In vitro motility of liver connexin vesicles along microtubules utilizes kinesin motors.

Trafficking of the proteins that form gap junctions (connexins) from the site of synthesis to the junctional domain appears to require cytoskeletal delivery mechanisms. Although many cell types exhibit specific delivery of connexins to polarized cell sites, such as connexin32 (Cx32) gap junctions specifically localized to basolateral membrane domains of hepatocytes, the precise roles of actin- and tubulin-based systems remain unclear. We have observed fluorescently tagged Cx32 trafficking linearly at speeds averaging 0.25 µm/s in a polarized hepatocyte cell line (WIF-B9), which is abolished by 50 µM of the microtubule-disrupting agent nocodazole. To explore the involvement of cytoskeletal components in the delivery of connexins, we have used a preparation of isolated Cx32-containing vesicles from rat hepatocytes and assayed their ATP-driven motility along stabilized rhodamine-labeled microtubules in vitro. These assays revealed the presence of Cx32 and kinesin motor proteins in the same vesicles. The addition of 50 µM ATP stimulated vesicle motility along linear microtubule tracks with velocities of 0.4-0.5 µm/s, which was inhibited with 1 mM of the kinesin inhibitor AMP-PNP (adenylyl-imidodiphosphate) and by anti-kinesin antibody but only minimally affected by 5 µM vanadate, a dynein inhibitor, or by anti-dynein antibody. These studies provide evidence that Cx32 can be transported intracellularly along microtubules and presumably to junctional domains in cells and highlight an important role of kinesin motor proteins in microtubule-dependent motility of Cx32.

Trifluoroethanol reveals helical propensity at analogous positions in cytoplasmic domains of three connexins.

Cytoplasmic domains of gap junction proteins (connexins) are involved in channel gating, voltage and pH sensitivity, and contain binding sites for partner proteins. However, their secondary structure is incompletely characterized and comparisons among the connexins is totally lacking. Circular dichroism (CD) was used to study the conformational properties of synthetic peptides corresponding to the highly divergent amino acid sequences of cytoplasmic domains of connexin (Cx)32, Cx36, and Cx43. We report that whereas peptides were largely unstructured in aqueous buffer, certain peptides in 30% trifluoroethanol (TFE) showed considerable helical content. These structured peptides correspond to analogous regions in each of the three connexin cytoplasmic domains. This first comparative study of conformational properties of connexin cytoplasmic domains reveals protein domains that may play similar roles in channel function and protein-protein interactions.

The neuronal connexin36 interacts with and is phosphorylated by CaMKII in a way similar to CaMKII interaction with glutamate receptors.

Electrical synapses can undergo activity-dependent plasticity. The calcium/calmodulin-dependent kinase II (CaMKII) appears to play a critical role in this phenomenon, but the underlying mechanisms of how CaMKII affects the neuronal gap junction protein connexin36 (Cx36) are unknown. Here we demonstrate effective binding of (35)S-labeled CaMKII to 2 juxtamembrane cytoplasmic domains of Cx36 and in vitro phosphorylation of this protein by the kinase. Both domains reveal striking similarities with segments of the regulatory subunit of CaMKII, which include the pseudosubstrate and pseudotarget sites of the kinase. Similar to the NR2B subunit of the NMDA receptor both Cx36 binding sites exhibit phosphorylation-dependent interaction and autonomous activation of CaMKII. CaMKII and Cx36 were shown to be significantly colocalized in the inferior olive, a brainstem nucleus highly enriched in electrical synapses, indicating physical proximity of these proteins. In analogy to the current notion of NR2B interaction with CaMKII, we propose a model that provides a mechanistic framework for CaMKII and Cx36 interaction at electrical synapses.

Cardiac connexins: genes to nexus.

Gap junctions are formed of at least 20 connexin proteins in mammals and possibly pannexins as well. Of the connexins, at least 5 (Cx30.2, Cx37, Cx40, Cx43 and Cx45) are prominently expressed in the heart and each shows regional and cell type specific expression. Contributions of each of these connexins to heart function has been in many cases illuminated by connexin null mice. The cardiac connexin genes whose genomic organization and transcriptional controls have been studied most thoroughly indicate more complex possibilities for alternate promoter usage than originally thought as well a multiple transcription factor binding sites; presumably, such complexity governs developmental timing and regional connexin expression patterns. The structure of cardiac connexin proteins indicate four primarily alpha-helical transmembrane domains, cytoplasmic amino and carboxyl termini and a cytoplasmic loop, all of which contain some regions of alpha-helix, and extracellular loops that are primarily Beta-structure. A number of proteins that bind to cardiac connexins are known, and more are certain to be discovered, linking the connexin into an intercellular signaling complex, the nexus. Binding sites may either correspond to structured regions within the connexin molecules or be unstructured, leading to presumably low-affinity and dynamic interactions.

Transfection of mammalian cells with connexins and measurement of voltage sensitivity of their gap junctions.

Vertebrate gap junction channels are formed by a family of more than 20 connexin proteins. These gap junction proteins are expressed with overlapping cellular and tissue specificity, and coding region mutations can cause human hereditary diseases. Here we present a summary of what has been learned from voltage clamp studies performed on cell pairs either endogenously expressing gap junctions or in which connexins are exogenously expressed. General protocols presented here are currently used to transfect mammalian cells with connexins and to study the biophysical properties of the heterologously expressed connexin channels. Transient transfection is accomplished overnight with maximal expression occurring at about 36 h; stable transfectants normally can be generated within three or four weeks through colony selection. Electrophysiological protocols are presented for analysis of voltage dependence and single-channel conductance of gap junction channels as well as for studies of chemical gating of these channels.