A Novel Device for Cell-Cell Electrofusion

Stewart, Justin T.

01 January 2011

Cell transplantation therapy is a potentially powerful tool and can be used to replace defective cells with healthy cells. This offers the possibility of alleviating the destructive symptoms for many diseases such as Parkinson's disease, Alzheimer's disease, stroke, spinal cord trauma, Type I diabetes and many more. While there are many diseases that could be positively impacted from cell transplantation therapy, the focus of this research is insulin dependent, Type I Diabetes. The Islets of Langerhans are composed of various types of cells located in the pancreas and are responsible for a variety of biochemical functions. Specifically, the beta Islet cells are responsible for production of the hormone insulin that regulates and aids in biosynthesis of glucose. Transplantation of isolated allografted pancreatic islets, which contain insulin producing cells, into diabetic rats has proven to be highly successful. However, these transplantations involve using medications for long term immunosuppression to defend against an undesired host immune response. Immunosuppressive medications are both costly and illicit additional side effects that can be detrimental to the host. This research focuses on the use of testicular derived Sertoli cells that have been publicized to provide localized immunoprotection. Electrofusion is a process that can be used to fuse homogeneous and heterogeneous cell types by promoting the creation of micropores in the cell's lipid bilayer. This renders the cell temporarily fusogenic, or capable of facilitating fusion. Cells must then be brought into contact with one another via mechanical, chemical or viral means. This research study proposes to optimize electrofusion technology to create novel, secretory hybrids composed of Islet and Sertoli cells that are immunoprotected and produce insulin in response to a glucose challenge. The components of the electrofusion device include a Sterlitech 0.2 ìm microporous membrane, a woven cellulose absorbent pad, two aluminum electrodes and a chamber body and top injection molded using Delrin. Preliminary experiments using B16-F10 murine melanoma cells incorporated with centrifugation to increase cell to cell contact resulted in an average fusion yield of 18.9% ± 8.1 SD using a field strength of 2500 V/cm, 8 pulses and a 250 ìs pulse length. Additionally, lab synthesized electroporation buffers containing 8.5% sucrose (w/v) and 0.3% glucose increased total and viable fusion yields to 37.1% ± 9.3 SD and 13.8% ± 2.1 SD, respectively. These results showed promise and should be further validated with additional cell lines and tissues to corroborate reproducibility.

Allograft

Electropermeabilization

Fusogenic

Immunosuppresion

Xenograft

American Studies

Arts and Humanities

Biology

Biostatistics

Characterization of the H10/A4 Region of Vesicular Stromatitis Virus G Protein and Effects of H2-H10/A4 Mutations of Fusogenic Functions / VSV G H10/A4 Mutants and H2-H10/A4 Double Mutants

Shokralla, Shahira

11 1900

The vesicular stomatitis virus glycoprotein G is responsible for low pH mediated membrane fusion induced by the virus. Four linker insertion mutants (H2, H5, HIO, A4) of the G ectodomain were found to disrupt fusion and yet maintained all the requirements for proper folding and cell surface expression (Li et al., 1993). Site specific mutagenesis of residues 123 to 137, surrounding the H2 mutant, either blocked or shifted the pH optima and threshold of fusion to more acidic values with a concomitant reduction in cell-cell fusion efficiency (Zhang and Ghosh, 1994; Fredericksen and Whitt, 1995). The region is highly conserved among vesiculoviruses and was found to insert into lipid membranes by hydrophobic photolabelling (Durrer et al., 1995) suggesting a possible role for this domain as the fusion peptide. Site-directed mutagenesis of residues 190 to 210, surrounding the H5 insertion mutant, did not significantly affect fusion (Fredericksen and Whitt, 1995). Surrounding the H10 and A4 insertion mutants is a conserved region, residues 395 to 424, that does not interact with target membranes (Durrer et al., 1995). To determine the functional importance of this region, site-directed mutagenesis was employed. Substitution of conserved Gly 404, Gly 406, Asp 409, and Asp 411 with Ala, Ala, Asn, and Asn, respt:.ctively, both reduced fusion and caused a shift in the pH of fusion threshold to more acidic values (tested by Y. He as published in Shokralla et al., 1998). In this study, the Hl0/A4 region is further mutagenized and tested for fusion. Cell surface expression was examined by indirect immunofluorescence and lactoperoxidase catalyzed iodination. Rates of transport from the endoplasmic reticulum and oligomerization into trimers were tested by resistance to endoglycosidase H and sucrose density gradient centrifugation, respectively. Low-pH induced conformational changes were assayed by resistance to proteolytic digestion. Residues Gly 395, Gly 404, Gly 409 and Ala 418 were substituted with Glu, Lys, Asp, and Lys, respectively. All mutants, with the exception of A418K, were expressed at levels similar to or above wild-type. Mutants G404K and D409A completely abolished fusion. Mutant G395E reduced cell-cell fusion efficiency by 82% and shifted both the pH threshold and optimum of wild type fusion. Although all mutants were capable of trimer formation, alterations in the structure of mutants G404K, D409 A, and A418K were detected by slower transport rates. All Hl0/A4 mutants were more susceptible to trypsin than wild-tyr,e at the pH of6.5, and mutant G404K was completely susceptible at this pH Reductions in the extent of fusion, along with shifts in the pH optima and thresholds of fusion suggest that the Hl0/A4 region (residues 395 to 418) of vesicular stomatitis virus G protein is important for G mediated fusion. The region may influence low-pH induced conformational changes. Double mutants of the H2 and HI0/A4 regions were also tested for their effects on fusion. The extents of fusion mediated by double mutant G proteins were severely reduced with levels ranging from 28% wild-type fusion to complete fusion deficiency. Only mutant Gl31A G404A was capable of 83% wild-type fusion. Mutants Gl31A G395E, Gl31A G404A, Gl31A D4LIN, Dl37N G404A, and the fusion defective D137N D411N were expressed at levels above wild-type G protein at the cell surface. Mutants Fl25Y D411N and Pl26L D411N, although capable of very low levels of fusion were not detectable at the cell surface by immunoflorescence and were detected at low levels by lactoperoxidase catalyzed iodination of cell surface proteins. These two mutants, along with Gl31A G404A, also showed slower transport rates than wild-type G. All double mutants showed increased sensitivity to trypsin at the pH of 6.5 with mutant Fl25Y D411N showing complete susceptibility. They were also all capable of trimer formation by sucrose density gradient centrifugation. In comparing the fusion profiles of double mutants with those of their component single mutants, it was found that in most cases the pH threshold of fusion by double mutants was greater than the sum of the single mutants and that the pH optimum of fusion corresponded to that of the constituent H2 single mutant. Although, the regions are functionally independent, they may indirectly affect one another through alterations in protein structure. / Thesis / Master of Science (MS)

H10/A4 region

vesicular stomatitis

virus G protein

H2-H10/A4

mutations

fusogenic functions

Influence of the Membrane Anchoring and Cytoplasmic Domains on the Fusogenic Activity of Vesicular Stomatitis Virus Glycoprotein G

Odell, Derek A.

04 1900

Relatively little is known about the vesicular stomatitis virus (VSV) glycoprotein G fusion mechanism. Vesicular stomatitis virus has a single type 1 integral membrane glycoprotein G embedded in the viral membrane. It is the only viral protein required for VSV induced low pH mediated fusion. Mutations in four regions (H2, A5, A4 and HI0) of the VSV G ectodomain have been shown to abolish the fusion activity of the viral glycoprotein (Li et al.,l993). One region H2 (a.a 117-139) has been suggested to be the fusion peptide (Zhang and Ghosh, 1994)(Fredericksen and Whitt, 1995). Amino acids 59-221 of the G protein, an area that encompasses the H2 region, has recently been shown to interact with liposomes through hydrophobic photolabeling experiments (Durrer et al., 1995), suggesting that the H2 region (fusion peptide)is able to interact with hydrophobic target bilayers at low pH. A soluble VSV G protein lacking the transmembrane anchor and cytoplasmic tail of VSV G is not fusogenic, suggesting that G must be anchored to the plasma membrane to promote syncytia (Florkiewicz and Rose, 1984). To better understand the steps involved in the fusion mechanism of VSV G it is important to identify domains within the protein that are involved in the fusion process. To determine the contributions of the transmembrane anchor and cytoplasmic tail to the VSV fusion mechanism chimeric G proteins were constructed. The transmembrane anchor alone or in conjunction with the cytoplasmic tail ofVSV G was replaced with equivalent domain from other viral proteins, HSV-1 glycoproteins gB and gD, adenovirus E3 11.6 K gene, that are not involved in low-pH fusion and the cellular protein CD4. All chimeras were expressed in COS-1 cells, glycosylated, oligomerized, transported to the cdl surface, showed a low-pH induced conformational change and were expressed on the cell surface at levels equivalent to wild-type G. The transmembrane hybrids show extensive syncytia formation at levels similar to wild-type G when induced at pH 5.6. The transmembrane-cytoplasmic tail hybrids showed reduced levels of syncytia as compared to wild-type Gat both pH 5.6 and 5.2. A glycosylphosphatidylinositollipid-anchored ectodomain of G (GGPI), which lacks both the transmembrane and cytoplasmic tail ofG, was expressed in COS-1 cells. The GGPI chimera was glycosylated, expressed on the cell surface,and oligomerized similar to wild-type G. However the chimera was fusion negative, could not promote lipid mixing and h~,d an altered tryptic digestion profile. A fusion negative chimera Gt12gBwas constructed by exchanging the TM of G with the equivalent domain from HSV-1 gB TM plus eight extra amino acids of the gB ectodomain. Deletion of the 11 extra gB amino acids (GgB3G) restored the fusogenic activity of this chimera. Another chimera G 10 DAF directly demonstrated that the fusion negative phenotype of GGPI, like chimera Gtii1Lll2gB, was a result of the 10 extra amino acids at the EC-TM interface. The ectodomain (EC)-transmembrane (TM) interface is highly conserved among 5 vesiculoviruses. Chimeras with a 9 amino acid insertion (GlODAF), deletion (G~9) or replacement (G~910DAF) were expressed in COS-1 cells. The expressed proteins were glycosylated, underwent a low-pH induced conformational change and were expressed on the cell surface at levels equivalent to wild type, but were fusion negative. Suggesting that both the sequence and spatial arrangement of amino acids at the EC-TM interface may affect VSV G fusion. Taken together the data suggests that the specific amino acid sequence of the transmembrane anchor of VSV G is not essential for fusion. Replacement of the TM of VSV G with equivalent domains from other viral and cellular proteins does not affect the fusion activity. The cytoplasmic tail of VSV G may form an entity alone or in conjunction with the transmembrane anchor that can regulate fusion. Another region in the ectodomain of VSV G renders the glycoprotein fusion sensitive in a cell-cell fusion assay and was characterized at the EC-TM interface. / Thesis / Master of Science (MS)

membrane anchoring

cytoplasmic domains

fusogenic activity

vesicular stomatitis

virus glycoprotein g

Molecular characterisation of Broome virus, a new fusogenic orthoreovirus species.

Claudia Thalmann

Unknown Date

This thesis describes the molecular characterisation of Broome virus (BroV), a new fusogenic orthoreovirus species that was isolated from a little red flying-fox (Pteropus scapulatus) in Broome, Western Australia in 2002. The BroV genome consists of ten segments of dsRNA, each containing a plus-strand with a 3’ terminal pentanucleotide sequence that is conserved amongst all viruses in the genus Orthoreovirus, family Reoviridae, and a 5’ terminal pentanucleotide sequence that is unique to BroV. With the exception of S4, all genome segments are predicted to encode a single translation product producing a total of seven structural and four nonstructural proteins. All BroV proteins were identified as homologues of known orthoreovirus proteins and shown to have similar secondary structure and possess key conserved amino acid sequence motifs and structural features implicated in biological function. Notably, no cell-attachment protein gene homologue was identified in the BroV genome suggesting the use of an alternate cell entry mechanism to that employed by most orthoreoviruses. The amino acid sequence identity between cognate BroV proteins and those of other orthoreoviruses ranges from 13-50%, which is too low for BroV to be considered a new isolate of any established orthoreovirus species group. Phylogenetic analyses based on both structural and nonstructural proteins provide additional evidence to support this claim. It is proposed that BroV is the prototype member of a new sixth species group Broome virus, in the genus Orthoreovirus. The complete genome characterisation of BroV provided an opportunity to produce recombinant proteins in Escherichia coli and to generate polyclonal antibodies in rabbits for use in research and surveillance. Such reagents proved valuable in the experimental identification of the fusion-associated small transmembrane (FAST) protein p13 that is responsible for the syncytia observed in BroV-infected cells. Despite the low amino acid sequence identity between the FAST proteins of different orthoreovirus species they possess conserved structural features that have been implicated in biological function. Of these conserved features, the BroV p13 protein is predicted to possess one transmembrane domain, a C-terminal polybasic region, a C-terminal hydrophobic patch and an N-terminal myristoylation consensus sequence. The unique repertoire and arrangement of sequence-predicted structural features identified in p13 indicate that it is a novel fifth member of the FAST protein family. The BroV-specific immunological reagents were also used to develop an enzyme-linked immunosorbent assay (ELISA) suitable for serological screening. A survey of flying-foxes from Papua New Guinea (PNG) revealed that BroV or BroV-like viruses are currently circulating in these animals. This demonstrates that BroV is not limited to the Australian continent.