Studies On Phosphorylation And Oligomerization Of Rotavirus Nonstructural Protein 5 (NSP5) And Cellular Pathways That Regulate Virus Replication

Namsa, Nima Dondu

07 1900

Rotavirus is one of the leading etiological agents of gastroenteritis in young of many species including humans worldwide and is responsible for about 600,000 infant deaths per annum. Rotavirus belongs to the Reoviridae family, and its genome is composed of 11 double-stranded RNA segments that encode six structural proteins and six nonstructural proteins. Rotavirus replication is fully cytoplasmic and occurs within highly specialized regions called viroplasms. NSP2 and NSP5 have been shown to be essential for viroplasm formation and, when co-expressed in uninfected cells, to form viroplasm¬like structures. A recent study suggest a key role for NSP5 in architectural assembly of viroplasms and in recruitment of viroplasmic proteins, containing four structural (VP1, VP2, VP3 and VP6) and two nonstructural (NSP2 and NSP5) proteins. NSP5, the translation product of gene segment 11 has a predicted molecular eight of 21 kDa. NSP5 has been reported to exist in multiple isoforms ranging in size from 28-and 32-35 kDa from a 26-kDa precursor has been attributed to O-glycosylation and hyperphosphorylation. To study different properties of the protein, recombinant NSP5 containing an N-terminal hisidine tag was expressed in bacteria and purified by affinity chromatography. A significant observation was the similarity in phosphorylation property of the bacterially expressed and that expressed in mammalian cells. While the untagged recombinant protein failed to undergo phosphorylation in vitro, addition of His tag or deletions at the N-terminus promoted phosphorylation of the protein in vitro, which is very similar to the reported properties exhibited by the corresponding proteins expressed in mammalian cells. Phosphorylation of NSP5 in vitro is independent of the cell type from which the extract is derived suggesting that the kinases that phosphorylate NSP5 are distributed in all cell types. Among the C-terminal deletion mutants studied, NH-∆C5 and NH-∆C10 were phosphorylated better than full-length NSP5, but NH-∆C25 and NH¬∆C35 showed substantial reduction in the level of phosphorylation compared to full-length NSP5. These results indicate that the C-terminal 30 residues spanning the predicted α-helical domain of NSP5 are critical for its phosphorylation in vitro which is in correspondence with previous findings that C-terminal 21 amino acids of NSP5 direct its insolubility, hyperphosphorylation, and VLS formation. The results revealed that though the tagged full-length and some of the mutants could be phosphorylated in vitro, they are not suitable substrates for hyperphosphorylation unlike the similar proteins expressed in mammalian cells or infected cells. Analysis by western blot and mass spectrometry revealed that the bacterially expressed NH-NSP5 is indeed phosphorylated. It appears that prior phosphorylation in bacteria renders the protein conformationally not amendable for hyperphosphorylation by cellular kinases in vitro. Mutation of the highly conserved proline marginally enhanced its phosphorylation in vitro but the stability of protein is affected. Notably, mutation of S67A, identified as a critical residue for the putative caesin kinase-I and-II pathways of NSP5 phosphorylation, affected neither the phosphorylation nor the ATPase activity of NSP5. These results suggest that bacterially expressed NSP5 by itself has undectable auto-kinase activity and it is hypophosphorylated. Purified recombinant NSP5 has been reported to possess an Mg¬ 2+-dependent ATP-specific triphosphatase activity. The results indicated that deletion of either C-terminal 48 amino acids or N-terminal 33 residues severely affected the ATPase activity of recombinant NSP5, underlying the importance of both N-and C-terminal domains for NSP5 ATP hydrolysis function. NSP5 expressed in rotavirus infected cells exists as inter-molecular disulfide-linked dimeric forms and it appears that the 46 kDa isoforms, that are phosphorylated, corresponds to dimer as revealed by western blotting. Analytical gel filtration analysis of NH-NSP5, NH-ΔN43 and NH-ΔN33-ΔC25 showed most of the proteins in void volume, but an additional peak corresponding to the mass of dimeric species further supports that NSP5 is basically a dimer that undergoes oligomerization. Analysis by sucrose-gradient fractionation revealed that NH-NSP5 and NH-ΔN43 proteins were mainly distributed in the lower fraction of the gradient suggesting the existence of high molecular weight complexes or higher oligomers. The multimeric nature of NSP5 and its mutants was further confirmed by dynamic light scattering which suggests that high molecular weight complexes are of homogenous species. The correlation curves showed a low polydispersity distribution and a globular nature of recombinant NH-NSP5 proteins. The present results clearly demonstrate that dimer is the basic structural unit of NSP5 which undergoes oligomerization to form a complex consisting of about 20-21 dimers. The nonstructural protein 5 is hyperphosphorylated in infected cells and cellular kinases have been implicated to be involved in its phosphorylation. NSP5 contains multiple consensus sites for phosphorylation by several kinases, but the cellular kinases that specifically phosphorylate NSP5 in infected cells are yet to be identified. Previous studies from our laboratory using signaling pathway inhibitors revealed that recombinant NH¬NSP5 and its deletion mutants can be phosphorylated in vitro by purified cellular kinases and by mammalian cell extracts. These studies also showed the involvement of PI3K-Akt and MAPK signaling pathways in NSP5 phosphorylation and a negative role for GSK3β in the phosphorylation of bacterially expressed recombinant NSP5 in vitro. In the present work, using phospho-specific anti-Ser9 GSK3β antibody, we observed that GSK3β is inactivated in a rotavirus infected MA104 cells in a strain-independent manner. GSK3β¬specific small interfering RNA (siRNA-GSK3β) reduced GSK3β levels leading to increased level of synthesis of the structural rotavirus protein VP6 and NSP5 hyperphosphorylation compared to control siRNA. The pharmacological kinase inhibitors (LY294002, Genistein, PD98059, and Rapamycin) studies at the concentrations tested did not significantly affect rotavirus infection as seen from the number foci, while U0126 severely affected rotavirus replication. The results clearly demonstrated the importance of the MEK1/2 signaling pathway in the successful replication of rotavirus and NSP5 hyperphosphorylation in rotavirus-infected cells. In contrast inhibition of GSK3β activity by LiCl, increased in general, the number of foci by greater than 2-fold for all viral strains studied. These results suggest that MEK1/2 pathway majorly contributes to GSK3β inactivation in rotavirus infected cells. Thus, our results reveal that rotavirus activates both the PI3K/Akt and FAK/ERK1/2 MAPK pathways and appears to utilize them as a strategy to activate mTOR, and inhibit GSK3β through phosphorylation on serine 9, the negative regulator of rotavirus NSP5 phosphorylation, and thus facilitate translational competence of rotaviral mRNAs during virus replication cycle. It was shown previously in the laboratory by co-immunoprecipitation assay that Hsp70 interacts with rotaviral proteins VP1 and VP4 in rotavirus-infected mammalian cells. In this study, the interactions between Hsp70 with VP1 and VP4 were further evaluated in vitro by GST-pull down assay. It was observed that the N-terminal ATPase and C-terminal peptide-binding domain of Hsp70 is necessary for its direct interaction with VP1 and VP4. The presence of Hsp70 in purified double-and triple-layered virus particles further supported the observed interactions of rotaviral proteins VP1 and VP4 with Hsp70. However, the specific interaction observed between Hsp70 and rotaviral capsid proteins, VP1 and VP4 in viral particles suggests that Hsp70 has an important role during rotavirus assembly which requires further investigation.

Rotaviruses

Rotaviral Nonstructural Proteins

Nonstructural Protein

Viral Proteins

Heat Shock Protein 70 (Hsp70)

Viral Replication

Rotaviral Replication

Rotavirus Nonstructural Protein 5 (NSP5)

Rotavirus

Rotaviral Structural Proteins

Rotaviral Proteins

Nonstructural Protein 5

VP1

VP4

Virology

Vliv přítomnosti proteinu Hsp70 na infekci způsobenou Y virem bramboru / The effect of Hsp70 protein on the infection caused by Potato virus Y

Doričová, Vlasta

January 2014

Whithin their natural environment, plants are subjected to a combination of stress conditions. Since potential interactions between signal pathways, plants respond to multiple stresses differently from how they do to individual stresses, activating a specific programme. Heat shock proteins (HSP70) overexpressed after heat shock influence the viral infection. On one side HSP70 can participate on refolding of aggregated or partially denaturated proteins, on the other side HSP70 can interact with viral proteins and facilitate propagation of viral replication complexes. In this work the effect of heat shock (42řC, 2. hours) applied before or after the inoculation of plants Nicotiana tabacum L. cv. Petit Havana SR1 with Potato virus Y on viral infection was detected. This effect was studied in two biological experiments. The amount of coat protein of PVYNTN and protein HSP70 were detected simultaneously with the activity assays of Hatch-Slack cycle enzymes, glycosidases and peroxidase. Both experimental approaches (heat shock applied before or after the inoculation by PVYNTN ) enhanced amount of the virus and in the 2nd experiment it accelerated infection development. Immediately after application of heat shock the amount of HSP70 was increased. The enhancement of HSP70 by viral infection occurred...

Význam aktivačních a inhibičních ligandů na leukemických blastech pro stimulaci NK buněk. / Signification of activatory and inhibitory ligands on leukemia cells to NK stimulations.

Imryšková, Zuzana

January 2010

In last decades, with expansion of immunological and biological methods are developed new diagnostical and treatment processes, which enable stratification of patients into sanative groups and trend to individual therapy. Absolutely transparent are effects relevant to leukemia. Present treatment procedures enable not only longer survivance of patients, but often their stable sanation. In present time is in progress intesive research imunotherapy NK cells, which could be able to finish minimal residual disease after chemotherapeutical treatment, which is evoke by persistant malignant cells. Next advantage of this treatment procedure is elimination of system disease in cosequence of exactly pointed cure. In this work he attended in vitro testing to possibility of utilization imunotherapeutic treatment by NK cells acute and chronic myeloid leukemia and chronic lymfoblastic leukemia. Using flow cytometry methods we detected activation and inhibitory ligands which are recognized by NK cells on the cell surface of leukemia blasts. These are members of MHC complex HLA-E, molecules derived from MHC class I (MICA, MICB), UL16-binding proteins (ULBP-1, ULBP -2, ULBP -3, ULBP -4) and also Hsp70 protein according to the newest observation. We also atended to detection of expression inducible heat shock...

A New Laser Pointer Driven Optical Microheater for Precise Local Heat Shock

Placinta, Mike

01 January 2009

The zebrafish has emerged as an important genetic model system for the study of vertebrate development. However, while genetics is a powerful tool for the study of early gene functions, the approach is more limited when it comes to understanding later functions of genes that have essential roles in early embryogenesis. There is thus a need to manipulate gene expression at different times, and ideally only in some regions of the developing embryo. Methods for conditional gene regulation have been established in Drosophila, C.elegans and the mouse, utilizing conditional gene activation systems such as the Gal4-UAS system (fly) and the cre/lox recombination system (mouse). While these tools are also being developed in zebrafish, the accessibility of the zebrafish embryo makes other approaches both possible and desirable. We have taken advantage of a heat-shock inducible system that uses the hsp70 promoter that is activated by cellular stress, such as heat. Having established that this global heat shock method allows temporal control of gene expression, we aimed to spatially control gene expression by applying controlled thermal heat to only a small region of the embryo. This would allow us to determine cell- and tissue-autonomous roles for developmentally important genes in an embryo with otherwise normal gene function. We have now developed a device that uses a laser to heat a defined region of the embryo, and thus activate the hsp70 promoter only in restricted regions of the embryo. The output of a 75 mW red laser pointer was focused into the 50 µm diameter core of an optical fiber, whose cleaved and coated end was used to heat, and thus induce, gene expression in a defined area. We have established conditions that allow controlled heating and trans-gene activation in small regions of the embryo without inducing cell death. This new tool will allow us to study the cell-autonomous roles of embryonic signaling molecules in cell differentiation, proliferation, and survival in a variety of tissues and at different times.

heat shock

optical fibers

fate map

hsp70 promoter

pituitary

lineage tracing

Molecular biology

Animals

Biology

Biotechnology

Investigative Techniques

Laboratory and Basic Science Research

Molecular and Cellular Neuroscience

Other Neuroscience and Neurobiology

Therapeutics

Implication de deux protéines de choc thermique<br />humaines HSP70 et HSP22 dans les voies de la<br />réparation de l'ADN : approche structurale et<br />fonctionnelle

Rénier, Wendy

03 October 2006

HSP22 et HSP70 sont des protéines d'origine humaine appartenant à la famille des Heat Shock<br />Proteins. Cette thèse décrit des travaux visant à déterminer l'implication de ces deux protéines humaines de<br />choc thermique HSP70 et HSP22, dans les voies de réparation de l'ADN après stress. Ces protéines<br />possèdent, comme leur nom le sous-entend, la capacité d'être surexprimées par la cellule après choc<br />thermique mais aussi après une grande variété d'autres stress et dans de nombreuses maladies (Tavaria M et<br />al, 1996). Pour mieux connaître ces protéines, une étude structurale a été initiée. Les structures<br />tridimensionnelles de ces protéines ne sont pas connues ou seulement partiellement (Osipiuk J et al, 1999).<br />Les essais de cristallisation des protéines furent arrêtés après l'obtention de clones. Des prédictions de<br />structures secondaires et tertiaires (obtenues à l'aide de la bioinformatique) concernant HSP70-1 (partie Cterminale)<br />et HSP22 furent alors réalisées, montrant une organisation en feuillets β pour le domaine de liaison<br />au substrat de HSP70-1 et pour le domaine α-cristallin de HSP22. Les résultats obtenus dans le cadre de<br />l'étude des HSP dans les voies de la réparation de l'ADN ont montré que les HSP70 inductibles par le stress<br />(HSP72 et HSP70-1) sont impliquées dans ces voies cellulaires après différents stress (rayonnement X et UV,<br />champ magnétique, péroxyde d'hydrogène, cis-platine). HSP72 et HSP70-1 sont phosphorylées par les<br />kinases apparentées à la famille des Phosphatydil-Inositol-3-kinases ATM, ATR et DNA-PK (Sarkaria JN et<br />al, 1998) après radiations ionisantes et réalisent à ce moment un déplacement en deux phases entre le<br />cytoplasme et le noyau ; elles sont impliquées dans les stades précoces de la réparation. La même démarche<br />de recherche a été adoptée pour HSP22. HSP22 apparaît comme étant impliquée dans les voies de la<br />réparation de l'ADN aussi et plus particulièrement dans les voies de la réparation des cassures double brin<br />après irradiation par rayonnement X (Paull TT et Gellert M, 1998 ; Lobrich M et Jeggo PA, 2005). HSP22<br />forme des foci dans les cellules âgées suggérant un rôle pour HSP22 dans le vieillissement cellulaire chez<br />l'humain comme chez la mouche drosophile (Morrow G et al 2004). Une nouvelle méthode d'imagerie<br />Diffraction Enhanced Imaging (DEI ; Chapman D et al, 1997), visant à l'acquisition d'une information<br />histologique, développée au synchrotron ESRF, a été testée d'un point de vue radiobiologique sur des cultures<br />primaires de fibroblastes et de chondrocytes. L'irradiation par cette méthode n'a pas présenté de différence en<br />comparaison avec une irradiation par une source conventionnelle de cellules humaines issues de culture<br />primaire, avec la même dose de rayonnement X (Rothkamm K et Lobrich M, 2003). Dans les cellules<br />glioblastomales de rat, la réponse HSP70 est augmentée dans les conditions de la thérapie « synchrotron PATPlat<br />» (c'est-à-dire en cas de photoactivation du platine à l'aide du rayonnement synchrotron (Corde S et al,<br />2003 ; Biston MC et al, 2004)).

[SDV:IB] Life Sciences/Bioengineering

Stress biomarkers in a rat model of decompression sickness /

Caviness, James A.

January 2005

Thesis (M.S.)--Uniformed Services University of the Health Sciences, 2005. / Typescript (photocopy).

Understanding the Heat Shock Response Pathway in Plasmodium Falciparum and Identification of a Novel Exported Heat Shock Protein

Grover, Manish

January 2014

Infections or diseases are not just stressful for the one who encounters it. The pathogens causing the same also have to deal with the hostile environment present in the host. The maintenance of physiological homeostatic balance is must for survival of all organisms. This becomes a challenging task for the protozoan parasites which often alternate between two different hosts during their life cycle and thereby encounter several environmental insults which they need to acclimatize against, in order to establish a productive infection. Since their discovery as proteins up-regulated upon heat shock, heat shock proteins have emerged as main mediators of cellular stress responses and are now also known to chaperone normal cellular functions. Parasites like Plasmodium falciparum have fully utilized the potential of these molecular chaperones. This is evident from the fact that parasite has dedicated about 2% of its genome for this purpose. During transmission from the insect vector to humans, the malaria parasite Plasmodium falciparum experiences a temperature rise of about 10oC, and the febrile episodes associated with asexual cycle further add to the heat shock which the parasite has to bear with. The exact mechanism by which the parasite responds to temperature stress remains unclear; however, the induction of chaperones such as PfHsp90 and PfHsp70 has been reported earlier. In other eukaryotes, there are three main factors which regulate heat shock response (HSR): heat shock factor (HSF), heat shock element (HSE) and HSF binding protein (HSBP). Bioinformatics analysis revealed presence of HSE and HSBP in P. falciparum genome; however, no obvious homolog of HSF could be identified. Either the HSF homologue in P. falciparum is highly divergent or the parasite has evolved alternate means to tackle temperature stress. Therefore, we decided to biochemically characterize HSBP and understand the heat shock response pathway in the parasite using transcriptomics and proteomics. The expression for PfHSBP was confirmed at both mRNA and protein level and it was found to translocate into the nucleus during heat shock. As previously reported for HSBP in other organisms, PfHSBP also exists predominantly in trimeric and hexameric form and it interacts with PfHsp70-1. Nearly 900 genes, which represent almost 17% of the parasite genome, were found to have HSE in their promoter region. HSE are represented by three repeating units of nGAAn pentamer and its inverted repeat nCTTn; however, the most abundant class of genes in P. falciparum possessed an atypical HSE which had only 2 continuous repeat units. Next, we were interested to find out if these HSE could actually bind to any parasite protein. Therefore, we performed EMSA analysis with the parasite nuclear extracts using HSE sequence as the oligonucleotide. We observed retarded mobility of the oligonucleotide suggesting that it was indeed able to recruit some protein from the nuclear extract. The importance of transcriptional regulation during heat shock was further confirmed when parasite culture subjected to heat shock in the presence of transcription inhibitor did not show induction in the levels of PfHsp70. These evidences suggest that parasite indeed possesses all the components of heat shock response pathway with either a divergent homologue of HSF or an alternate transcription factor which would have taken its role. Next, we performed global profiling of heat shock response using transcriptomic analysis and 2DDIGE based proteomic profiling. Overall, the parasite’s response to heat shock can be classified under 5 functional categories which aim at increasing the folding capacity of the cell, prevent protein aggregation, increase cytoadhesion, increase host cell remodelling and increase erythrocyte membrane rigidity. Out of the 201 genes found to be up-regulated upon heat shock, 36 were found to have HSE in their promoter region. This suggested that HSE-mediated protein up-regulation could be responsible for the induction of only 18% of total number of genes up-regulated upon heat shock. How would the parasite bring about up-regulation of rest of the heat shock responsive genes? It has been previously reported that genes for some of the heat shock proteins in P. falciparum possess G-box regulatory elements in their promoters and recently, it was shown that these elements served as the binding site for one of the transcription factors (PF13_0235) of AP2 family. Therefore, we looked for the status of this AP2 factor and its targets in our transcriptome data. Although, PF13_0235 was itself not up-regulated, we found up-regulation of its target genes which included another AP2 factor gene PF11_0404. The target genes of PF11_0404 were also up-regulated upon heat shock, thereby suggesting the functioning of an AP2 factor mediated response to heat shock. The next major challenge which the malaria parasite has to deal with is the remodelling of the erythrocyte as these cells do not have a cellular machinery which the parasite can take control of. The parasite remodels the erythrocyte with the help of its large repertoire of exported proteins and develops protrusions known as “knobs” on the erythrocyte surface. These protrusions are cytoadherent in nature and constitute the main virulence determinants of malaria. They also represent variable antigens that allow immune escape. Our lab has previously demonstrated an exported PfHsp40, termed as KAHsp40, to be involved in knob biogenesis. Apart from KAHsp40, there are 19 other PfHsp40s which possess the PEXEL motif required for protein export to erythrocytes. Although, Hsp40s work with an Hsp70 partner, none of the parasitic Hsp70s were known to be exported and was always a missing link in the field of malaria chaperone biology. A genomic re-annotation event could fill this gap by re-annotating the sequence for a pseudogene, PfHsp70-x and described it to contain a functional ORF. According to the re-annotated ORF sequence, PfHsp70-x possessed an ER signal peptide and thus could be targeted to the secretory pathway. Following validation of the re-annotation using a PCR-based approach, we confirmed the expression of this protein at the protein level by immunoblot analysis. Using various subcellular fractionation approaches and immunolocalization studies we established that PfHsp70-x indeed gets exported to the erythrocyte compartment; however, it did not contain the PEXEL motif required for protein export. It gets secreted into the vacuole around the parasite via the canonical ER-Golgi secretory pathway. Its trafficking from vacuole into the erythrocyte was mediated by a hexameric sequence which was present just after the signal peptide cleavage site and before the beginning of ATP-binding domain. In the erythrocyte compartment, it was found to interact with KAHsp40 and MAHRP1, proteins previously implicated in knob biogenesis. Most importantly, PfHsp70-x interacted with the major knob component PfEMP1; however, itself did not become part of knobs. Instead, it localized to the Maurer’s clefts in the erythrocyte compartment. Inside the parasite, PfHsp70-x was present in a complex with Plasmepsin V and PfHsp101. These proteins have been shown to be essential for host cell remodelling process. Plasmepsin V recognizes the PEXEL motif and brings about its cleavage and PfHsp101 specifically targets these PEXEL-cleaved exported proteins to the translocon in vacuolar membrane thereby facilitating their export into the erythrocyte. Thus, PfHsp70-x could also be involved in directing the export of knob constituents apart from just facilitating their assembly. Since, we found out that heat shock or the febrile episodes encountered during the asexual cycling of the parasite promote host cell remodelling; we wanted to find out if PfHsp70-x has any specific role under conditions of temperature stress. PfHsp70-x gene expression was not influenced upon heat shock, however, its export into the erythrocyte was inhibited and the protein got accumulated within the parasite compartment. Surprisingly, immunolocalization studies revealed that the accumulated pool of PfHsp70-x localized into the nucleus instead of ER thus suggesting an alternate role to be associated with PfHsp70-x under stress. Overall, our study addresses two major aspects of malaria pathogenesis. First, response to heat shock and second, remodelling of the host cell. We, for the first time describe global profiling of the parasite’s heat shock response and identify a novel P. falciparum specific heat shock protein member to be involved in malaria pathogenesis.

Plasmodium Falciparum

Heat Shock Proteins

Malaria Pathogenesis

Molecular Chaperones

Malaria Heat Shock Proteins

Heat Shock Factor Binding Proteins

Pathogen Virulence

Transcription Regulation

Transcriptomics

Proteomics

Genomics

Hsp90

Hsp70

Hsp40

Heat Shock Response Pathway

PfHsp70

PfHsp70-x

Malaria Parasite

Biochemistry