Sánchez HA, Mese G, Srinivas M, White TW, Verselis VK.

AR059505 NIAMS NIH HHS , GM54179 NIGMS NIH HHS , R01 AR059505-03 NIAMS NIH HHS , R01 AR059505 NIAMS NIH HHS , R01 GM054179 NIGMS NIH HHS , R01 EY013869 NEI NIH HHS

	Figure 1. Regulation of WT Cx26 and A40V and G45E mutant hemichannels by voltage and extracellular Ca2+. Representative conductance-voltage (G-V) relationships are shown expressed in Xenopus oocytes at different external Ca2+ concentrations ranging from nominal (0 added) to 2 mM obtained by applying slow (3 min) voltage ramps from 50 to −100 mV to oocytes expressing WT Cx26 (A), G45E (B), or A40V (C). The holding potential before and after each ramp was maintained at −20 mV. All conductances were normalized to the maximum value measured in 0 Ca2+. In WT and both mutant hemichannels, conductance declined strongly with hyperpolarization except in low extracellular Ca2+. Increasing Ca2+ shifted activation in the depolarizing direction in all cases. However, both mutant hemichannels appeared less sensitive to the effects of Ca2+, particularly at low Ca2+ concentrations. This reduced sensitivity to Ca2+ was strongest in A40V. In addition, G45E hemichannels showed stronger voltage-dependent closure at positive voltages (up to 50 mV).
	Figure 2. Steady-state Ca2+ response curves show that A40V hemichannels are less sensitive to external Ca2+ than WT Cx26 and G45E hemichannels. (A) Examples of recordings of WT Cx26 (top) and A40V (bottom) hemichannel currents and effects of increasing concentrations of extracellular Ca2+ (0, 0.2, 0.3, 0.5, 1.0, 2.0, and 5.0 mM). Oocytes were voltage clamped and maintained at −40 mV throughout. (B) Summary of data for WT Cx26 (■), A40V (∇), and G45E (○) compiled from several experiments such as that shown in A. Each point is the mean ± SEM of ∼20 experiments. (C) Plot showing resting membrane potentials measured in oocytes 24–48 h after RNA injection for WT Cx26 (■), A40V (∇), and G45E (○). Each point represents a measurement from an individual oocyte. Horizontal lines represent means of −25.1 ± 9.4 mV, −13.1 ± 5.5 mV, and −22.3 ± 8.0 mV for WT Cx26, A40V, and G45E, respectively. (D) The left panel shows the mean holding currents for oocytes from C when initially clamped to −40 mV. A40V-expressing oocytes, which showed the lowest resting potentials, showed the largest holding currents. The same oocytes exposed to 0 added Ca2+ (right) showed similar maximum current levels, indicating similar levels of expression.
	Figure 3. G45E hemichannels exhibit increased permeability to Ca2+. (A) Representative currents elicited by a series of voltage steps applied to oocytes expressing WT Cx26, A40V, and G45E. Oocytes were voltage clamped to −20 mV. The applied voltage step protocol consisted of 10-s steps from 60 to −100 mV in intervals of 10 mV followed by a 5-s step to −110 mV. Each series was repeated in extracellular solutions containing 0.2 mM Ca2+, 1.8 mM Ca2+, and 1.8 mM Ba2+. Currents from oocytes expressing any one of the three hemichannel types were similar in low Ca2+ (0.2 mM). Upon raising Ca2+ to 1.8 mM, a large transient inward current developed in oocytes expressing G45E when the voltage was stepped to −110 mV after depolarizing steps that activated these hemichannels. Equimolar substitution of Ca2+ with Ba2+ abolished the large transient inward current. Also, the hemichannel currents in Ba2+ resembled those in low Ca2+. (B and C) The transient current observed in oocytes expressing G45E represents a Ca2+-activated chloride current. (B) A representative recording of the reversal potential of the transient current for an oocyte bathed in 100 mM NaCl and 0.2 mM Ca2+. At various voltages (as indicated), oocytes were briefly exposed to 1.8 mM Ca2+ (indicated by the black boxes). The transient current that developed (filled in gray) reversed between −20 and −30 mV and was followed by a decay in the hemichannel current that reversed upon returning to 0.2 mM Ca2+. This protocol was repeated in an external solution in which 100 mM NaCl was replaced with a 50:50 NaCl/NaAsp. (C) Plot of peak transient current after exposure to 1.8 mM Ca2+ in 100 mM NaCl and 50:50 NaCl/NaAsp. Reversal potential shifted in accordance with the change in the extracellular Cl concentration.
	Figure 4. WT Cx26 hemichannels are also permeable to Ca2+. (A and B) Currents from oocytes expressing G45E (A) and WT Cx26 (B) recorded 24 and 48 h after injection of RNA. At 48 h, recordings are shown in 1.8 and 5.0 mM extracellular Ca2+. Voltage step protocols are the same as in Fig. 3 A. At 48 h, oocytes expressing G45E show larger hemichannel currents in 1.8 Ca2+ (compared with 24 h) along with larger Ca2+-activated Cl currents. Upon raising Ca2+ to 5 mM, G45E hemichannels continued to activate at positive voltages and to induce Ca2+-activated Cl currents. With increased expression of WT Cx26 hemichannels, Ca2+-activated Cl currents were also induced, albeit more weakly in comparison to G45E. (C) Peak chloride current is plotted as a function of the membrane conductance. Measurements were obtained from the same voltage protocol as shown in A and B). The magnitude of the chloride current was measured at the peak that developed at −110 mV after the activating voltages steps. Baseline was taken as the instantaneous current upon stepping to −110 mV that preceded the development of the large inward transient. The membrane conductance was measured at the end of the activating voltage step, the bulk of which was caused by hemichannel activation. Open symbols are data from WT Cx26, and closed symbols are from G45E. Experiments from individual oocytes are plotted as different symbol shapes. Lines represent fits (by eye) to the data for illustration purposes. n = 8 oocytes for G45E, and n = 9 oocytes for WT Cx26.
	Figure 5. G45E hemichannels exhibit a larger unitary conductance. Representative examples of patch clamp recordings from inside-out patches containing single WT Cx26 (A), A40V (B), and G45E (C) hemichannels. The single hemichannel currents shown are in response to 8-s voltage ramps between ±70 mV and are leak subtracted (see Materials and methods). In contrast to other hemichannels that generally show inward current rectification in symmetric 140 mM KCl, WT Cx26 shows slight outward rectification. A recording of a single Cx50 hemichannel in the same solutions is included for comparison in A.
	Figure 6. Cysteine substitutions at A40 and G45 produce functional hemichannels, but G45C exhibits impaired function as a result of coordination of metal ions. (A–C) Current traces from oocytes are shown expressing WT Cx26 (A), A40C (B), and G45C (C). Oocytes were held at −40 mV throughout and were exposed to a low extracellular Ca2+ (0.2 mM) solution with and without 10 µM of the heavy metal chelator TPEN. Oocytes expressing G45C show little current in 0.2 mM Ca2+ in the absence of TPEN and a large potentiation >10-fold after addition of TPEN. A40C hemichannel currents are robust in the absence of TPEN, and a small increase occurred after addition. TPEN had no effect on WT Cx26 hemichannels, which were robust upon lowering Ca2+ to 0.2 mM. (D) Summary of the effects of TPEN. Each bar represents the fold change (mean ± SEM) in current after TPEN in 0.2 mM Ca2+ (n = 9 for WT Cx26, n = 17 for A40C, and n = 51 for G45C).
	Figure 7. SCAM experiments using different MTS reagents show robust and differential effects on G45C. (A and B) The effects of MTS reagents on hemichannel currents are shown from G45C (A) and A40C (B) recorded at −40 mV. Before the recordings shown, oocytes were exposed to a solution containing 3 mM EGTA (0 Ca2+) to open hemichannels and then were exposed to the same solution containing 0.2 mM MTSET (positively charged, left) or 2.0 mM MTSES (negatively charged, right). G45C currents showed rapid and robust response to both MTS reagents that were opposite in sign, decreasing for MTSET and increasing for MTSES. Both MTS reagents decreased A40C currents, but the effects were more modest and slow in time course. (C) Summary of the percent change in current (mean ± SEM) upon application of the MTS reagent. n = 5 for WT Cx26, n = 7 for A40C, and n = 24 for G45C for MTSET. n = 7 for WT Cx26, n = 7 for A40C, and n = 23 for G45C for MTSES.
	Figure 8. Single-channel SCAM indicates that G45 is a pore-lining residue. (A) Recordings of single G45C hemichannels in excised patches. The top trace is a recording from an inside-out patch held at −40 mV. Exposure to MTSET produced a stepwise reduction in current (discernable levels indicated by dashed lines). The bottom recording is from an outside-out patch held at 40 mV. Exposure to MTSES produced a stepwise increase in current (discernable levels indicated by dashed lines). C and O depict fully closed and open states in both traces. (B) Examples of G45C hemichannel currents before and after (3 min) application of MTS reagents. The left panel shows a single G45C hemichannel recording in the absence of added reagent. The solid line is a fit to the open hemichannel current. The middle and right panels show effects of MTS reagents. Solid black lines represent fits to the open hemichannel I-V relationships before MTS application. Data and fits (gray lines) are after MTS application. (C) Same as in B for single A40C hemichannels. All currents were elicited by 8-s voltage ramps between ±70 mV. Currents were leak subtracted as described in Materials and methods.
	Figure 9. A40V and G45E mutants make functional cell–cell channels. (A) Bar graph showing junctional conductances, gj (mean ± SEM), measured in oocyte pairs injected with H2O (control, n = 10), WT Cx26 (n = 12), A40V (n = 8), and G45E (n = 7). Coupling was robust for WT Cx26 and both mutants compared with the control. Representative examples of junctional currents (left) along with steady-state Gj-Vj relationships (right) obtained from WT Cx26 (n = 4), A40V (n = 3), and G45E (n = 4) cell pairs. Gj is gj normalized to the maximum about Vj = 0. Records were taken from oocytes that were paired for shorter times to avoid series access resistance errors that accompany strong coupling. Vj steps between ±120 mV were applied in 10-mV increments. (B) Bar graph showing junctional conductances (mean ± SEM) measured in N2A cell pairs transfected with A40V and G45E (n = 42 for A40V, and n = 53 for G45E). Examples of junctional currents are shown below. Vj steps between ±120 mV were applied in 10-mV increments.

Barish, A transient calcium-dependent chloride current in the immature Xenopus oocyte. 1983, Pubmed, Xenbase

Barish, A transient calcium-dependent chloride current in the immature Xenopus oocyte. 1983, Pubmed , Xenbase
Beltramello, Impaired permeability to Ins(1,4,5)P3 in a mutant connexin underlies recessive hereditary deafness. 2005, Pubmed
Bikle, Mice lacking 25OHD 1alpha-hydroxylase demonstrate decreased epidermal differentiation and barrier function. 2004, Pubmed
Bukauskas, Gap junction channel gating. 2004, Pubmed
Bukauskas, Biophysical properties of gap junction channels formed by mouse connexin40 in induced pairs of transfected human HeLa cells. 1995, Pubmed
Cohen-Salmon, Targeted ablation of connexin26 in the inner ear epithelial gap junction network causes hearing impairment and cell death. 2002, Pubmed
De Vuyst, Intracellular calcium changes trigger connexin 32 hemichannel opening. 2006, Pubmed
Fairley, Calcium metabolism and the pathogenesis of dermatologic disease. 1991, Pubmed
Gerido, Aberrant hemichannel properties of Cx26 mutations causing skin disease and deafness. 2007, Pubmed , Xenbase
Gerido, Connexin disorders of the ear, skin, and lens. 2004, Pubmed
Goldberg, Selective permeability of gap junction channels. 2004, Pubmed
Gómez-Hernández, Molecular basis of calcium regulation in connexin-32 hemichannels. 2003, Pubmed , Xenbase
González, Species specificity of mammalian connexin-26 to form open voltage-gated hemichannels. 2006, Pubmed , Xenbase
Griffith, Cochleosaccular dysplasia associated with a connexin 26 mutation in keratitis-ichthyosis-deafness syndrome. 2006, Pubmed
Harris, Emerging issues of connexin channels: biophysics fills the gap. 2001, Pubmed
Hennings, Calcium regulation of growth and differentiation of mouse epidermal cells in culture. 1980, Pubmed
Hoang Dinh, Diverse deafness mechanisms of connexin mutations revealed by studies using in vitro approaches and mouse models. 2009, Pubmed
Horton, Gene splicing by overlap extension: tailor-made genes using the polymerase chain reaction. 1990, Pubmed
Janecke, GJB2 mutations in keratitis-ichthyosis-deafness syndrome including its fatal form. 2005, Pubmed
Karlin, Substituted-cysteine accessibility method. 1998, Pubmed
Kelsell, Connexin 26 mutations in hereditary non-syndromic sensorineural deafness. 1997, Pubmed
Kronengold, Single-channel SCAM identifies pore-lining residues in the first extracellular loop and first transmembrane domains of Cx46 hemichannels. 2003, Pubmed , Xenbase
Kronengold, Pore-lining residues identified by single channel SCAM studies in Cx46 hemichannels. 2003, Pubmed , Xenbase
Kuruma, Dynamics of calcium regulation of chloride currents in Xenopus oocytes. 1999, Pubmed , Xenbase
Lai-Cheong, Genetic diseases of junctions. 2007, Pubmed
Lang, Functional significance of channels and transporters expressed in the inner ear and kidney. 2007, 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
Maeda, Structure of the connexin 26 gap junction channel at 3.5 A resolution. 2009, Pubmed
Meşe, Connexin26 deafness associated mutations show altered permeability to large cationic molecules. 2008, Pubmed
Montgomery, A novel connexin 26 gene mutation associated with features of the keratitis-ichthyosis-deafness syndrome and the follicular occlusion triad. 2004, Pubmed , Xenbase
Oesterle, Intracellular recordings from supporting cells in the guinea pig cochlea: DC potentials. 1990, Pubmed
Oh, Molecular determinants of electrical rectification of single channel conductance in gap junctions formed by connexins 26 and 32. 1999, Pubmed
Oh, Stoichiometry of transjunctional voltage-gating polarity reversal by a negative charge substitution in the amino terminus of a connexin32 chimera. 2000, Pubmed , Xenbase
Purnick, Reversal of the gating polarity of gap junctions by negative charge substitutions in the N-terminus of connexin 32. 2000, Pubmed , Xenbase
Purnick, Structure of the amino terminus of a gap junction protein. 2000, Pubmed , Xenbase
Richard, Mutations in the human connexin gene GJB3 cause erythrokeratodermia variabilis. 1998, Pubmed
Richard, Missense mutations in GJB2 encoding connexin-26 cause the ectodermal dysplasia keratitis-ichthyosis-deafness syndrome. 2002, Pubmed
Richard, Human connexin disorders of the skin. 2001, Pubmed
Richard, Connexins: a connection with the skin. 2000, Pubmed
Rouan, trans-dominant inhibition of connexin-43 by mutant connexin-26: implications for dominant connexin disorders affecting epidermal differentiation. 2001, Pubmed , Xenbase
Sánchez, Metabolic inhibition increases activity of connexin-32 hemichannels permeable to Ca2+ in transfected HeLa cells. 2009, Pubmed
Schalper, Connexin hemichannel composition determines the FGF-1-induced membrane permeability and free [Ca2+]i responses. 2008, Pubmed
Srinivas, Regulation of connexin hemichannels by monovalent cations. 2006, Pubmed , Xenbase
Srinivas, Correlative studies of gating in Cx46 and Cx50 hemichannels and gap junction channels. 2005, Pubmed , Xenbase
Stong, A novel mechanism for connexin 26 mutation linked deafness: cell death caused by leaky gap junction hemichannels. 2006, Pubmed
Suchyna, Different ionic selectivities for connexins 26 and 32 produce rectifying gap junction channels. 1999, Pubmed , Xenbase
Tang, Conformational changes in a pore-forming region underlie voltage-dependent "loop gating" of an unapposed connexin hemichannel. 2009, Pubmed , Xenbase
Terrinoni, Connexin 26 (GJB2) mutations as a cause of the KID syndrome with hearing loss. 2010, Pubmed
Terrinoni, Connexin 26 (GJB2) mutations, causing KID Syndrome, are associated with cell death due to calcium gating deregulation. 2010, Pubmed
Trexler, Voltage gating and permeation in a gap junction hemichannel. 1996, Pubmed , Xenbase
Trexler, The first extracellular loop domain is a major determinant of charge selectivity in connexin46 channels. 2000, Pubmed , Xenbase
Tu, The role of the calcium-sensing receptor in epidermal differentiation. 2004, Pubmed
van Steensel, A novel connexin 26 mutation in a patient diagnosed with keratitis-ichthyosis-deafness syndrome. 2002, Pubmed
Verselis, Opposite voltage gating polarities of two closely related connexins. 1994, Pubmed , Xenbase
Verselis, Loop gating of connexin hemichannels involves movement of pore-lining residues in the first extracellular loop domain. 2009, Pubmed , Xenbase
Verselis, Divalent cations regulate connexin hemichannels by modulating intrinsic voltage-dependent gating. 2008, Pubmed , Xenbase
Wilders, Limitations of the dual voltage clamp method in assaying conductance and kinetics of gap junction channels. 1992, Pubmed
Wohlrab, Electrophysiological characterization of human keratinocytes using the patch-clamp technique. 2000, Pubmed
Yotsumoto, Novel mutations in GJB2 encoding connexin-26 in Japanese patients with keratitis-ichthyosis-deafness syndrome. 2003, Pubmed
Zhang, Gap junction-mediated intercellular biochemical coupling in cochlear supporting cells is required for normal cochlear functions. 2005, Pubmed
Zhou, Identification of a pore lining segment in gap junction hemichannels. 1997, Pubmed , Xenbase