Plasmodium falciparum merozoite surface protein networks and host protein interactions

Sasser, Todd.

January 2004

Thesis (Ph. D.)--University of Hawaii at Manoa, 2004. / Includes bibliographical references (leaves 95-103).

Erythrocyte invasion by Plasmodium falciparum

Jones, Matthew L.

January 2009

Thesis (Ph.D.)--University of Alabama at Birmingham, 2009. / Title from PDF title page (viewed on Feb. 10, 2010). Includes bibliographical references.

Characterisation of the plasmodium falciparum Hsp40 chaperones and their partnerships with Hsp70 /

Botha, Melissa.

January 2008

Thesis (Ph.D. (Biochemistry, Microbiology & Biotechnology)) - Rhodes University, 2009.

Molecular characterisation of the chaperone properties of Plasmodium falciparum heat shock protein 70 /

Shonhai, Addmore.

January 2007

Thesis (Ph.D. (Biochemistry, Microbiology & Biotechnology)) - Rhodes University, 2007.

Structure, Stability And Unfolding Of Plasmodium falciparum Triosephosphate Isomerase

Ray, Soumya S

12 1900

No description available.

Plasmodium falciparum - Protein

Enzymes

Protein Foldings

Triosephosphate Isomerase

Molten Globule

Protein Molten Globules

Enzymology

Studies On Heat Shock Protein 60 From Plasmodium Falciparum

Padma Priya, P

07 1900

Malaria is caused by a protozoan parasite belonging to the genus Plasmodia. Plasmodium falciparum is responsible for the fatal form of human malaria. Spread of drug resistant parasites warrants for sound biological understanding of the parasite at both cellular and biochemical level. Heat shock proteins are highly conserved group of proteins required for correct folding, transport, and degradation of substrate proteins in vivo. Hsp60 is found in eubacteria, mitochondria, and chloroplasts, where in cooperation with Hsp10, it participates in protein folding. Keeping in mind the central importance of chaperones in biological processes, our lab has been interested in examining roles of heat shock proteins in malarial parasite during its asexual growth in human erythrocytes. During its life cycle, the parasite continually shuttles between a cold-blooded insect vector with the body temperature of 27°C and a warm-blooded human host with the body temperature of 37°C and parasite experiences episodes of heat shock periodically. Therefore malaria parasite serves as good model to study heat shock protein functions. Like all biological systems, the malaria parasite expresses several chaperones including proteins of the Hsp40, Hsp60, Hsp70, Hsp90 and Hsp100 families. Towards this we have systematically characterized different families of stress proteins Hsp40, Hsp60, Hsp70, Hsp90 as well as Hsp100. In addition to cloning their genes we have studied their expression, localization, abundance, complexes and their biological roles. Earlier studies from our lab showed PfHsp90 is essential for parasite growth and survival in human erythrocytes. Our present study attempts to study heat shock protein 60 of the malarial parasite (PfHsp60). In this connection we have been successful to clone and express PfHsp60 gene from Plasmodium falciparum in E. coli and to raise antibodies specific to PfHsp60. We have examined its expression and import in the mitochondrion of malarial parasite during its asexual growth in human erythrocytes. Analysis of the total parasite lysates resolved by two-dimensional gel electrophoresis followed by western blotting using specific antibodies showed PfHsp60 exhibits an isoelectric point corresponding to its signal uncleaved precursor (pI - 6.2). Mass spectrometric analysis of the spot corresponding to precursor PfHsp60 confirmed the presence of signal peptide region. Co-immunoprecipitation analysis of total parasite lysates with antibodies specific to PfHsp60 showed precursor PfHsp60 to be associated with PfHsp70 and PfHsp90. Co-immunoprecipitation from the mitochondrial and cytoplasmic fraction confirmed the position of mature PfHsp60. Indirect immunofluorescence analysis also showed presence of a pool of PfHsp60 in the cytoplasm of the parasite, in addition to its expected localization in the mitochondrion. Treatment of parasite infected erythrocytes with an inhibitor of Hsp90 disrupted its association with cytoplasmic chaperones and targeted precursor Pfhsp60 for intracellular degradation. On the other hand treatment with the mitochondrial import inhibitor further inhibited the import of precursor PfHsp60 into the mitochondrion and stabilized its interaction with cytosolic chaperones. Previous reports have shown that there are four fold accumulations of PfHsp60 transcripts in heat shocked parasites. However, the expression of PfHsp60 was not induced upon heat shock in the blood stages of P.falciparum. Biochemical data indicate that the mitochondrion is not the source of ATP in the parasite. Furthermore the genome does not seem to encode the critical subunits of Fo-F1 ATP synthase. Yet, the active mitochondrial electron transport chain serves for regeneration of ubiquinone required for pyrimidine biosynthesis. The active electron transport chain is critical for parasite survival. Recent study with the lab-grown 3D7 strain of malaria parasite concluded that mitochondria are not required for energy conversion. Transcriptome analysis of the parasite derived directly from blood samples of infected patients showed that genes encoding the proteins of mitochondrial biogenesis, oxidative phosphorylation, respiration and highlighted the mean expression level for PfHsp60 is dramatically up regulated in parasites. Gene up regulation doesn’t always translate to increase in protein function or metabolic up regulation. When we analyzed the total parasite lysates of field isolates resolved by two-dimensional gel electrophoresis also showed presence of the precursor form of Pfhsp60 in the cytoplasm of the parasite. Overall, our observations indicated accumulation of precursor PfHsp60 in the parasite cytoplasm suggesting an inefficient mitochondrial protein import in the malarial parasite. The defect in mitochondrial protein import is possibly reflective of the compromised energy state of the parasite mitochondrion. This fits with the model that has been reported in mutant strains of yeast, Saccharomyces cerevisiae lacking functional F o-F1-ATPase. These strains were found to grow very poorly under anaerobic conditions and are known to accumulate Hsp60 protein in the cytoplasm mainly its precursor form. Under optimal growth conditions most eukaryotes maintain close co-ordination between gene expression, translation and translocation efficiently. As a result, mitochondrial precursor proteins are usually not found to accumulate in the cytoplasm. To our knowledge this the first report suggesting an inefficient co-ordination in the synthesis and translocation of precursor PfHsp60 and possibly other proteins during asexual growth of malarial parasite in human erythrocytes under optimal growth conditions. Finally, expression of the PfHsp60 gene in E.coli resulted in its association with bacterial GroEL subunits co-fractionating with a size of 920 kDa, corresponding to the tetra decameric form. The observation indicated possible existence of a hybrid chaperonin complex consisting of subunits from ectopically expressed PfHsp60 and endogenous GroEL.

Malaria

Plasmodium Falciparum - Protein

Malarial Parasite PfHsp60

Heat Shock Proteins

Stress Proteins

PfHsp60 Gene

P. falciparum

GroEL-PfHsp60 Mixed Oligomer

Heat Shock Protein 60 (Hsp60)

GroEL

Biochemistry

Functional Role Of Heat Shock Protein 90 From Plasmodium Falciparum

Pavithra, S

12 1900

Molecular chaperones have emerged in recent years as major players in many aspects of cell biology. Molecular chaperones are also known as heat shock proteins (HSPs) since many were originally discovered due to their increased synthesis in response to heat shock. They were initially identified when Drosophila salivary gland cells were exposed to a heat shock at 37°C for 30 min and then returned to their normal temperature of 25°C for recovery. A “puffing” of genes was found to have occurred in the chromosome of recovering cells, which was later shown to be accompanied by an increase in the synthesis of proteins with molecular masses of 70 and 26 kDa. These proteins were hence named “heat shock proteins”. The first identification of a function for HSPs was the discovery in Escherichia coli that five proteins synthesized in response to heat shock were involved in λ phage growth. The products of the groEL and groES genes were found to be essential for phage head assembly while the dnaK, dnaJ and grpE gene products were essential for λ phage replication. It was later shown that GroEL and GroES are part of a chaperonin system for protein folding in the prokaryotic cytosol while DnaK is a member of the Hsp70 family that works in conjunction with the DnaJ (Hsp40) co-chaperone and the nucleotide exchange factor GrpE to promote phage replication by dissociating the DnaB helicase from the phage-encoded P protein. Since then, a large number of other proteins collectively referred to as HSPs have been discovered. However, heat shock is not the only signal that induces synthesis of heat shock proteins. Stress of any kind, such as nutrient deprivation, chemical treatment and oxidative stress among others causes increased production of HSPs and therefore, they are also known as stress proteins. The term “molecular chaperone” was originally used to describe the function of nucleoplasmin, a Xenopus oocyte protein that promotes nucleosome assembly by binding tightly to histones and donating the bound histone to chromatin. However, since then, chaperones have been defined as “a family of unrelated classes of proteins that mediate the correct assembly of other proteins, but are not themselves components of the final functional structure”. This view of molecular chaperones, though undoubtedly correct, doesn’t capture the multifaceted roles they have since been discovered to play in cellular processes. In recent years, molecular chaperones have been shown to perform other functions in addition to the maintenance of protein homeostasis: translocation of proteins across organelle membranes, quality control in the endoplasmic reticulum, turnover of misfolded proteins as well as signal transduction. As a result, many chaperones are also essential under non-stress conditions and play crucial roles in cell growth and development, cell-cell communication and regulation of gene expression. Heat shock protein 90 (Hsp90) is one of the most abundant and highly conserved molecular chaperones in organisms ranging from bacteria to all branches of eukarya. It has been shown to be essential for cell viability in Saccharomyces cerevisiae, Schizosaccharomyces pombe and Drosophila melanogaster. Although the bacterial homolog HtpG is dispensable under normal conditions, it is important for cell survival during heat shock. In addition to its role as general chaperone in protein folding following stress, Hsp90 has a more specialized role as a chaperone for several protein kinases and transcription factors. Many Hsp90 client proteins are signaling proteins involved in regulation of cell growth and survival. These proteins are critically dependent on Hsp90 for their maturation and conformational maintenance resulting in a key role for Hsp90 in these processes. Recent reports have also highlighted a role for Hsp90 in linking the expression of genetic and epigenetic variation in response to environmental stress with morphological development in Drosophila melanogaster and Arabidopsis thaliana. In Candida albicans, Hsp90 augments the development of drug resistance, implicating a role for Hsp90 in the evolution of infectious diseases. The malarial parasite, Plasmodium falciparum, is the causative agent of the most lethal form of human malaria. The parasite life cycle involves two hosts: an invertebrate mosquito vector and a vertebrate human host. As the parasite moves from the mosquito to the human body, it experiences an increase in temperature resulting in a severe heat shock. The mechanisms by which the parasite adapts to changes in temperature have not been deciphered. Our laboratory has been interested in investigating the role of heat shock proteins during acclimatization of the parasite to such temperature fluctuations. Heat shock proteins of the Hsp40, Hsp60, Hsp70 and Hsp90 families have been characterized in the parasite and are being examined in our laboratory. This thesis pertains to understanding the functional role of Plasmodium falciparum Hsp90 (PfHsp90) during adaptation of the parasite to fluctuations in environmental temperature. The parasite expresses a single gene for cytosolic Hsp90 on chromosome 7 (PlasmoDB accession no.: PF07_0029) coding for a protein of 745 amino acids with a pI of 4.94 and Mw of 86 kDa. Eukaryotic Hsp90 regulates several protein kinases and transcription factors involved in cell growth and differentiation pathways resulting in a crucial role for Hsp90 in developmental processes. A role for PfHsp90 in parasite development, therefore, seems likely. Indeed, PfHsp90 has previously been implicated in parasite development from the ring stage to the trophozoite stage during the intra-erythrocytic cycle. Pharmacological inhibition of PfHsp90 function using geldanamycin (GA), a specific inhibitor of Hsp90 activity, abrogates stage progression. These experiments suggest that PfHsp90 may play a critical role in parasite development. This is further substantiated by the fact that several pathogenic protozoan parasites such as Leishmania donovani, Trypanosoma cruzi, Toxoplasma gondii and Eimeria tenella depend on Hsp90 function during different stages of their life cycles. It appears, therefore, that a principal role of Hsp90 in protozoan parasites may be the regulation of their developmental cycles. However, the precise functions of PfHsp90 during the intra-erythrocytic cycle of the malarial parasite are not clear. In this study we have carried out a functional analysis of PfHsp90 in the malarial parasite. We have examined the role of PfHsp90 in parasite development during repeated exposure to febrile temperatures. We have investigated its involvement in parasite development during a commonly used synchronization protocol involving cyclical changes in temperature. We have examined the interaction of GA with the Hsp90 multi-chaperone complex from P. falciparum as well as the human host. Finally, we have carried out a systems level analysis of chaperone networks in the malarial parasite as well as its human host using an in silico approach. We have analyzed the protein-protein interactions of PfHsp90 in the chaperone network and predicted putative cellular processes likely to be regulated by parasite chaperones, particularly PfHsp90.

Plasmodium Falciparum - Protein

Protein Structure

Heat Shock Protein 90

Cellular Organism

Molecular Chaperones

Malarial Parasite - Chaperone Networks

Hsp90

Chaperone

Antimalarials

Malaria

Geldanamycin (GA)

Biochemistry