane domain is required for microneme targeting, while the cytoplasmic domain is essential for surface translocation of the protease to the parasite posterior following discharge from micronemes. The interplay of pre- and post-translational regulatory elements that coordinate subcellular trafficking of PfSUB2 provides the parasite with exquisite control over enzyme-substrate interactions

The malaria parasite egress protease SUB1 is a calcium-dependent redox switch subtilisin.

Malaria is caused by a protozoan parasite that replicates within an intraerythrocytic parasitophorous vacuole. Release (egress) of malaria merozoites from the host erythrocyte is a highly regulated and calcium-dependent event that is critical for disease progression. Minutes before egress, an essential parasite serine protease called SUB1 is discharged into the parasitophorous vacuole, where it proteolytically processes a subset of parasite proteins that play indispensable roles in egress and invasion. Here we report the first crystallographic structure of Plasmodium falciparum SUB1 at 2.25 Å, in complex with its cognate prodomain. The structure highlights the basis of the calcium dependence of SUB1, as well as its unusual requirement for interactions with substrate residues on both prime and non-prime sides of the scissile bond. Importantly, the structure also reveals the presence of a solvent-exposed redox-sensitive disulphide bridge, unique among the subtilisin family, that likely acts as a regulator of protease activity in the parasite

Computational Reverse-Engineering of a Spider-Venom Derived Peptide Active Against Plasmodium falciparum SUB1

merozoites and invasion into erythrocytes. As PfSUB1 has emerged as an interesting drug target, we explored the hypothesis that PcFK1 targeted PfSUB1 enzymatic activity. culture in a range compatible with our bioinformatics analysis. Using contact analysis and free energy decomposition we propose that residues A14 and Q15 are important in the interaction with PfSUB1.Our computational reverse engineering supported the hypothesis that PcFK1 targeted PfSUB1, and this was confirmed by experimental evidence showing that PcFK1 inhibits PfSUB1 enzymatic activity. This outlines the usefulness of advanced bioinformatics tools to predict the function of a protein structure. The structural features of PcFK1 represent an interesting protein scaffold for future protein engineering

Comparative proteomics and functional analysis reveal a role of plasmodium falciparum osmiophilic bodies in malaria parasite transmission

An essential step in the transmission of the malaria parasite to the Anopheles vector is the transformation of the mature gametocytes into gametes in the mosquito gut, where they egress from the erythrocytes and mate to produce a zygote, which matures into a motile ookinete. Osmiophilic bodies are electron dense secretory organelles of the female gametocytes which discharge their contents during gamete formation, suggestive of a role in gamete egress. Only one protein with no functional annotation, Pfg377, is described to specifically reside in osmiophilic bodies in Plasmodium falciparum. Importantly, Pfg377 defective gametocytes lack osmiophilic bodies and fail to infect mosquitoes, as confirmed here with newly produced pfg377 disrupted parasites. The unique feature of Pfg377 defective gametocytes of lacking osmiophilic bodies was here exploited to perform comparative, label free, global and affinity proteomics analyses of mutant and wild type gametocytes to identify components of these organelles. Subcellular localization studies with fluorescent reporter gene fusions and specific antibodies revealed an osmiophilic body localization for four out of five candidate gene products analyzed: the proteases PfSUB2 (subtilisin 2) and PfDPAP2 (Dipeptidyl aminopeptidase 2), the ortholog of the osmiophilic body component of the rodent malaria gametocytes PbGEST and a previously non-annotated 13 kDa protein. These results establish that osmiophilic bodies and their components are dispensable or marginally contribute (PfDPAP2) to gamete egress. Instead, this work reveals a previously unsuspected role of these organelles in P. falciparum development in the mosquito vector

TARGETING THE ROLE OF SUBTILISIN-LIKE PROTEASE 2 FOR INHIBITION OF ERYTHROCYTE INVASION BY THE MALARIA PARASITE, PLASMODIUM

Malaria is a mosquito-harbored infectious disease causing approximately half a million deaths every year around the world. Out of the five Plasmodium species that infect humans, P. falciparum is the deadliest. Despite the relative success in decreasing malaria-related deaths through various efforts, emergence of parasite resistance against antimalarials remains a major challenge. This is mainly because the parasite develops resistance before new effective drugs can become available. In addition, there is no approved vaccine for malaria that will prevent the infection in most groups affected. The protection offered by the malaria vaccine candidate, RTS,S, currently on phase III clinical trials, is less than 40% in children when used along with bed nets and other malaria prevention recommendations. Additional vaccine candidates are needed to provide better protection against malaria. The characterization of molecular targets allows the development of inhibitors against the parasite via rational design, helping to advance the development of vaccine and treatment. Subtilisin-like protease 2 (SUB2) is the only Plasmodium subtilisin playing a direct role during invasion of the red blood cell (RBC), a critical step in malaria parasite development during the asexual, symptom-causing stages. SUB2 merozoite surface sheddase (MeSh) activity is essential for parasite survival and RBC invasion. A SUB2-specic inhibitor will lead to impairment of invasion. Additionally, SUB2 is secreted onto the surface of the parasite to access its substrates, staying exposed to the antibodies in the blood, making it a merozoite surface antigen itself and a candidate for antibody-mediated inhibition. This makes SUB2 both a potential drug target and a vaccine candidate. At the present, our understanding of SUB2 biochemistry and biophysical properties is limited and now studies have tested this subtilisin as a vaccine candidate. In this dissertation, we show that antibody-mediated inhibition results in decreased parasite infection in a proof-of-principle experiment with mice. We have also attempted to characterize the two SUB2 peptides utilized in immunization experiments by using a self-assembling protein nanoparticle on a different, but related, experiment using a mouse model of malaria. Finally, we develop an expression system for active SUB2 as well as a SUB2-specific protease assay with native SUB2 substrates

Serine protease identification (in vitro) and molecular structure predictions (in silico) from a phytopathogenic fungus, Alternaria solani

Citation: Chandrasekaran, M., Chandrasekar, R., Sa, T., & Sathiyabama, M. (2014). Serine protease identification (in vitro) and molecular structure predictions (in silico) from a phytopathogenic fungus, Alternaria solani. Retrieved from http://krex.ksu.eduSerine proteases generally share a relatively high degree of sequence identity and play a major role in the diversity of biological processes. Here we focus on three-dimensional molecular architecture of serine proteases from Alernaria solani. The difference in flexibility of active binding pockets and electrostatic surface potential distribution of serine proteases in comparison with other fungal species is reported in this study. In this study we have purified a serine protease from the early blight pathogen, Alernaria solani. MALDI-TOF-MS/MS analysis revealed that protease produced by A. solani belongs to alkaline serine proteases. AsP is made up of 403 amino acid residues with molecular weight of 42.1kDa (Isoelectric point (pI)-6.51) and molecular formula C[subscript 1859]H[subscript 2930]N[subscript 516]O[subscript 595]S[subscript 4]. The follow-up research on the molecular structure prediction is used for assessing the quality of A. solani Protease (AsP). The AsP protein structure model was built based on its comparative homology with serine protease using the program, MODELER. AsP had 16 β-sheets and 10 α-helices, with Ser[superscript 350] (G347-G357), Asp[superscript 158] (D158-H169) and His[superscript 193] (H193-G203) in separate turn/coil structures. Biological metal binding region situated near the 6th-helix and His[superscript 193] residue is responsible for metal binding site. In addition, the calcium ion is coordinated by the carboxyl groups of Lys[superscript 84], Ile[superscript 85], Lys[superscript 86], Asp[superscript 87], Phe[superscript 88], Ala[superscript 89], Ala[superscript 90] (K84-A90) for first calcium (Ca[superscript 2+]) binding site and carbonyl oxygen atom of Lys[superscript 244], Gly[superscript 245], Arg[superscript 246], Thr[superscript 247], Lys[superscript 248], Lys[superscript 249], and Ala[superscript 250] (K244–A250), for second Ca[superscript 2+] binding site. Moreover, Ramachandran plot analysis of protein residues falling into most favored secondary structures were determined (83.3%). The predicted molecular 3D structural model was further verified using PROCHECK, ERRAT and VADAR servers to confirm the geometry and stereo-chemical parameters of the molecular structural design. The functional analysis of AsP 3D molecular structure predictions familiar in the current study may provide a new perspective in the understanding and identification of antifungal protease inhibitor designing

Two Plasmodium Rhomboid Proteases Preferentially Cleave Different Adhesins Implicated in All Invasive Stages of Malaria

Invasion of host cells by the malaria pathogen Plasmodium relies on parasite transmembrane adhesins that engage host-cell receptors. Adhesins must be released by cleavage before the parasite can enter the cell, but the processing enzymes have remained elusive. Recent work indicates that the Toxoplasma rhomboid intramembrane protease TgROM5 catalyzes this essential cleavage. However, Plasmodium does not encode a direct TgROM5 homolog. We examined processing of the 14 Plasmodium falciparum adhesins currently thought to be involved in invasion by both model and Plasmodium rhomboid proteases in a heterologous assay. While most adhesins contain aromatic transmembrane residues and could not be cleaved by nonparasite rhomboid proteins, including Drosophila Rhomboid-1, Plasmodium falciparum rhomboid protein (PfROM)4 (PFE0340c) was able to process these adhesins efficiently and displayed novel substrate specificity. Conversely, PfROM1 (PF11_0150) shared specificity with rhomboid proteases from other organisms and was the only PfROM able to cleave apical membrane antigen 1 (AMA1). PfROM 1 and/or 4 was thus able to cleave diverse adhesins including TRAP, CTRP, MTRAP, PFF0800c, EBA-175, BAEBL, JESEBL, MAEBL, AMA1, Rh1, Rh2a, Rh2b, and Rh4, but not PTRAMP, and cleavage relied on the adhesin transmembrane domains. Swapping transmembrane regions between BAEBL and AMA1 switched the relative preferences of PfROMs 1 and 4 for these two substrates. Our analysis indicates that PfROMs 1 and 4 function with different substrate specificities that together constitute the specificity of TgROM5 to cleave diverse adhesins. This is the first enzymatic analysis of Plasmodium rhomboid proteases and suggests an involvement of PfROMs in all invasive stages of the malaria lifecycle, in both the vertebrate host and the mosquito vector

Comparative genomics reveals Cyclospora cayetanensis possesses coccidia-like metabolism and invasion components but unique surface antigens

Assessment of the completeness of sequenced Toxoplasma gondii, Eimeria tenella and Cyclospora cayetanensis genomes based on core eukaryotic protein-encoding genes search using BUSCO. (DOCX 14 kb