Person: Hemler, Martin
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Hemler
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Martin
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Hemler, Martin
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Publication Tetraspanin CD151 plays a key role in skin squamous cell carcinoma(2012) Li, Qinglin; Yang, Xiuwei H.; Xu, Fenghui; Sharma, Chandan; Wang, Hong-Xing; Knoblich, Konstantin; Rabinovitz, Isaac; Granter, Scott; Hemler, MartinHere we provide the first evidence that tetraspanin CD151 can support de novo carcinogenesis. During two-stage mouse skin chemical carcinogenesis, CD151 reduces tumor lag time and increases incidence, multiplicity, size, and progression to malignant squamous cell carcinoma (SCC), while supporting both cell survival during tumor initiation and cell proliferation during the promotion phase. In human skin SCC, CD151 expression is selectively elevated compared to other skin cancer types. CD151 support of keratinocyte survival and proliferation may depend on activation of transcription factor STAT3, a regulator of cell proliferation and apoptosis. CD151 also supports PKCα-α6β4 integrin association and PKC-dependent β4 S1424 phosphorylation, while regulating α6β4 distribution. CD151-PKCα effects on integrin β4 phosphorylation and subcellular localization are consistent with epithelial disruption to a less polarized, more invasive state. CD151 ablation, while minimally affecting normal cell and normal mouse functions, markedly sensitized mouse skin and epidermoid cells to chemicals/drugs including DMBA (mutagen) and camptothecin (topoisomerase inhibitor), as well as to agents targeting EGFR, PKC, Jak2/Tyk2, and STAT3. Hence, CD151 ‘co-targeting’ may be therapeutically beneficial. These findings not only support CD151 as a potential tumor target, but also should apply to other cancers utilizing CD151-laminin-binding integrin complexes.Publication Transcriptional profiling of stroma from inflamed and resting lymph nodes defines immunological hallmarks(Nature Publishing Group, 2012) Malhotra, Deepali; Fletcher, Anne Louise; Astarita, Jillian Leigh; Lukacs-Kornek, Veronika; Tayalia, Prakriti; Gonzalez, Santiago F.; Elpek, Kutlu G.; Chang, Sook Kyung; Knoblich, Konstantin; Hemler, Martin; Brenner, Michael; Carroll, Michael; Mooney, David; Turley, Shannon J.Lymph node stromal cells (LNSCs) closely regulate immunity and self-tolerance, yet key aspects of their biology remain poorly illuminated. Comparative transcriptomic analyses of murine LNSC subsets revealed expression of important immune mediators, growth factors, and novel structural components. Pairwise analyses of ligands and cognate receptors across hematopoietic and stromal subsets suggested a complex web of cross-talk. Compared with skin and thymic fibroblasts, fibroblastic reticular cells (FRCs) were enriched in genes relevant to cytokine signaling. LNSCs from inflamed lymph nodes upregulated acute phase response genes, chemokines, and antigen presentation genes. Poorly studied podoplanin−CD31− LNSCs showed similarities to FRCs, but lacked IL-7 expression, and were identified as myofibroblastic integrin α7+ pericytes. Together these data comprehensively describe the transcriptional characteristics of LNSC subsets.Publication β1 Integrins Show Specific Association with CD98 Protein in Low Density Membranes(BioMed Central, 2001) Kolesnikova, Tatiana V; Mannion, Brian A; Berditchevski, Fedor; Hemler, MartinBackground: The CD98 (4F2, FRP-1) is a widely expressed cell surface protein heterodimer composed of a glycosylated heavy chain and a non-glycosylated light chain. Originally described as a T cell activation antigen, it was later shown to function in amino acid transport, cell fusion and homotypic cell aggregation. Several lines of evidence suggest its functional interaction with integrins but the biochemical basis for this interaction has been unclear. Results: We demonstrate that CD98 constitutively and specifically associates with β1 integrins (α2β1,α3β1, α5β1 and α6β1), but minimally with α4β1. Integrin-CD98 association was established by reciprocal immunoprecipitation experiments, and confirmed by CD98-induced clustering of α3β1 but not α4β1 on the surface of rhabdomyosarcoma cells. Integrin-CD98 association is independent of the α subunit cytoplasmic tail, is maintained in α3β1 ligand-interaction deficient mutants, and is not inhibited by EDTA. Within the CD98 heavy chain, a C109S mutation (but not a C330S mutation) caused a loss of β1 integrin association. The same C109S mutation also caused a loss of CD98 light chain association. Importantly, CD98 associated selectively with β1 integrins present in low density "light membrane" fractions on a sucrose gradient. CD98 was not present in dense fractions that contained the majority of β1 integrins. Notably, the C109S mutant of CD98, that did not associate with β1 integrins, showed also a reduced localization into light membrane fractions. Conclusions: We demonstrate that CD98 association with β1 integrins is specific, occurs in the context of low density membranes, and may require the CD98 light chain.Publication Structural Organization and Interactions of Transmembrane Domains in Tetraspanin Proteins(BioMed Central, 2005) Kovalenko, Oleg V; Metcalf, Douglas G; DeGrado, William F; Hemler, MartinBackground: Proteins of the tetraspanin family contain four transmembrane domains (TM1-4) linked by two extracellular loops and a short intracellular loop, and have short intracellular N- and C-termini. While structure and function analysis of the larger extracellular loop has been performed, the organization and role of transmembrane domains have not been systematically assessed. Results: Among 28 human tetraspanin proteins, the TM1-3 sequences display a distinct heptad repeat motif (abcdefg)n. In TM1, position a is occupied by structurally conserved bulky residues and position d contains highly conserved Asn and Gly residues. In TM2, position a is occupied by conserved small residues (Gly/Ala/Thr), and position d has a conserved Gly and two bulky aliphatic residues. In TM3, three a positions of the heptad repeat are filled by two leucines and a glutamate/glutamine residue, and two d positions are occupied by either Phe/Tyr or Val/Ile/Leu residues. No heptad motif is apparent in TM4 sequences. Mutations of conserved glycines in human CD9 (Gly25 and Gly32 in TM1; Gly67 and Gly74 in TM2) caused aggregation of mutant proteins inside the cell. Modeling of the TM1-TM2 interface in CD9, using a novel algorithm, predicts tight packing of conserved bulky residues against conserved Gly residues along the two helices. The homodimeric interface of CD9 was mapped, by disulfide cross-linking of single-cysteine mutants, to the vicinity of residues Leu14 and Phe17 in TM1 (positions g and c) and Gly77, Gly80 and Ala81 in TM2 (positions d, g and a, respectively). Mutations of a and d residues in both TM1 and TM2 (Gly25, Gly32, Gly67 and Gly74), involved in intramolecular TM1-TM2 interaction, also strongly diminished intermolecular interaction, as assessed by cross-linking of Cys80. Conclusion: Our results suggest that tetraspanin intra- and intermolecular interactions are mediated by conserved residues in adjacent, but distinct regions of TM1 and TM2. A key structural element that defines TM1-TM2 interaction in tetraspanins is the specific packing of bulky residues against small residues.