A voltage-dependent gap junction in Drosophila melanogaster.

HOME

HELP

FEEDBACK

SUBSCRIPTIONS

A voltage-dependent gap junction in Drosophila melanogaster.

V K Verselis, M V Bennett and T A Bargiello

Albert Einstein College of Medicine, Bronx, New York 10461.

ABSTRACT

Steady-state and kinetic analyses of gap junctional conductance,gi, in salivary glands of Drosophila melanogaster third instarlarvae reveal a strong and complex voltage dependence that canbe elicited by two types of voltages. Voltages applied betweenthe cells, i.e., transjunctional voltages, Vj, and those appliedbetween the cytoplasm and the extracellular space, inside-outsidevoltages, Vi,o, markedly alter gj. Alteration of Vi-o whileholding Vj = O,i.e., by equal displacement of the voltages inthe cells, causes gj to increase to a maximum on hyperpolarizationand to decrease to near zero on depolarization. These conductancechanges associated with Vi-o are fit by a model in which thereare two independent gates in series, one in each series, onein each membrane, where each gate is equally sensitive to Vi-oand exhibits first order kinetics. Vj's generated by applyingvoltage steps of either polarity to either cell, substantiallyreduce gj. These conductance changes exhibit complex kineticsthat depend on Vi-o as well as Vj. At more positive Vi-o's,the changes in gj have two phases, an early phase consistingof of a decrease in gj for either polarity of Vj and a laterphase consisting of an increase in gj on hyperpolarizing eithercell and a decrease on depolarizing either cell. At negativeVi-o's in the plateau region of the gj-Vi-o relation, the laterslow increase in gj is absent on hyperpolarizing either cell.Also, the early decrease in gj for either polarity of Vj isfaster the more positive the Vi-o. The complex time course elicitedby applying voltage steps to one cell can be explained as combinedactions of Vi-o and Vj, with the early phase ascribable to Vj,but influenced by Vi-o, and the later phase to the changes inVi-o associated with the generation of Vj. The substantiallydifferent kinetics and sensitivity of changes in gj by Vi-oand Vj suggests that the mechanisms of gating by these two voltagesare different. Evidently, these gap-junction channels are capableof two distinct, but interactive forms of voltage dependence.

This article has been cited by other articles:

Q. Liu, B. Chen, E. Gaier, J. Joshi, and Z.-W. Wang
Low Conductance Gap Junctions Mediate Specific Electrical Coupling in Body-wall Muscle Cells of Caenorhabditis elegans
J. Biol. Chem., March 24, 2006; 281(12): 7881 - 7889.
[Abstract] [Full Text] [PDF]

R. Bruzzone, S. G. Hormuzdi, M. T. Barbe, A. Herb, and H. Monyer
Pannexins, a family of gap junction proteins expressed in brain
PNAS, November 11, 2003; 100(23): 13644 - 13649.
[Abstract] [Full Text] [PDF]

A. Revilla, M. V. L. Bennett, and L. C. Barrio
Molecular determinants of membrane potential dependence in vertebrate gap junction channels
PNAS, December 19, 2000; 97(26): 14760 - 14765.
[Abstract] [Full Text] [PDF]

L. A. Stebbings, M. G. Todman, P. Phelan, J. P. Bacon, and J. A. Davies
Two Drosophila Innexins Are Expressed in Overlapping Domains and Cooperate to Form Gap-Junction Channels
Mol. Biol. Cell, July 1, 2000; 11(7): 2459 - 2470.
[Abstract] [Full Text]

D. Manthey, F. Bukauskas, C. G. Lee, C. A. Kozak, and K. Willecke
Molecular Cloning and Functional Expression of the Mouse Gap Junction Gene Connexin-57 in Human HeLa Cells
J. Biol. Chem., May 21, 1999; 274(21): 14716 - 14723.
[Abstract] [Full Text] [PDF]

Y Landesman, T. White, T. Starich, J. Shaw, D. Goodenough, and D. Paul
Innexin-3 forms connexin-like intercellular channels
J. Cell Sci., January 7, 1999; 112(14): 2391 - 2396.
[Abstract] [PDF]

T Kojima, N Sawada, M Oyamada, H Chiba, H Isomura, and M Mori
Rapid appearance of connexin 26-positive gap junctions in centrilobular hepatocytes without induction of mRNA and protein synthesis in isolated perfused liver of female rat
J. Cell Sci., January 12, 1994; 107(12): 3579 - 3590.
[Abstract] [PDF]

				R. Bruzzone, S. G. Hormuzdi, M. T. Barbe, A. Herb, and H. Monyer Pannexins, a family of gap junction proteins expressed in brain PNAS, November 11, 2003; 100(23): 13644 - 13649. [Abstract] [Full Text] [PDF]

				A. Revilla, M. V. L. Bennett, and L. C. Barrio Molecular determinants of membrane potential dependence in vertebrate gap junction channels PNAS, December 19, 2000; 97(26): 14760 - 14765. [Abstract] [Full Text] [PDF]

				L. A. Stebbings, M. G. Todman, P. Phelan, J. P. Bacon, and J. A. Davies Two Drosophila Innexins Are Expressed in Overlapping Domains and Cooperate to Form Gap-Junction Channels Mol. Biol. Cell, July 1, 2000; 11(7): 2459 - 2470. [Abstract] [Full Text]

				D. Manthey, F. Bukauskas, C. G. Lee, C. A. Kozak, and K. Willecke Molecular Cloning and Functional Expression of the Mouse Gap Junction Gene Connexin-57 in Human HeLa Cells J. Biol. Chem., May 21, 1999; 274(21): 14716 - 14723. [Abstract] [Full Text] [PDF]

				Y Landesman, T. White, T. Starich, J. Shaw, D. Goodenough, and D. Paul Innexin-3 forms connexin-like intercellular channels J. Cell Sci., January 7, 1999; 112(14): 2391 - 2396. [Abstract] [PDF]

				T Kojima, N Sawada, M Oyamada, H Chiba, H Isomura, and M Mori Rapid appearance of connexin 26-positive gap junctions in centrilobular hepatocytes without induction of mRNA and protein synthesis in isolated perfused liver of female rat J. Cell Sci., January 12, 1994; 107(12): 3579 - 3590. [Abstract] [PDF]