Srinivas M , Jannace TF , Cocozzelli AG , Li L , Slavi N , Sellitto C , White TW .

R01 EY013163 NEI NIH HHS , EY013163 U.S. Department of Health & Human Services | National Institutes of Health (NIH), R01 EY028170 NEI NIH HHS , EY028170 U.S. Department of Health & Human Services | National Institutes of Health (NIH), EY026911 U.S. Department of Health & Human Services | National Institutes of Health (NIH), R01 EY026911 NEI NIH HHS

	Figure 1. Wild-type and mutant forms of Cx43 are equivalently expressed and form functional gap junctions in paired Xenopus oocytes. (a) Equal amounts of membrane extracts were frst probed with an antibody that recognized Cx43. H2O injected controls did not express Cx43 as expected. Wild-type Cx43, Cx43-G8V, Cx43- A44V, and Cx43-E227D were readily detected in lanes corresponding to each injection condition with similar band intensities. (b) To confrm equal sample loading, blots were stripped and reprobed with an antibody against β-tubulin, which was present at comparable levels in all lanes. (c) Gap junctional conductance levels for cell pairs expressing either wild-type, or mutant, forms of Cx43 were all signifcantly greater than the H2O injected negative controls (p<0.05, one way ANOVA), but not signifcantly diferent from each other. Values are the mean±SEM.
	Figure 2. Cx43 mutations do not alter gap junction voltage gating. Oocyte pairs were subjected to hyperpolarizing and depolarizing transjunctional potentials (Vj ) while recording junctional currents (Ij ). (a) Wild-type Cx43 gap junction channels had Ij s that decreased symmetrically at higher values of Vj . Ij s between cell pairs expressing Cx43-G8V (b), Cx43-A44V (c), or Cx43-E227D (d) behaved in a similar fashion. (e) Steady-state voltage gating of wild-type Cx43 (flled squares) showed an approximately symmetric decline in steady state conductance at increasing values of Vj . Data from cell pairs expressing Cx43-G8V (open squares), Cx43-A44V (open circles), or Cx43-E227D (open triangles) were similar to wild-type Cx43.
	Figure 3. Cx43 mutations induce large hemichannel currents in Xenopus oocytes. Single cells were clamped at a holding potential of −40 mV and subjected to voltage pulses ranging from −30 to +60mV in 10mV steps. H2O (a) and wild-type Cx43 (b) injected cells displayed negligible membrane currents. Cx43-G8V (c), Cx43- A44V (d), and Cx43-E227D (e) expressing oocytes displayed much larger hemichannel currents than wild-type Cx43. (f) Steady-state currents from each pulse were plotted as a function of membrane voltage. Steady state currents in wild-type Cx43 (flled squares) or H2O injected control cells (flled circles) were negligible at all tested membrane voltages. Cx43-G8V (open squares) expressing cells exhibited signifcantly increased steadystate currents at all voltages compared to either control or wild-type Cx43 oocytes. Cx43-A44V (open circles), or Cx43-E227D (open triangles) currents were similar to those observed in control cells at negative voltages, but increased at positive potentials. Data are the mean±SEM.
	Figure 4. Calcium and gadolinium ions block mutant Cx43 hemichannel activity. Oocytes expressing Cx43 mutations were sequentially stepped from −70 mV to +20mV (a) while being perfused with medium containing 2mM Ca2+, 0.2mM Ca2+, or 5 µM Gd3+ (b). In the example shown for a Cx43-E227D expressing cell (c), hemichannel currents were initially suppressed by 2mM Ca2+, and increased markedly when the extracellular calcium was reduced to 0.2mM. Hemichannel currents were also suppressed by perfusion with 5 µM Gd3+, and recovered rapidly when Gd3+ was washed out with 0.2mM Ca2+. Currents were suppressed again by increasing the extracellular calcium to 2.0mM.
	Figure 5. Representative examples of patch clamp recordings from cell-attached patches containing single Cx43-G8V (a), Cx43-A44V (b), and Cx43-E227D (c) hemichannels in symmetric 140mM KCl solutions. Single hemichannel currents were recorded in response to 8-s voltage ramps between −70 and +70mV. Current-voltage relations for Cx43-A44V and Cx43-E227D were linear, whereas those of Cx43-G8V showed slight inward rectifcation. All three mutations show closing transitions to subconductance states. Occasional transitions to the fully closed state are also seen (b). (d) Cell-attached patches from wild-type Cx43 injected oocytes failed to show single channel activity. (e) Mean slope conductances measured at Vm =0 are similar for the three mutant hemichannels. Values represent the mean±SEM from 5 to 7 recordings.
	Figure 6. Gating of single Cx43-E227D hemichannels at positive and negative voltages. Representative examples of recordings from a Cx43-E227D expressing oocyte in a cell-attached patch confguration containing one to two open channels at voltages ranging from −110 to +70mV. Cx43-E227D hemichannels were predominantly open at inside positive voltages. Occasional closures to subconductance states were observed at high positive voltages. In contrast, Cx43-E227D hemichannels showed voltage-dependent closures to negative voltages. While channels are predominantly open at −30 mV, dwell times in the open state decreased with hyperpolarization to −50, −70 and −90 mV. Residence in subconductance states or the fully closed state was favored at the more hyperpolarized voltages. Te zero current level, i.e. the fully closed state (C), the current levels of one (O1) or two fully open hemichannels (O2) and that of the subconductance state (S) are depicted by dotted lines. Te zero current level was determined as described in Methods.
	Figure 7. Expression of mutant Cx43 in transfected HeLa cells results in targeting to gap junction plaques and formation of functional intercellular channels. Cx43-G8V (a,b), Cx43-A44V (c,d), and Cx43-E227D (e,f) transfected cells (blue DAPI stain) displayed a strong Cx43 (red) labeling that concentrated at cell-tocell interfaces (white arrowheads) and correlated with GFP (green) fuorescence. (g) Measurement of gap junctional coupling in transfected cell pairs showed that all three Cx43 mutations induced similar high levels of conductance. (h) A single gap junction channel recording for Cx43-A44V shows transitions between the fully open state and closed state with a unitary conductance of 113 pS. Data are the mean±SEM.

Altman, Inflammatory linear verrucose epidermal nevus. 1971, Pubmed

Altman, Inflammatory linear verrucose epidermal nevus. 1971, Pubmed
Barrio, Gap junctions formed by connexins 26 and 32 alone and in combination are differently affected by applied voltage. 1991, Pubmed , Xenbase
Başaran, Keratoderma, hypotrichosis and leukonychia totalis: a new syndrome? 1995, Pubmed
Boyden, Dominant De Novo Mutations in GJA1 Cause Erythrokeratodermia Variabilis et Progressiva, without Features of Oculodentodigital Dysplasia. 2015, Pubmed
Bruzzone, Expression of chimeric connexins reveals new properties of the formation and gating behavior of gap junction channels. 1994, Pubmed , Xenbase
Bruzzone, Connections with connexins: the molecular basis of direct intercellular signaling. 1996, Pubmed
Bruzzone, Connexin40, a component of gap junctions in vascular endothelium, is restricted in its ability to interact with other connexins. 1993, Pubmed , Xenbase
Bukauskas, Gating properties of gap junction channels assembled from connexin43 and connexin43 fused with green fluorescent protein. 2001, Pubmed
Bukauskas, Gap junction channel gating. 2004, Pubmed
Butterweck, Differential expression of the gap junction proteins connexin45, -43, -40, -31, and -26 in mouse skin. 1994, Pubmed
Chi, Pathogenic connexin-31 forms constitutively active hemichannels to promote necrotic cell death. 2012, Pubmed
Contreras, Gating and regulation of connexin 43 (Cx43) hemichannels. 2003, Pubmed
Das Sarma, Targeted gap junction protein constructs reveal connexin-specific differences in oligomerization. 2002, Pubmed
Delmar, Connexins and Disease. 2018, Pubmed
DeVries, Hemi-gap-junction channels in solitary horizontal cells of the catfish retina. 1992, Pubmed
Ebihara, Properties of a nonjunctional current expressed from a rat connexin46 cDNA in Xenopus oocytes. 1993, Pubmed , Xenbase
Elenes, Heterotypic docking of Cx43 and Cx45 connexons blocks fast voltage gating of Cx43. 2001, Pubmed
Eskandari, Inhibition of gap junction hemichannels by chloride channel blockers. 2002, Pubmed , Xenbase
Essenfelder, Connexin30 mutations responsible for hidrotic ectodermal dysplasia cause abnormal hemichannel activity. 2004, Pubmed , Xenbase
Evans, The gap junction cellular internet: connexin hemichannels enter the signalling limelight. 2006, Pubmed
Fishman, Functional analysis of human cardiac gap junction channel mutants. 1991, Pubmed
García, Keratitis-ichthyosis-deafness syndrome-associated Cx26 mutants produce nonfunctional gap junctions but hyperactive hemichannels when co-expressed with wild type Cx43. 2015, Pubmed
García, From Hyperactive Connexin26 Hemichannels to Impairments in Epidermal Calcium Gradient and Permeability Barrier in the Keratitis-Ichthyosis-Deafness Syndrome. 2016, Pubmed
Gerido, Aberrant hemichannel properties of Cx26 mutations causing skin disease and deafness. 2007, Pubmed , Xenbase
Hansen, Distinct permeation profiles of the connexin 30 and 43 hemichannels. 2014, Pubmed , Xenbase
Hansen, Activation, permeability, and inhibition of astrocytic and neuronal large pore (hemi)channels. 2014, Pubmed , Xenbase
Harris, Connexin channel permeability to cytoplasmic molecules. 2007, Pubmed
Harris, Emerging issues of connexin channels: biophysics fills the gap. 2001, Pubmed
Horton, Gene splicing by overlap extension: tailor-made genes using the polymerase chain reaction. 1990, Pubmed
Ishida-Yamamoto, Erythrokeratodermia variabilis et progressiva. 2016, Pubmed
Kamibayashi, Expression of gap junction proteins connexin 26 and 43 is modulated during differentiation of keratinocytes in newborn mouse epidermis. 1993, Pubmed
Kanaporis, Gap junction channels exhibit connexin-specific permeability to cyclic nucleotides. 2008, Pubmed
Kang, Connexin 43 hemichannels are permeable to ATP. 2008, Pubmed
Kelly, Mechanisms linking connexin mutations to human diseases. 2015, Pubmed
Kogame, Palmoplantar keratosis in oculodentodigital dysplasia with a GJA1 point mutation out of the C-terminal region of connexin 43. 2014, Pubmed
Laird, Life cycle of connexins in health and disease. 2006, Pubmed
Laird, Syndromic and non-syndromic disease-linked Cx43 mutations. 2014, Pubmed
Lee, Connexin-26 mutations in deafness and skin disease. 2009, Pubmed
Lee, Connexin mutations causing skin disease and deafness increase hemichannel activity and cell death when expressed in Xenopus oocytes. 2009, Pubmed , Xenbase
Lilly, Connexin channels in congenital skin disorders. 2016, Pubmed
Malchow, Evidence for hemi-gap junctional channels in isolated horizontal cells of the skate retina. 1993, Pubmed
Mese, The Cx26-G45E mutation displays increased hemichannel activity in a mouse model of the lethal form of keratitis-ichthyosis-deafness syndrome. 2011, Pubmed
Meşe, Connexin26 deafness associated mutations show altered permeability to large cationic molecules. 2008, Pubmed
Mhaske, The human Cx26-D50A and Cx26-A88V mutations causing keratitis-ichthyosis-deafness syndrome display increased hemichannel activity. 2013, Pubmed , Xenbase
Montgomery, A novel connexin 26 gene mutation associated with features of the keratitis-ichthyosis-deafness syndrome and the follicular occlusion triad. 2004, Pubmed , Xenbase
Paznekas, Connexin 43 (GJA1) mutations cause the pleiotropic phenotype of oculodentodigital dysplasia. 2003, Pubmed
Plum, Unique and shared functions of different connexins in mice. 2000, Pubmed
Retamal, Diseases associated with leaky hemichannels. 2015, Pubmed
Richard, Genetic heterogeneity in erythrokeratodermia variabilis: novel mutations in the connexin gene GJB4 (Cx30.3) and genotype-phenotype correlations. 2003, Pubmed
Shuja, Connexin26 Mutations Causing Palmoplantar Keratoderma and Deafness Interact with Connexin43, Modifying Gap Junction and Hemichannel Properties. 2016, Pubmed
Slavi, Connexin 46 (cx46) gap junctions provide a pathway for the delivery of glutathione to the lens nucleus. 2014, Pubmed , Xenbase
Spray, Equilibrium properties of a voltage-dependent junctional conductance. 1981, Pubmed , Xenbase
Srinivas, Quinine blocks specific gap junction channel subtypes. 2001, Pubmed
Srinivas, Human diseases associated with connexin mutations. 2018, Pubmed
Turner, Expression of achaete-scute homolog 3 in Xenopus embryos converts ectodermal cells to a neural fate. 1994, Pubmed , Xenbase
Umegaki-Arao, Inflammatory Linear Verrucous Epidermal Nevus with a Postzygotic GJA1 Mutation Is a Mosaic Erythrokeratodermia Variabilis et Progressiva. 2017, Pubmed
Valiunas, Gap junction channels formed by coexpressed connexin40 and connexin43. 2001, Pubmed
Valiunas, Cyclic nucleotide permeability through unopposed connexin hemichannels. 2013, Pubmed
Vinken, Introduction: connexins, pannexins and their channels as gatekeepers of organ physiology. 2015, Pubmed
Wang, Connexin mimetic peptides inhibit Cx43 hemichannel opening triggered by voltage and intracellular Ca2+ elevation. 2012, Pubmed
Wang, Exome sequencing reveals mutation in GJA1 as a cause of keratoderma-hypotrichosis-leukonychia totalis syndrome. 2015, Pubmed
White, Functional characteristics of skate connexin35, a member of the gamma subfamily of connexins expressed in the vertebrate retina. 1999, Pubmed , Xenbase
White, Selective interactions among the multiple connexin proteins expressed in the vertebrate lens: the second extracellular domain is a determinant of compatibility between connexins. 1994, Pubmed , Xenbase
White, Unique and redundant connexin contributions to lens development. 2002, Pubmed
White, Mouse Cx50, a functional member of the connexin family of gap junction proteins, is the lens fiber protein MP70. 1992, Pubmed , Xenbase
White, Optimal lens epithelial cell proliferation is dependent on the connexin isoform providing gap junctional coupling. 2007, Pubmed
White, Nonredundant gap junction functions. 2003, Pubmed