Current Search: SNAREs (x)
-
-
Title
-
THE ROLE OF HSC-70 IN VERY LOW DENSITY LIPOPROTEIN TRANPORT VESICLE GOLGI FUSION COMPLEX FORMATION.
-
Creator
-
Nafi-Valencia, Erika, Siddiqi, Shadab, University of Central Florida
-
Abstract / Description
-
Excess production and secretion of very low-density lipoprotein (VLDL) by the liver into the circulatory system is directly related to atherosclerosis, a chronic cardiovascular disease that threatens the lives of many worldwide and continues to be a leading cause of death in the United States. The rate-limiting step in VLDL secretion is its transport from the site of biogenesis, the hepatic endoplasmic reticulum to the cis-Golgi. This step is mediated by a specialized ER- derived vesicle, the...
Show moreExcess production and secretion of very low-density lipoprotein (VLDL) by the liver into the circulatory system is directly related to atherosclerosis, a chronic cardiovascular disease that threatens the lives of many worldwide and continues to be a leading cause of death in the United States. The rate-limiting step in VLDL secretion is its transport from the site of biogenesis, the hepatic endoplasmic reticulum to the cis-Golgi. This step is mediated by a specialized ER- derived vesicle, the VLDL transport vesicle (VTV). Upon exit of the ER the VTV targets, fuses and delivers VLDL into the lumen of the Golgi. The targeting and fusion of the VTV with the Golgi is facilitated by specific set of soluable N-ethylmaleimide sensitive factor attachment protein receptor (SNARE) proteins that form a SNARE complex, which is required for the VTV-Golgi fusion and thus delivery to the Golgi. Data from our laboratory indicates that the formation of the SNARE complex requires cytosolic factors. Through the purification of liver cytosol, chromatographic steps, detailed mass spectrometry, immunodepletion and western blotting data it was identified that the protein necessary for SNARE complex formation is Hsc-70. Although Hsc-70's identification is significant, the role it plays in SNARE complex formation for VTV -Golgi fusion is a predicament and yet to be unraveled. In this study we performed a series of co-immunoprecipitation reactions to identify its role in SNARE-complex assembly. Using western blot data we confirmed binding of Hsc-70 with Sec22b, the v-SNARE on the VTV. Moreover, we confirmed the interaction of Hsc-70 with t-SNAREs, (syn5, rBet1 and GOS28) on the Golgi membrane. Removal of Hsc-70 from the liver cytosol resulted in significant reduction of SNARE-complex formation. Ultimately, the identification proteins involved in the process of VLDL delivery to the Golgi would offer therapeutic targets to control VLDL secretion into the blood by the liver.
Show less
-
Date Issued
-
2012
-
Identifier
-
CFH0004322, ucf:45036
-
Format
-
Document (PDF)
-
PURL
-
http://purl.flvc.org/ucf/fd/CFH0004322
-
-
Title
-
UNDERSTANDING THE ROLE OF PLASMODIUM FALCIPARUM VAMP8 SNARE HOMOLOGUE.
-
Creator
-
Camacho Ferreira, Katherine, Chakrabarti, Debopam, University of Central Florida
-
Abstract / Description
-
Malaria is one of the worlds most deadly infectious diseases and results in almost a million deaths each year, largely in children under the age of five in Sub-Saharan Africa. Outside Africa, malaria is responsible for a large number of cases in the Amazon rainforest of Brazil, Middle East, and in some areas of Asia . According to the World Health Organization, there was an estimated 655, 000 deaths from malaria in 2012. Malaria is caused by a eukaryotic Apicomplexan parasite, Plasmodium,...
Show moreMalaria is one of the worlds most deadly infectious diseases and results in almost a million deaths each year, largely in children under the age of five in Sub-Saharan Africa. Outside Africa, malaria is responsible for a large number of cases in the Amazon rainforest of Brazil, Middle East, and in some areas of Asia . According to the World Health Organization, there was an estimated 655, 000 deaths from malaria in 2012. Malaria is caused by a eukaryotic Apicomplexan parasite, Plasmodium, which has three distinct life cycles occurring in the midgut of the female Anopheles mosquito, the liver of the human host, and human erythrocytes. When the parasite infects the erythrocyte, some induced cell host modifications are made in order to accommodate growth. During its intra-erythrocytic life cycle, the malaria parasite traffics numerous proteins to a set of unique destinations within its own plasma membrane including the digestive vacuole, the apicoplast, rhoptries, and micronemes. Vesicular transport is an essential process in eukaryotic cells. This coordinated process is responsible for moving thousands of proteins between compartments within the cell. Essential to the targeting and fusion of protein transport vesicles in eukaryotes are SNAREs (soluble N-ethylmaleimide sensitive factor attachment protein receptors), a family of fusogenic proteins that are localized to distinct intracellular compartments . Studies performed in our laboratory have identified 18 proteins putatively belonging to the PfSNARE family . To date the exact role of PfSNAREs in the unique trafficking pathways of malaria is undetermined. Of particular interest to our study is PfVAMP8. In model eukaryotic organisms, VAMP8 containing vesicles deliver cargo to lysosomes and are involved in endocytosis. The food vacuole of the parasite is very similar to that of lysosomes and is essential to parasite survival. The study aims to identify the organelle(s) to which PfVAMP8 is localized and characterize membrane-association properties of this parasite's R-SNARE protein. We believe that PfVAMP8 would localize to unique compartments in the parasite protein network flow. An in depth understanding of its mechanisms and localizations could be a key in developing novel anti-malarials. This study aims to identify the organelle(s) to which PfVAMP8 are localized, determine the trafficking determinants of this protein and determine this proteins' expression and membrane association during the intra-erythrocytic stages of Plasmodium falciparum. Our immunofluorescence studies with known biological markers reveals that, PfVAMP8 passes through the endoplasmic reticulum, Golgi, and localizes to the food vacuole during trophozoite and schizont stage. Further characterization of the membrane association properties of the protein in this study reveals that PfVAMP8 is a soluble integral membrane protein with amphipathic characteristics.
Show less
-
Date Issued
-
2013
-
Identifier
-
CFH0004525, ucf:45157
-
Format
-
Document (PDF)
-
PURL
-
http://purl.flvc.org/ucf/fd/CFH0004525
-
-
Title
-
VESICLE TARGETING IN PLASMODIUM FALCIPARUM: THE IDENTIFICATION AND MOLECULAR CHARACTERIZATION OF PLASMODIUM FALCIPARUM FAMILY OF SNARE PROTEINS.
-
Creator
-
Ayong, Lawrence, Chakrabarti, Debopam, University of Central Florida
-
Abstract / Description
-
Proteins of the SNARE (Soluble N-ethylmaleimide sensitive factor attachment protein receptor) super-family have been characterized as playing an essential role in vesicle targeting and fusion in all eukaryotes. The intracellular malaria parasite Plasmodium falciparum exhibits an unusual endomembrane system that is characterized by an unstacked Golgi apparatus, a developmentally induced apical complex, and various organellar structures of parasite origin in the infected host cells. How malaria...
Show moreProteins of the SNARE (Soluble N-ethylmaleimide sensitive factor attachment protein receptor) super-family have been characterized as playing an essential role in vesicle targeting and fusion in all eukaryotes. The intracellular malaria parasite Plasmodium falciparum exhibits an unusual endomembrane system that is characterized by an unstacked Golgi apparatus, a developmentally induced apical complex, and various organellar structures of parasite origin in the infected host cells. How malaria parasites target nuclear-encoded proteins to these novel compartments is a central question in Plasmodium cell biology. Ultrastructural studies elsewhere have implicated the participation of specialized vesicular elements in transport of virulence proteins, including various cytoadherance and host cell remodeling factors, into the infected erythrocyte cytoplasm. However, little is known about the machineries that define the directionality of vesicle trafficking in malaria parasites. We hypothesized that the P. falciparum SNARE proteins would exhibit novel features required for vesicle targeting to the parasite-specific compartments. We then identified for the first time and confirmed the expression of eighteen SNARE genes in P. falciparum. Members of the PfSNAREs exhibit atypical structural features (Ayong et al., 2007, Molecular & Biochemical Parasitology, 152(2), 113-122). Among the atypical PfSNAREs, PfSec22 contains an unusual insertion of the Plasmodium export element (PEXEL) within its profilin-like longin domain, preceded by an N-terminal hydrophobic segment. Localization analyses suggest that PfSec22 is predominantly a vesicle-associated SNARE of the ER/Golgi interface, but which associates partially with mobile extraparasitic vesicles in P. falciparum-infected erythrocytes at trophozoite stages. We showed that PfSec22 export into host cells occurs via a two-step model that involves extraparasitic vesicle budding from the parasite plasma membrane and fusion with the parasitophorous vacuolar membrane. Export of PfSec22 was independent of its membrane-insertion suggesting that this protein might cross the vacuolar space as a single-pass type IV membrane protein. We demonstrated that the atypical longin domain dictates the steady-state localization of PfSec22, regulating its ER/Golgi trafficking and export into host cells. Our study provides the first experimental evidence for SNARE protein export in P. falciparum, and suggests a role of PfSec22 in vesicle trafficking within the infected host cell (Ayong et al, Eukaryotic Cell, Epub Jul 17, 2009). Next, to define the physiological function of the PfSec22 protein in Plasmodium parasites, we investigated its cognate partners. Using purified recombinant proteins we showed that PfSec22 forms direct binding interactions with six other PfSNAREs in vitro. These included the PfSyn5, PfBet1, PfGS27, PfSyn6, PfSyn16 and PfSyn18 PfSNAREs. By generating GFP-expressing parasites, we successfully localized the SNARE proteins PfSyn5, PfBet1 and PfGS27 to the parasite cis-Golgi compartment. We confirmed the association of PfSec22 with PfSyn5, PfBet1 and PfGS27 in vivo by immunoprecipitation analyses. Our data indicate a conserved ER-to-Golgi SNARE assembly in P. falciparum, and suggest that the malaria Sec22 protein might form novel SNARE complexes required for vesicle traffic within P. falciparum-infected erythrocytes
Show less
-
Date Issued
-
2009
-
Identifier
-
CFE0002852, ucf:48053
-
Format
-
Document (PDF)
-
PURL
-
http://purl.flvc.org/ucf/fd/CFE0002852