Cells within a tissue are autonomous units, yet constantly depend on signals from their surrounding. This information exchange is mediated by membrane proteins that assemble into localized, spatial and temporal organized multi-unit complexes. We will investigate on three levels how cells regulate subunit protein biosynthesis, complex assembly, and distribution of subunits within the complex. We use gap junctions as a model system. Gap junction channels cluster together comparable to claudins, cadherins, integrins, and acetylcholine receptors that are central to tight junctions, adherens junctions, desmosomes, hemidesmosomes, focal adhesions, and electrical synapses. We want to determine, especially in cells that co-express more than one connexin isoform (the gap junction channel subunit proteins) where exactly connexins are synthesized, where they begin to interact, how they are trafficked to the plasma membrane, how cells build the channel cluster, and find helper proteins that aid in these processes (aim I). Furthermore, we want to identify specific signals presumably located within the connexin polypeptide sequences that control subunit compatibility and channel composition; and determine whether aberrant connexin interactions can lead to disease (aim II). Finally, we want to find out how cells control the distribution of channels within a cluster (aim III). The approach includes to construct and express fluorescence tagged connexins, amino acid exchange variants, disease mutants, and chimeras in novel cell-free, cell-based, and live-cell systems that we have developed, track connexins in living cells by high-resolution, multi-color time lapse microscopy, determine their interaction, and use biochemical and immunological approaches to characterize helper proteins and probe channel environments. Results will provide significant novel insight into the biosynthesis, subunit assembly, composition, and function of gap junctions and of other oligomeric membrane structures; they will elucidate mechanistic principles of connexin related diseases; and they will aid in understanding the dynamic structural composition of other localized membrane signaling.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM055725-07
Application #
6944913
Study Section
Cell Development and Function Integrated Review Group (CDF)
Program Officer
Shapiro, Bert I
Project Start
1998-02-01
Project End
2007-08-31
Budget Start
2005-09-01
Budget End
2006-08-31
Support Year
7
Fiscal Year
2005
Total Cost
$236,803
Indirect Cost
Name
Lehigh University
Department
Biology
Type
Schools of Arts and Sciences
DUNS #
808264444
City
Bethlehem
State
PA
Country
United States
Zip Code
18015
Kells-Andrews, Rachael M; Margraf, Rachel A; Fisher, Charles G et al. (2018) Connexin-43 K63-polyubiquitylation on lysines 264 and 303 regulates gap junction internalization. J Cell Sci 131:
Thévenin, Anastasia F; Margraf, Rachel A; Fisher, Charles G et al. (2017) Phosphorylation regulates connexin43/ZO-1 binding and release, an important step in gap junction turnover. Mol Biol Cell 28:3595-3608
Falk, Matthias M; Bell, Cheryl L; Kells Andrews, Rachael M et al. (2016) Molecular mechanisms regulating formation, trafficking and processing of annular gap junctions. BMC Cell Biol 17 Suppl 1:22
Nimlamool, Wutigri; Andrews, Rachael M Kells; Falk, Matthias M (2015) Connexin43 phosphorylation by PKC and MAPK signals VEGF-mediated gap junction internalization. Mol Biol Cell 26:2755-68
Kowal, Tia J; Falk, Matthias M (2015) Primary cilia found on HeLa and other cancer cells. Cell Biol Int 39:1341-7
Falk, Matthias M; Kells, Rachael M; Berthoud, Viviana M (2014) Degradation of connexins and gap junctions. FEBS Lett 588:1221-9
Fong, John T; Nimlamool, Wutigri; Falk, Matthias M (2014) EGF induces efficient Cx43 gap junction endocytosis in mouse embryonic stem cell colonies via phosphorylation of Ser262, Ser279/282, and Ser368. FEBS Lett 588:836-44
Wang, Shaojie; Kowal, Tia J; Marei, Mona K et al. (2013) Nanoporosity significantly enhances the biological performance of engineered glass tissue scaffolds. Tissue Eng Part A 19:1632-40
Thevenin, Anastasia F; Kowal, Tia J; Fong, John T et al. (2013) Proteins and mechanisms regulating gap-junction assembly, internalization, and degradation. Physiology (Bethesda) 28:93-116
Fong, John T; Kells, Rachael M; Falk, Matthias M (2013) Two tyrosine-based sorting signals in the Cx43 C-terminus cooperate to mediate gap junction endocytosis. Mol Biol Cell 24:2834-48

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