Functional differences of class 1a PI 3-kinase heterodimers

Beeton, Carolyn Ann

January 2000

No description available.

572.8

Investigating cotranslational protein integration into the endoplasmic reticulum membrane

McCormick, Peter Joseph

17 February 2005

During co-translational integration, the transmembrane (TM) sequence of a nascent membrane protein moves laterally into the ER lipid bilayer upon reaching the translocon. Our lab has previously shown that this movement is a multistep process, but it was not clear whether the observed photocrosslinking of the TM segment to translocon proteins resulted from specific interactions or simply from TM-translocon proximity. If the latter, the TM α-helix will be oriented randomly with respect to translocon proteins, whereas, if the former, a specific TM helix surface would face TRAM and/or Sec61α. Integration intermediates were prepared by in vitro translation of truncated mRNAs in the presence of a Lys-tRNA analog with a photoreactive moiety attached to the lysine side-chain. When photoadduct formation was monitored as a function of probe location within the TM α-helix, we found that the extent of photocrosslinking to TRAM and Sec61α was non-random. Thus, the TM sequence occupies a distinct location within the translocon, a result that can only be achieved through protein-protein interactions that mediate the lateral movement, positioning, and integration of the TM sequence. In the case of multi-spanning membrane proteins, it was unknown how multiple hydrophobic regions integrated into the ER membrane. By placing photoprobes within each of several TM domains of a multi-spanning membrane protein, we were able to determine at what stage of integration each TM segment was no longer adjacent to translocon proteins. Using this approach we were able to establish a mechanism of integration for multi-spanning membrane proteins co-translationally inserted into the ER membrane.

Protein Trafficking

Membrane Protein

Integration

ER

Role of Ocrl1-dependent signaling abnormalities and mutation heterogeneity in Lowe Syndrome cellular phenotypes

Swetha Ramadesikan (9017243)

23 June 2020

<p>Lowe Syndrome (LS) is a lethal developmental disease characterized by mental retardation, cataracts at birth and kidney dysfunction. LS children unfortunately die by adolescence from renal failure. The gene responsible for the disease (<i>OCRL1</i>) encodes an inositol 5’ phosphatase Ocrl1. In addition to its 5’ phosphatase domain, this protein has other domains that allow protein-protein interactions, facilitating diverse sub-cellular distribution and functions. LS patient cells lacking Ocrl1 display defects in cell spreading, ciliogenesis and vesicle trafficking. Currently the mechanisms underlying these cellular defects are not known, and hence no LS-specific therapies exist. </p> <p>We have uncovered the mechanisms underlying two LS-specific cellular phenotypes- namely cell spreading and ciliogenesis and identified 2 FDA-approved candidates- statins and rapamycin that could revert these abnormalities. We found that Ocrl1-deficient cells exhibit hyperactivation in mTOR signaling, resulting in ciliogenesis as well as autophagy defects, which were rescued by administering rapamycin. We also identified a novel RhoGTPase signaling-dependent cell adhesion defect in LS patient cells which resulted in focal adhesion abnormalities and sensitivity to fluid shear stress (critical for kidney function). Both RhoGTPase signaling dependent cell spreading and adhesion defects were corrected by treatment with statins. </p> <p>Importantly, over 200 unique mutations in <i>OCRL1</i> cause LS and patients demonstrate heterogeneity in symptoms. However, the correlation between genotype and cellular phenotypes is unknown. We have determined that different <i>OCRL1</i> patient mutations have a differential impact on the two cellular phenotypes described above. Mutants exhibit behavior, sub-cellular distribution and cellular phenotypes unique to the domain and relevant to LS pathogenesis. We also propose that a subset of non-catalytic phosphatase domain mutations are conformationally affecting the protein, suggesting that LS has a conformational disease component. Importantly, we tested an FDA-approved drug, 4-phenyl butyric acid (4-PBA), used as a therapeutic in conformational diseases and found that it could revert phenotypes and restore the catalytic activity of these mutants. These findings collectively contribute to provide the cellular basis for LS patient heterogeneity as well as to propose a conformational disease component for LS (allowing the use of chemical chaperones as a therapeutic strategy for a subset of LS patients). Together, we hope that these studies will help lay the foundation of better prognosis and tailoring personalized therapeutic strategies for LS patients.</p>

Cell Biology

Genetics

Protein Trafficking

Lowe syndrome

STRUCTURAL BASIS OF LMAN1 CARGO CAPTURE IN ER & RELEASE IN ERGIC

Das, Vaijayanti

30 July 2012

No description available.

Biochemistry

Papillomavirus L2-Dependent Endocytosis and Subcellular Trafficking

Lu, Mingfeng, Lu, Mingfeng

January 2016

Human papillomaviruses (HPV) are among the most common sexually transmitted infections and are responsible for 5% of all human cancers. HPV type 16 is the most prevalent of the high-risk HPVs (a subgroup of HPVs with potential to cause cancer), accounting for ~55% of HPV-associated cancers. HPV16 is a nonenveloped virus, composed of the major capsid protein L1, the minor capsid protein L2, and a circular double-stranded DNA genome (vDNA) condensed with human histones. HPV initially infects undifferentiated basal keratinocytes and viral replication is dependent on epithelial differentiation. Like many other DNA viruses, HPV must deliver its vDNA to the host cell nucleus to successfully replicate. Initial binding of HPV16 to host cells is through L1 interactions with cell surface heparan sulfate receptors. Shortly after virus binding, L2 is believed to undergo furin cleavage-dependent conformational changes, resulting in spanning of the protein across the local membrane and exposure of the central and C-terminal regions of L2 (which was lumenal and and inaccessible before furin cleavage) to the host cell cytosol. L2 is critical for transport of the L2/vDNA from endosomes to the trans-Golgi network (TGN). We hypothesize that furin-dependent early L2 spanning, through the direct binding and recruitment of cytosolic sorting factors, may contribute to viral endocytosis and subcellular retrograde trafficking (trafficking from endosomes to Golgi) of vDNA. We have developed a Tac receptor (CD25 or IL2 receptor, a transmembrane cell surface protein) chimera system to study L2-dependent endocytosis and trafficking. In this system the Tac ecto- and transmembrane domains are fused to the ~400 amino acid portion of L2 that is likely cytosolic upon L2 spanning. Through transient expression of Tac-L2 chimera we use anti-Tac ectodomain antibodies to label and track cell surface populations by immunofluorescence and confocal microscopy. We have also adopted this system to study endocytosis through a cell surface biotinylation approach. Both approaches suggest that L2 may enhance endocytosis and preliminary evidence suggests that the Tac-L2 chimera may recruit the cytosolic retromer complex (the host cytosolic factors help protein retrograde trafficking) to preferentially traffic to the TGN. Retromer-dependent trafficking of cargo from early endosomes to the TGN is known to involve certain members of the sorting nexin family, specifically the SNX-BAR proteins. We performed a small siRNA screen and identify SNX6 and SNX32 (aka SNX6b) as SNX-BAR proteins that may be specifically involved in retrograde trafficking of HPV16 L2/vDNA during infection. Future work will focus on the mechanisms through which L2 and SNX6 influence HPV16 entry and trafficking.

L2 Protein

Protein Trafficking

Cellular and Molecular Medicine

Human Papillomavirus

Functional analysis of the deubiquitylating enzyme fat facets in mouse in protein trafficking.

Prodoehl, Mark

January 2008

Fat facets in Mouse (FAM) or mUSP9x is a deubiquitylating enzyme of the USP class. Knockdown of FAM protein levels in mouse pre-implantation embryos by antisense oligonucleotides is known to prevent embryos from progressing to the blastocyst stage indicating an important role for FAM in early mammalian development. In mammals, the Fam gene is located on the X-chromosome. In mice, the Y homologue, Dffry or usp9y, is expressed exclusively in the testes and maps to the Sxrb deletion (Brown et al., 1998). Sxrb is associated with an early post-natal blockage of spermatogonial proliferation and differentiation leading to absence of germ cells (Bishop et al., 1988; Mardon et al., 1989). The human Y homologue of Fam is closely associated with oligozoospermia (Sargent et al., 1999; Sun et al., 1999) and the human X homologue has been linked to the failure of oocytes to pass through the first meitoc prophase in Turner syndrome (Cockwell et al., 1991; Speed, 1986) Despite these associations, the substrates and precise role of Fam and its homologues in these processes have not yet been defined. Due to the complex nature of Fam expression and the lack of data tying FAM to specific cellular functions, much attention has been paid in identifying interacting partners and cellular targets of FAM activity to aid in the definition of its role in the cell and development. Three common molecular biology techniques were applied here in an attempt to further characterise known interactions of FAM, including interactions with the cell adhesion molecule β-catenin and the protein trafficking pathway proteins epsin-1 and itch. The aim of these investigations was to generate FAM mutants that could abolish individual interactions, enabling investigation of individual interactions in cellular function and development. These experiments failed to identify the amino acids of FAM that were critical for its interactions with β-catenin, epsin-1, or itch. Experiments aimed at characterising a novel ubiquitin-like domain located in the N-terminal half of the FAM protein, did however identify novel interactions of FAM with the three Golgi associated adaptor proteins GGA1, GGA2, and GGA3. Further investigations prompted by this interaction, examined the role of FAM in the trafficking of proteins from the Golgi apparatus. Cellular FAM protein levels were altered either by exogenous expression of FAM protein or knockdown of endogenous FAM using FAM specific shRNA triggers. The cellular protein levels and extent of post-translational modification of eleven lysosomal proteins were monitored in each case. It was found that increased FAM protein levels resulted in decreased cellular protein levels of five of the eleven lysosomal proteins studied. In contrast, a reduction in FAM protein levels was found to result in an increase in the cellular protein levels of eight of the eleven lysosomal proteins. This study provides the first evidence of a deubiquitylating enzyme that is able to interact with the GGA proteins. It is also the first to describe a deubiquitylating enzyme that can affect the biosynthesis of lysosomal proteins and provides valuable new insight into the cellular function of FAM/USP9X. / Thesis (Ph.D.) -- University of Adelaide, School of Molecular and Biomedical Sciences, 2008

Lysosomes.

Proteins.

Enzymes.

Proteomic and Molecular Genetic Investigation of Deubiquitinating Enzymes in the Budding Yeast Saccharomyces cerevisiae

Lam, Mandy Hiu Yi

23 February 2011

Protein ubiquitination is essential for the proper functioning of many eukaryotic cellular processes. The cleavage of ubiquitin chains from ubiquitinated proteins is performed by deubiquitinating enzymes, of which there are 16 in the Ubp (ubiquitin specific protease) group in the budding yeast Saccharomyces cerevisiae. The goal of my thesis has been to examine the biological roles and molecular functions of these enzymes using a combination of proteomic and molecular genetic approaches. As part of a large collaborative effort, interacting protein partners of the Ubps were isolated through affinity purification of tagged proteins, followed by protein identification by mass spectrometry. Purification of tagged Ubp6 led to the identification of the 19S proteasome complex, along with a novel subunit, Sem1. As the human homologue of Sem1 was previously identified as being associated with a protein involved in the repair of DNA double-strand breaks, I examined the possible role of Sem1 in DNA damage repair. A deletion of Sem1 and other 19S subunits resulted in hypersensitivity to various DNA damaging drugs, implicating the 19S complex in the process of DNA repair. iii I also found that purified Ubp2 interacted stably with the ubiquitin ligase Rsp5 and the protein Rup1. UBP2 interacts genetically with RSP5, indicating a functional relationship, while Rup1 facilitates the physical tethering of Ubp2 to Rsp5. Using the uracil permease Fur4, a Rsp5 substrate, as a model reporter, I found that ubp2Δ cells exhibited a temporal stabilization of Fur4 at the plasma membrane following the induction of endocytosis, implicating Ubp2 in protein sorting, specifically at the multivesicular body. In order to understand the role of Ubp2, I examined the effect of Ubp2 on Rsp5 function. I found that Rsp5, similar to its mammalian homologues, is auto-ubiquitinated in vivo, and that Ubp2 is able to directly deubiquitinate Rsp5 in vitro. Moreover, the presence of a substrate or Rup1 both resulted in increased autoubiquitination, implying an auto-inhibitory mechanism of Rsp5 regulation. Taken together, the data presented in this thesis implicate deubiquitinating enzymes in interesting and varied roles in the cell, and suggest a novel mechanism for the modulation of Rsp5-dependent trafficking processes.

molecular biology

ubiquitination

yeast

proteomics

genomics

protein trafficking

deubiquitination

0307

Proteomic and Molecular Genetic Investigation of Deubiquitinating Enzymes in the Budding Yeast Saccharomyces cerevisiae

Lam, Mandy Hiu Yi

23 February 2011

Protein ubiquitination is essential for the proper functioning of many eukaryotic cellular processes. The cleavage of ubiquitin chains from ubiquitinated proteins is performed by deubiquitinating enzymes, of which there are 16 in the Ubp (ubiquitin specific protease) group in the budding yeast Saccharomyces cerevisiae. The goal of my thesis has been to examine the biological roles and molecular functions of these enzymes using a combination of proteomic and molecular genetic approaches. As part of a large collaborative effort, interacting protein partners of the Ubps were isolated through affinity purification of tagged proteins, followed by protein identification by mass spectrometry. Purification of tagged Ubp6 led to the identification of the 19S proteasome complex, along with a novel subunit, Sem1. As the human homologue of Sem1 was previously identified as being associated with a protein involved in the repair of DNA double-strand breaks, I examined the possible role of Sem1 in DNA damage repair. A deletion of Sem1 and other 19S subunits resulted in hypersensitivity to various DNA damaging drugs, implicating the 19S complex in the process of DNA repair. iii I also found that purified Ubp2 interacted stably with the ubiquitin ligase Rsp5 and the protein Rup1. UBP2 interacts genetically with RSP5, indicating a functional relationship, while Rup1 facilitates the physical tethering of Ubp2 to Rsp5. Using the uracil permease Fur4, a Rsp5 substrate, as a model reporter, I found that ubp2Δ cells exhibited a temporal stabilization of Fur4 at the plasma membrane following the induction of endocytosis, implicating Ubp2 in protein sorting, specifically at the multivesicular body. In order to understand the role of Ubp2, I examined the effect of Ubp2 on Rsp5 function. I found that Rsp5, similar to its mammalian homologues, is auto-ubiquitinated in vivo, and that Ubp2 is able to directly deubiquitinate Rsp5 in vitro. Moreover, the presence of a substrate or Rup1 both resulted in increased autoubiquitination, implying an auto-inhibitory mechanism of Rsp5 regulation. Taken together, the data presented in this thesis implicate deubiquitinating enzymes in interesting and varied roles in the cell, and suggest a novel mechanism for the modulation of Rsp5-dependent trafficking processes.

molecular biology

ubiquitination

yeast

proteomics

genomics

protein trafficking

deubiquitination

0307

Functional analysis of the deubiquitylating enzyme fat facets in mouse in protein trafficking.

Prodoehl, Mark

January 2008

Fat facets in Mouse (FAM) or mUSP9x is a deubiquitylating enzyme of the USP class. Knockdown of FAM protein levels in mouse pre-implantation embryos by antisense oligonucleotides is known to prevent embryos from progressing to the blastocyst stage indicating an important role for FAM in early mammalian development. In mammals, the Fam gene is located on the X-chromosome. In mice, the Y homologue, Dffry or usp9y, is expressed exclusively in the testes and maps to the Sxrb deletion (Brown et al., 1998). Sxrb is associated with an early post-natal blockage of spermatogonial proliferation and differentiation leading to absence of germ cells (Bishop et al., 1988; Mardon et al., 1989). The human Y homologue of Fam is closely associated with oligozoospermia (Sargent et al., 1999; Sun et al., 1999) and the human X homologue has been linked to the failure of oocytes to pass through the first meitoc prophase in Turner syndrome (Cockwell et al., 1991; Speed, 1986) Despite these associations, the substrates and precise role of Fam and its homologues in these processes have not yet been defined. Due to the complex nature of Fam expression and the lack of data tying FAM to specific cellular functions, much attention has been paid in identifying interacting partners and cellular targets of FAM activity to aid in the definition of its role in the cell and development. Three common molecular biology techniques were applied here in an attempt to further characterise known interactions of FAM, including interactions with the cell adhesion molecule β-catenin and the protein trafficking pathway proteins epsin-1 and itch. The aim of these investigations was to generate FAM mutants that could abolish individual interactions, enabling investigation of individual interactions in cellular function and development. These experiments failed to identify the amino acids of FAM that were critical for its interactions with β-catenin, epsin-1, or itch. Experiments aimed at characterising a novel ubiquitin-like domain located in the N-terminal half of the FAM protein, did however identify novel interactions of FAM with the three Golgi associated adaptor proteins GGA1, GGA2, and GGA3. Further investigations prompted by this interaction, examined the role of FAM in the trafficking of proteins from the Golgi apparatus. Cellular FAM protein levels were altered either by exogenous expression of FAM protein or knockdown of endogenous FAM using FAM specific shRNA triggers. The cellular protein levels and extent of post-translational modification of eleven lysosomal proteins were monitored in each case. It was found that increased FAM protein levels resulted in decreased cellular protein levels of five of the eleven lysosomal proteins studied. In contrast, a reduction in FAM protein levels was found to result in an increase in the cellular protein levels of eight of the eleven lysosomal proteins. This study provides the first evidence of a deubiquitylating enzyme that is able to interact with the GGA proteins. It is also the first to describe a deubiquitylating enzyme that can affect the biosynthesis of lysosomal proteins and provides valuable new insight into the cellular function of FAM/USP9X. / Thesis (Ph.D.) -- University of Adelaide, School of Molecular and Biomedical Sciences, 2008

Lysosomes.

Proteins.

Enzymes.

Special features of vesicle trafficking in skeletal muscle cells

Kaisto, T. (Tuula)

31 October 2003

Abstract Skeletal muscles are composed of long, multinucleated cells called myofibers, which are highly differentiated cells and therefore unique in structure. In the present study the organization of the endocytic and exocytic pathways in isolated rat skeletal myofibers was defined with confocal and electron microscopic methods. In isolated myofibers the I band areas were shown to be active in endocytosis. The sorting endosomes were distributed in a cross-striated fashion while the recycling and late endosomal compartments were located to perinuclear areas and interfibrillar spaces, where they followed the course of microtubules. Protein trafficking in the different stages of muscle cell differentation was also analyzed. The studies with L6 myoblasts and myotubes showed that during myogenesis varying fractions of different viral glycoproteins were sorted from the endoplasmic reticulum (ER) into a specific compartment that did not recycle with the Golgi apparatus. This compartment is suggested to be the sarcoplasmic reticulum (SR). The studies with living muscle cells showed further changes in vesicle trafficking taking place during myogenesis. With GFP-tagged tsO45G protein, transport containers were detected in 20% of the infected myofibers, while all infected L6 myoblasts or myotubes showed intense movement of corresponding structures. We also detected significant differences between the pre-and post-Golgi traffickings in myofibers. When the distribution of the ER in adult myofibers was studied, the confocal microscopic data showed that the labeling patterns of the rough endoplasmic reticulum (RER) and the SR markers were different. Blocking of different cargo proteins in the RER revealed two discrete distribution patterns, neither of them identical with the SR. The collected electron microscopic data supported the idea that in mature myofibers there are two separate RER compartments. We suggest that the RER compartment capable of export function located around the myonuclei and on the Z lines, while the non-exporting RER compartment localized to terminal cisternae and probably took care of the synthesis of the SR proteins.

endocytosis

enveloped viruses

muscles

protein trafficking

sarcoplasmic reticulum