Biochemical characterization of Alanine racemase- a spore protein produced by Bacillus anthracis

Alanine racemase catalyzes the interconversion of L-alanine and D-alanine and plays a crucial role in spore germination and cell wall biosynthesis. In this study, alanine racemase produced by Bacillus anthracis was expressed and purified as a monomer in Escherichia coli and the importance of lysine 41 in the cofactor binding octapeptide and tyrosine 270 in catalysis was evaluated. The native enzyme exhibited an apparent Km of 3 mM for L-alanine, and a Vmax of 295 μmoles/min/mg, with the optimum activity occurring at 37°C and a pH of 8-9. The activity observed in the absence of exogenous pyridoxal 5 -phosphate suggested that the cofactor is bound to the enzyme. Additionally, the UV-visible absorption spectra indicated that the activity was pH independece, of VV-visible absorption spectra suggests that the bound PLP exists as a protonated Schiff’s base. Furthermore, the loss of activity observed in the apoenzyme suggested that bound PLP is required for catalysis. Finally, the enzyme followed non-competitive and mixed inhibition kinetics for hydroxylamine and propionate with a Ki of 160 μM and 30 mM, respectively

Plasmodium falciparum Prp16 homologue and its role in splicing

Large numbers of Plasmodium genes have been predicted to have introns. However, little information exists on the splicing mechanisms in this organism. Here, we describe the DExD/DExH-box containing Pre-mRNA processing proteins (Prps), PfPrp2p, PfPrp5p, PfPrp16p, PfPrp22p, PfPrp28p, PfPrp43p and PfBrr2p, present in the Plasmodium falciparum genome and characterized the role of one of these factors, PfPrp16p. It is a member of DEAH-box protein family with nine collinear sequence motifs, a characteristic of helicase proteins. Experiments with the recombinantly expressed and purified PfPrp16 helicase domain revealed binding to RNA, hydrolysis of ATP as well as catalytic helicase activities. Expression of helicase domain with the C-terminal helicase-associated domain (HA2) reduced these activities considerably, indicating that the helicase-associated domain may regulate the PfPrp16 function. Localization studies with the PfPrp16 GFP transgenic lines suggested a role of its N-terminal domain (1-80 amino acids) in nuclear targeting. Immunodepletion of PfPrp16p, from nuclear extracts of parasite cultures, blocked the second catalytic step of an in vitro constituted splicing reaction suggesting a role for PfPrp16p in splicing catalysis. Further we show by complementation assay in yeast that a chimeric yeast-Plasmodium Prp16 protein, not the full length PfPrp16, can rescue the yeast prp16 temperature-sensitive mutant. These results suggest that although the role of Prp16p in catalytic step II is highly conserved among Plasmodium, human and yeast, subtle differences exist with regards to its associated factors or its assembly with spliceosomes. (C) 2012 Elsevier B.V. All rights reserved

Proteome analysis reveals a large merozoite surface protein-1 associated complex on the Plasmodium falciparum merozoite surface

Plasmodium merozoite surface protein-1 (MSP-1) is an essential antigen for the merozoite invasion of erythrocytes. A key challenge to the development of an effective malaria vaccine that can block the erythrocyte invasion is to establish the molecular interaction(s) among the parasite surface proteins as well as with the host cell encoded receptors. In the present study, we applied molecular interactions and proteome approaches to identify PfMSP-1 associated complex on the merozoite surface. Proteomic analysis identified a major malaria surface protein, PfRhopH3 interacting with PfMSP-1₄₂. Pull-down experiments with merozoite lysate using anti-PfMSP-1 or anti-PfRhopH3 antibodies showed 16 bands that when identified by tandem mass spectrometry corresponded to11 parasite proteins: PfMSP-3, PfMSP-6, PfMSP-7, PfMSP-9, PfRhopH3, PfRhopH1, PfRAP-1, PfRAP-2, and two RAP domain containing proteins. This MSP-1 associated complex was specifically seen at schizont/merozoite stages but not the next ring stage. We could also identify many of these proteins in culture supernatant, suggesting the shedding of the complex. Interestingly, the PfRhopH3 protein also showed binding to the human erythrocyte and anti-PfRhopH3 antibodies blocked the erythrocyte invasion of the merozoites. These results have potential implications in the development of PfMSP-1 based blood stage malaria vaccine

Plasmodium falciparum Tudor Staphylococcal Nuclease interacting proteins suggest its role in nuclear as well as splicing processes

Tudor Staphylococcal Nuclease (p100 or SND1), a member of the micronuclease family is a multifunctional protein that plays a key role(s) in transcription and splicing processes in many eukaryotic cells. PfTudor-SN, a Plasmodium homolog of the human p100 protein is a structurally conserved protein; however molecular details of its function are not yet understood. Our previous studies have shown that PfTudor-SN binds RNA and it is possible to selectively inhibit parasite growth by PfTudor-SN specific drugs. In the present study, we identified the molecular interactions between Plasmodium falciparum Tudor-SN and twelve Plasmodium proteins such as Histone h2A, SPT2 (a transcriptional regulator), a Cold-shock DNA binding protein in a bacterial two-hybrid screen. To get further insight into some of these interactions, we mapped the interaction domain in PfTudor-SN protein using the yeast two-hybrid system. Of these proteins, Plasmodium N-methyl-d-aspartate receptor associated protein, PfUbiquitin conjugating enzyme and Cold-shock DNA binding protein showed interaction with the SN domains of PfTudor-SN. Immuno-localization studies of the interacting proteins showed their presence predominantly in the nucleus, which inevitably suggests the molecular interactions between these proteins and PfTudor-SN. Furthermore, we also identified a molecular interaction between the Tudor domain of PfTudor-SN protein and Plasmodium spliceosomal Sm protein, PfSmD1 advocating the role of PfTudor-SN in the spliceosome assembly. Together, these results suggest multiple role(s) for PfTudor-SN protein mainly in nuclear and splicing processes at asexual blood stages of the malaria parasite