Abstract

Gap junctional communication is essential for proper development and health of animal and human cardiac tissues. Gap junction channels establish communication by directly connecting the cytoplasm of adjacent cells. These channels are formed in vivo from several main proteins termed connexins that are coexpressed in embryonic and adult cardiac tissues. Since each connexin has its own perm-selectivity and gating properties, in vitro studies represent a strategy for understanding how the passage of endogenous metabolites through channels is regulated in vivo, and for determining how these connexins interact with one another to produce channels with new biophysical properties. We propose to continue our studies of gap junction channels formed by different cardiac connexins in order to further explore mechanisms that induce changes in permeability and selectivity.
For Specific Aim #1, we will determine, through site-directed mutagenesis, how interactions between carboxyl tails of connexins alter the permeability of connexons, by focusing mainly on the phosphorylation of connexin43.
In Specific Aim #2 we will use novel expression systems (funded during the previous cycle) to alter the ratio of individual connexins combined into the same connexon in order to determine the basic mechanism of selectivity to large molecules through these new channels, based on the size and charge of permeants, as well as changes in the charge of channels.
For Specific Aim #3, we will employ novel tissue culture systems to determine how newly formed channels alter permeability to endogenous metabolites; these systems will have the advantage of obtaining data from cells containing regulated expression of connexins. Finally, in Specific Aim #4, we will consolidate information obtained during previous aims to focus on the physiological relevance of changes in permeability and cell-to-cell communication in the differentiation of tissues. Our model will be a cultured tumor cell line whose membrane potential and growth depends upon direct communication through gap junctions. Collectively, these experiments will be built on observations made during the previous funding cycle, and will further establish the relevance of heteromerization as a novel system to regulate, not only gating, but also perm-selectivity of gap junction channels.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
5R01HL063969-07
Application #
7117767
Study Section
Electrical Signaling, Ion Transport, and Arrhythmias Study Section (ESTA)
Program Officer
Wang, Lan-Hsiang
Project Start
1999-12-01
Project End
2008-06-30
Budget Start
2006-07-01
Budget End
2007-06-30
Support Year
7
Fiscal Year
2006
Total Cost
$364,967
Indirect Cost

  Institution

Name
University of Utah
Department
Internal Medicine/Medicine
Type
Schools of Medicine
DUNS #
009095365
City
Salt Lake City
State
UT
Country
United States
Zip Code
84112

  Publications

Garciarena, Carolina D; Malik, Akif; Swietach, Pawel et al. (2018) Distinct moieties underlie biphasic H+ gating of connexin43 channels, producing a pH optimum for intercellular communication. FASEB J 32:1969-1981
Mondal, Abhijit; Appadurai, Daniel A; Akoum, Nazem W et al. (2017) Computational simulations of asymmetric fluxes of large molecules through gap junction channel pores. J Theor Biol 412:61-73
Kozoriz, Michael G; Bechberger, John F; Bechberger, Geralyn R et al. (2010) The connexin43 C-terminal region mediates neuroprotection during stroke. J Neuropathol Exp Neurol 69:196-206
Sachse, Frank B; Moreno, A P; Seemann, G et al. (2009) A model of electrical conduction in cardiac tissue including fibroblasts. Ann Biomed Eng 37:874-89
Sachse, Frank B; Moreno, Alonso P; Abildskov, J A (2008) Electrophysiological modeling of fibroblasts and their interaction with myocytes. Ann Biomed Eng 36:41-56
Moreno, Alonso P; Lau, Alan F (2007) Gap junction channel gating modulated through protein phosphorylation. Prog Biophys Mol Biol 94:107-19
Shen, Yongquan; Khusial, P Raaj; Li, Xun et al. (2007) SRC utilizes Cas to block gap junctional communication mediated by connexin43. J Biol Chem 282:18914-21
Moreno, Alonso P; Berthoud, Viviana M; Perez-Palacios, Gregorio et al. (2005) Biophysical evidence that connexin-36 forms functional gap junction channels between pancreatic mouse beta-cells. Am J Physiol Endocrinol Metab 288:E948-56
Zhong, G; Mantel, P L; Jiang, X et al. (2003) LacSwitch II regulation of connexin43 cDNA expression enables gap-junction single-channel analysis. Biotechniques 34:1034-9, 1041-4, 1046
Martinez, Agustin D; Hayrapetyan, Volodya; Moreno, Alonso P et al. (2002) Connexin43 and connexin45 form heteromeric gap junction channels in which individual components determine permeability and regulation. Circ Res 90:1100-7

Showing the most recent 10 out of 12 publications