Wong Siew Heng
Email Address
micwsh@nus.edu.sg
Organizational Units
NON NUS ORGANISATIONS
faculty
YONG LOO LIN SCH OF MEDICINE
faculty
37 results
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Publication Localization of the Lys, Asp, Glu, Leu tetrapeptide receptor to the Golgi complex and the intermediate compartment in mammalian cells(1994-12) Griffiths, G.; Ericsson, M.; Krijnse-Locker, J.; Nilsson, T.; Goud, B.; Söling, H.-D.; Tang, B.L.; Wong, S.H.; Hong, W.; INSTITUTE OF MOLECULAR & CELL BIOLOGYThe carboxyl-terminal Lys-Asp-Glu-Leu (KDEL), or a closely-related sequence, is important for ER localization of both lumenal as well as type II membrane proteins. This sequence functions as a retrieval signal at post-ER compartment(s), but the exact compartment(s) where the retrieval occurs remains unresolved. With an affinity-purified antibody against the carboxyl- terminal sequence of the mammalian KDEL receptor, we have investigated its subcellular localization using immunogold labeling on thawed cryosections of different tissues, such as mouse spermatids and rat pancreas, as well as HeLa, Vero, NRK, and mouse L cells. We show that rab1 is an excellent marker of the intermediate compartment, and we use this marker, as well as budding profiles of the mouse hepatitis virus (MHV) in cells infected with this virus, to identify this compartment. Our results demonstrate that the KDEL receptor is concentrated in the intermediate compartment, as well as in the Golgi stack. Lower but significant labeling was detected in the rough ER. In general, only small amounts of the receptor were detected on the trans side of the Golgi stack, including the trans-Golgi network (TGN) of normal cells and tissues. However, some stress conditions, such as infection with vaccinia virus or vesicular stomatitis virus, as well as 20°C or 43°C treatment, resulted in a significant shift of the distribution towards the trans-TGN side of the Golgi stack. This shift could be quantified in HeLa cells stably expressing a TGN marker. No significant labeling was detected in structures distal to the TGN under all conditions tested. After GTPγS treatment of permeabilized cells, the receptor was detected in the β-COP-containing buds/vesicles that accumulate after this treatment, suggesting that these vesicles may transport the receptor between compartments. We propose that retrieval of KDEL-containing proteins occurs at multiple post-ER compartments up to the TGN along the exocytotic pathway, and that within this pathway, the amounts of the receptor in different compartments varies according to physiological conditions.Publication A novel CARD containing splice-isoform of CIITA regulates nitric oxide synthesis in dendritic cells(2010-03) Huang, D.; Lim, S.; Chua, R.Y.R.; Shi, H.; Ng, M.L.; Wong, S.H.; MICROBIOLOGYMHC class II expression is controlled mainly at transcriptional level by class II transactivator (CIITA), which is a non-DNA binding coactivator and serves as a master control factor for MHC class II genes expression. Here, we describe the function of a novel splice-isoform of CIITA, DC-expressed caspase inhibitory isoform of CIITA (or DC-CASPIC), and we show that the expression of DCCASPIC in DC is upregulated upon lipopolysaccharides (LPS) induction. DC-CASPIC localizes to mitochondria, and protein-protein interaction study demonstrates that DC-CASPIC interacts with caspases and inhibits its activity in DC. Consistently, DC-CASPIC suppresses caspases-induced degradation of nitric oxide synthase-2 (NOS2) and subsequently promotes the synthesis of nitric oxide (NO). NO is an essential regulatory molecule that modulates the capability of DC in stimulating T cell proliferation/activation in vitro; hence, overexpression of DC-CASPIC in DC enhances this stimulation. Collectively, our findings reveal that DC-CASPIC is a key molecule that regulates caspases activity and NO synthesis in DC. © 2010 Higher Education Press and Springer-Verlag Berlin Heidelberg.Publication A novel antiinflammatory role for andrographolide in asthma via inhibition of the nuclear factor-κb pathway(2009) Bao, Z.; Guan, S.; Cheng, C.; Wu, S.; Fred, Wong W.S.; Wong, S.H.; Michael, Kemeny D.; Leung, B.P.; PHARMACOLOGY; MICROBIOLOGYPublication Cytosolic factors block antibody binding to the C-terminal cytoplasmic tail of the KDEL receptor(1994) Tang, B.L.; Wong, S.H.; Low, S.H.; Subramaniam, V.N.; Hong, W.; INSTITUTE OF MOLECULAR & CELL BIOLOGYThe mammalian KDEL receptor is an extremely hydrophobic membrane protein. One of the longest stretches of hydrophilic sequence resides at the C-terminus. Various antibodies against a synthetic peptide corresponding to this region confirmed that the C-terminus is exposed to the cytoplasm. It was observed that antibody binding to the C-terminus of the KDEL receptor was diminished during immunofluorescence microscopy procedures which involved fixation prior to permeabilization as compared to when cells were permeabilized before fixation. Binding of both polyclonal and monoclonal antibodies, as assessed by indirect immunofluorescence microscopy in digitonin permeabilized cells, was inhibited by preincubation with rat liver cytosol. This inhibition was not observed with antibody against another membrane protein (p28) with a cytoplasmically exposed epitope also residing in the Golgi/intermediate compartment. Rabbit reticulocyte lysate had a similar effect while Schizosaccharomyces pombe cytosol inhibited binding to a greater degree than Saccharomyces cerevisiae cytosol. This inhibition by cytosol was prevented by coincubation with the antibody and was dose-dependent on the cytosol. Inhibition did not occur on ice or at 15°C, or when the cytosol was energy-depleted by apyrase treatment. Interestingly, pretreatment of permeabilized cells with N-ethylmaleimide or its addition into the incubation mixture abolished inhibition. N-ethylmaleimide-treated cytosol, however, remained inhibitory. The findings suggest the existence of cytosolic factor(s) which interacts specifically with the cytoplasmic C-terminus of the KDEL receptor, which are likely to be components of the KDEL protein retrieval machinery.Publication Retardation of a surface protein chimera at the cis Golgi(1995) Low, S.H.; Tang, B.L.; Wong, S.H.; Hong, W.; INSTITUTE OF MOLECULAR & CELL BIOLOGYDipeptidyl peptidase IV (D4) and the α subunit of human chorionic gonadotrophin (αhcg) are plasma membrane and secretory proteins, respectively. In the course of studies to understand mechanisms involved in transport along the exocytotic pathway, the ectoplasmic domain of D4 was replaced by the mature polypeptide of αhcg, resulting in the membrane anchored chimera, D4αhcg. Surprisingly, when transfected into Chinese hamster ovary (CHO) and Madin-Darby canine kidney (MDCK) cells, strong perinuclear Golgi staining was predominant, in addition to the expected surface staining. By following the biogenesis and transport of the molecule, it was established that newly synthesized D4αhdg is eventually transported to the cell surface but only after a significant retardation in the Golgi apparatus. The compartment of retardation was identified as the early or cis Golgi, before the medial Golgi, where resistance to endoglycosidase (endo) H is conferred. As a result of the transport retardation of the chimera, we were able to document the appearance of an endo D sensitive intermediate, which is usually too transient to be apparent in normal cells. The retardation of this chimera in the cis Golgi complements our previous report in which the D4 molecule with its transmembrane domain replaced by that of aminopeptidase N resulted in retardation in the trans Golgi/trans Golgi network in MDCK and CHO cells [Low, S. H., Tang, B. L., Wong, S. H., & Hong, W. (1994) J. Biol. Chem. 269, 1985-1994). Together, these reports indicate that transport along the exocytic pathway may not be simply by default but requires some sort of signal, the disruption of which results in inefficient intra-Golgi and/or Golgi to surface transport. © 1995 American Chemical Society.Publication Effects of NH4Cl and nocodazole on polarized fibronectin secretion vary amongst different epithelial cell types.(1994-01) Low, S.H.; Wong, S.H.; Tang, B.L.; Hong, W.; INSTITUTE OF MOLECULAR & CELL BIOLOGYThe extracellular matrix protein fibronectin was found to be secreted by three polarized epithelial cell lines Madin-Darby canine kidney (MDCK), Caco-2 and LLC-PK1. About 54 and 46% of fibronectin was secreted from the apical and basolateral cell surfaces, respectively, in MDCK cells. In Caco-2 and LLC-PK1 cells, the majority (about 92-93%) of fibronectin secretion occurs from the basolateral cell surface, with the remaining 7-8% from the apical surface. In all three cell types, NH4Cl was found to inhibit basolateral secretion (resulting in enhanced apical secretion), while total fibronectin secretion was not significantly affected (although a delay in secretion was observed). Nocodazole reduced total fibronectin secretion to about 70% of control levels in MDCK and Caco-2 cells, with significant inhibition on secretion from both surfaces. In contrast, total fibronectin secretion was enhanced by nocodazole in LLC-PK1 cells. Furthermore, the majority of fibronectin secretion was redirected to the apical cell surface in LLC-PK1 cells. These observations demonstrate that the nature as well as the extent of the effects of NH4-Cl and nocodazole on polarized fibronectin secretion varies amongst different epithelial cell types.Publication Targeting the ‘Undruggable’ Driver Protein, KRAS, in Epithelial Cancers: Current Perspective(MDPI AG, 2023-02-01) Lam, KK; Wong, SH; Cheah, PY; Assoc Prof Peh Yean Cheah; MICROBIOLOGY AND IMMUNOLOGY; SAW SWEE HOCK SCHOOL OF PUBLIC HEALTHThis review summarizes recent development in synthetic drugs and biologics targeting intracellular driver genes in epithelial cancers, focusing on KRAS, and provides a current perspective and potential leads for the field. Compared to biologics, small molecule inhibitors (SMIs) readily penetrate cells, thus being able to target intracellular proteins. However, SMIs frequently suffer from pleiotropic effects, off-target cytotoxicity and invariably elicit resistance. In contrast, biologics are much larger molecules limited by cellular entry, but if this is surmounted, they may have more specific effects and less therapy-induced resistance. Exciting breakthroughs in the past two years include engineering of non-covalent KRAS G12D-specific inhibitor, probody bispecific antibodies, drug–peptide conjugate as MHC-restricted neoantigen to prompt immune response by T-cells, and success in the adoptive cell therapy front in both breast and pancreatic cancers.Publication Involvement of both vectorial and transcytotic pathways in the preferential apical cell surface localization of rat dipeptidyl peptidase IV in transfected LLC-PK1 Cells(1991-10-15) Low, S.H.; Wong, S.H.; Tang, B.L.; Hong, W.; INSTITUTE OF MOLECULAR & CELL BIOLOGYDipeptidyl peptidase IV (DPPIV) is a membrane glycoprotein with type II orientation. It is predominantly localized to the apical surface in epithelial cells. Previous studies (Bantles, J. P., Feracci, H. M., Shinger, B., and Hubbard, A. L. (1987) J. Cell Biol. 105, 1241-1251) using cellular fractionation and immunoprecipitation in rat liver suggest that DPPIV is targeted to the apical surface by an indirect pathway through transient appearance in the basolateral surface followed by specific transcytosis to the apical domain. In transfected Madin-Darby canine kidney (MDCK) cells using domain-selective biotinylation and streptavidin absorption, it was, however, shown that DPPIV is directly sorted to the apical surface (Low, S. H., Wong, S. H., Tang, B. L. Subramaniam, V. N., and Hong, W. (1991) J. Biol. Chem, 266, 13391-13396). These studies suggest that the sorting pathway for DPPIV may be cell type-specific, but it cannot be ruled out that the observed difference in the DPPIV sorting pathway may be due to different methods employed for dissecting the sorting pathway. In this study, we have expressed rat DPPIV, using an expression system driven by the Rous sarcoma virus enhancer and the SV40 early promoter region, in another epithelial cell line, LLC-PK1. As in MDCK cells, DPPIV is preferentially (about 90%) localized to the apical surface. Employing identical methods used previously in MDCK cells, it was found that both direct and transcytotic pathways are involved in the apical surface localization of DPPIV in this epithelial cell type. These observations clearly illustrate that the sorting pathway of rat DPPIV is cell type-specific.Publication Golgi retardation in Madin-Darby canine kidney and Chinese hamster ovary cells of a transmembrane chimera of two surface proteins(1994-01-21) Low, S.H.; Tang, B.L.; Wong, S.H.; Hong, W.; INSTITUTE OF MOLECULAR & CELL BIOLOGYDipeptidyl peptidase IV (DDD) is a type II plasma membrane protein. Replacement of its transmembrane domain with that of another surface protein, aminopeptidase N, resulted in accumulation in the Golgi apparatus of Madin- Darby canine kidney cells and a delayed Golgi to surface transport in Chinese hamster ovary (CHO) cells. The compartment of retardation was identified as post medial-Golgi, most likely to be the trans-Golgi/trans Golgi network (TGN). Compared to native DDD, the rate of endoplasmic reticulum to Golgi transport for the chimera was largely unchanged in both cell types. On the other hand, Golgi to surface transport was delayed by more than 2 h in CHO cells and essentially undetectable up to 22 h of chase in Madin-Darby canine kidney cells. The decrease in the rate of Golgi to surface transport in CHO cells resulted in a significant accumulation of the fusion protein in the trans-Golgi/TGN. This phenomena is very unlikely to be due to any drastic conformational changes, as neither the enzyme activity nor the dimerization of the constructed molecule was affected. The findings of this study indicate that the transmembrane domain, in the context of its flanking sequences, is important for efficient Golgi to cell surface transport.Publication Vesicle-associated membrane protein-8/endobrevin negatively regulates phagocytosis of bacteria in dendritic cells(2008) Ho, Y.H.S.; Deyu, T.C.; Huang, D.; Siew, H.W.; Wang, C.-C.; MICROBIOLOGY