Ambrosi C , Walker AE , Depriest AD , Cone AC , Lu C , Badger J , Skerrett IM , Sosinsky GE .

GM065937 NIGMS NIH HHS , GM072881 NIGMS NIH HHS , GM103311 NIGMS NIH HHS , GM103412 NIGMS NIH HHS , P41 GM103412 NIGMS NIH HHS , P41 RR002250 NCRR NIH HHS , P41 RR004050 NCRR NIH HHS , R01 GM065937 NIGMS NIH HHS , R01 GM072881 NIGMS NIH HHS , P41 GM103311 NIGMS NIH HHS

	Figure 2. Eight TM4 deafness mutations cause mis-trafficking.All 14 mutations were tested for their ability to make gap junctions in transiently transfected HeLa cells. Eight mutations (K188R, F191L, V198M, S199F, G200R, I203K, L205P, T208P) caused mis-trafficking, typically with intracellular aggregation. WT human Cx26 is shown at the top left for comparison, with an arrow pointing to a gap junction. The arrowhead in the F191L image points to a cell-cell apposition area with aggregate fluorescence.
	Figure 3. Six Cx26 TM4 traffic properly in HeLa cells.M195T, A197S, C202F, I203T, L205V and N206S each formed gap junctions between apposing cells when transiently expressed in mammalian cells. An arrow points to a gap junctions in each image.
	Figure 4. Analysis of hemichannel stability for gap junction forming mutants.Shown here are a representative electron micrograph and Blue Native westerns (bottom left hand inset) of purified hemichannels for each mutant purified from an Sf9/baculovirus expression system. The yellow arrowheads point to the recognizable bands. The insets on the top right are 6 fold enlargements of a normal hemichannel (the expected hexamer) indicated by the box in the micrograph, while the insets on the top left are 6 fold enlargements of the small oligomers visible only in unstable mutants and indicated by the circle in these micrographs.
	Figure 5. Dye transfer assays for gap junction forming mutants.Intercellular communication was assayed by scrape dye loading using Lucifer Yellow (LY) and Dextran Texas Red (TxR). LY will pass through gap junctions while Dextran TxR will not. (Panel A) Confluent gap-junction deficient parental HeLa cells (left column) and HeLa cells transiently transfected with Cx26 WT-GFP-4C (right column) serve as negative and positive controls, respectively. Top row: Images of LY fluorescence. Middle row: Images of TxR fluorescence Bottom row: Differential Interference Contrast (DIC) light micrograph of the same field of cells showing cell-cell contact. Dextran Texas Red acts as a reporter for dead or non-communicating cells and those along the scratch that also contained Lucifer Yellow were not counted in this analysis. (Panel B) Similar images as in (Panel A) for the two mutants, M195T and A197S, which made detergent stable hemichannels and channels. (Panel C) LY (top), TxR (middle) and DIC images (bottom) for mutants that made detergent unstable hemichannels and channels (left to right, C202F, I203T, L205V and N206S). The inset at the left is a 4.5x magnification of a LY non-transferring cell expressing C202F gap junctions. The arrow points to these cells in the C202F LY image. (D) Histogram of levels of communicating cells for each mutant. Error bars are standard errors of the mean (SEM).
	Figure 6. Six mutant channels (M195T, A197S, C202F, I203T, L205V and N206S) were tested for their conductances in the paired Xenopus oocyte system.(A) Mutant channels were tested in the homotypic configuration. Conductance measurements from two oocyte batches were pooled, each bar represents the mean ± SEM. The numbers above each bar represent the number of oocyte pairs in which coupling was observed as a fraction of the number tested. The negative-control (morpholino) involved oocytes injected only with the standard anti-XeCx38 antisense and intercellular conductance (Gj) was normalized to that of WT. Each bar represents a mean ± SEM and the numbers above each bar represent the number of oocyte pairs in which coupling was observed as a fraction of the number tested. (B) Mutants were paired heterotypically with WT and intercellular conductance (Gj) was normalized to that of WT. Conductance measurements from three oocyte batches were pooled, each bar represents the mean ± SEM, and the numbers above each bar represent the number of oocyte pairs in which coupling was observed as a fraction of the number tested. The negative-control (morpholino) involved oocytes injected only with the standard anti-XeCx38 antisense. (C) Characteristics of gap junctions induced by four of the six mutants after expression in Xenopus oocytes. Characteristic currents induced by WT are displayed on top Oocyte pairs were clamped at −20 mV and currents were recorded from a continuously clamped oocyte while its partner was pulsed in 10 mV increments to induce transjunctional voltages (Vj's) of up to ±100 mV. Only A197S and I203T formed distinguishable homotypic channels and these are observed on the right, adjacent to their corresponding heterotypic currents. (D) Transmembrane currents were measured in single oocytes to determine if mutants formed functionally conductive hemichannels. Each point represents the mean current (± SEM) for three oocytes from the same batch. The negative-control (morpholino) involved oocytes injected only with the standard anti-XeCx38 antisense.
	Figure 7. Co-expression of WT with M195T–WT decreases the stability of heteromers.(A–D) Hemichannels formed by M195T and the WT analyzed in different ratios showed increased instability from heteromeric interactions. EM images showed consistent aggregation of hemichannels for all four ratios analyzed, from 0:1 to 2:1. The Blue Native (BNGel PAGE) westerns confirmed stability with only two bands (hexamer and dodecamer) for the ratios 0 and 1:2 (A and B), but higher ratios of WT:M195T-V5-His6 are unstable with (C) three predominant bands for 1:1 and (D) a ladder of bands for the 2:1 ratio.
	Figure 8. C202F hemichannel stability can be rescued by the WT.(A) C202F forms unstable oligomers not easily recognizable by EM as hemichannels and a ladder of bands as detected by Blue Native western analysis. (B) The addition of WT protomers to the mutant oligomers did not result in stable hemichannels for the 0:1 ratio neither by EM or Blue Native western analysis. (C, D) The higher ratios (1:1 and 2:1) clearly showed only two bands on Blue Native westerns at the hexamer and dodecamer positions and more recognizable doughnut-like structures in EM images, but these heteromeric channels tended to aggregate.
	Figure 9. I203T mutant stability cannot be rescued by the WT.(A) Homomeric I203T hexamers and dodecamers are unstable. Both EM and Blue Native western analyses clearly showed no rescuing the I203T mutant hemichannels, even at the very high ratio of 2 (B), where the majority of the heteromer subunits should contain WT.
	Figure 10. L205V mutant cannot be rescued by the WT.(A) Homomeric oligomers of L205V are unstable. Similar to the I203T mutant shown in Fig. 9, (B) this mutant did not display stable hemichannels or channels when I203T monomers where mixed with the WT monomers in a 2:1 ratio of WT:L205V-V5-His6.
	Figure 11. N206S forms stable hemichannels when expressed with WT.(A–C) As visible by both EM and Blue Native Western analysis, stable hemichannels only resulted at 2:1 ratios of WT:N206S-V5-His6 (C). The EM image clearly showed distinct hemichannel structures and the hexamer band predominates in the Blue Native (BNGel PAGE) Western (C).
	Figure 12. Mapping of the twelve TM4 residues on the current X-ray model for the four transmembrane helices.Since the twelve amino acid positions analyzed fall only in the four α helical bundle domain of Cx26, here we show only (A) TM1 (medium blue), TM2 (cyan) TM3 (green) and TM4 (orange). The orientation of the Cx26 subunit is the same as in Fig. 1 with the extracellular loops at the top of the image. The mutant residues have been colored coded such that mutations that caused -trafficking are shown in purple, mutations that make gap junctions but unstable hemichannels are black and mutations that make stable gap junctions and hemichannels are indicated in red. Two positions, I203 and L205, have different phenotypes for the each of two mutations at these positions. These residues are dark blue. (B) Side chain interactions for these residues are between TM4 and TM1 and (C) TM4 and TM3. Note that the A197, N206S and T208 face the lipid bilayer. Note the mutant phenotypes are not mapped to any particular face of TM4.
	Figure 1. Spatial arrangement of 12 NSHL residues in TM4.(A) Topology diagram of Cx26. Blue boxes indicate these 12 residues. (B–E) Positions of residues on current X-ray atomic model (PDB ID 2ZW3) marked in blue on (B) monomer (C–E) hexamer. There is an ∼54° angle along the y axis between the two monomer views in (B). (C) Side view of front three connexins. Views down cytoplasmic side (D) and extracellular side (E).

Ambrosi, Analysis of four connexin26 mutant gap junctions and hemichannels reveals variations in hexamer stability. 2010, Pubmed, Xenbase

Ambrosi, Analysis of four connexin26 mutant gap junctions and hemichannels reveals variations in hexamer stability. 2010, Pubmed , Xenbase
Boassa, Trafficking and recycling of the connexin43 gap junction protein during mitosis. 2010, Pubmed
Bukauskas, Gating properties of gap junction channels assembled from connexin43 and connexin43 fused with green fluorescent protein. 2001, Pubmed
Desplantez, Influence of v5/6-His tag on the properties of gap junction channels composed of connexin43, connexin40 or connexin45. 2011, Pubmed
Dror, Hearing impairment: a panoply of genes and functions. 2010, Pubmed
Elfgang, Specific permeability and selective formation of gap junction channels in connexin-transfected HeLa cells. 1995, Pubmed
Evans, Gap junctions: structure and function (Review). 2002, Pubmed
Gaietta, Multicolor and electron microscopic imaging of connexin trafficking. 2002, Pubmed
Gaietta, Golgi twins in late mitosis revealed by genetically encoded tags for live cell imaging and correlated electron microscopy. 2006, Pubmed
Gerido, Connexin disorders of the ear, skin, and lens. 2004, Pubmed
Govindarajan, Impaired trafficking of connexins in androgen-independent human prostate cancer cell lines and its mitigation by alpha-catenin. 2002, Pubmed
Hamelmann, Pattern of connexin 26 (GJB2) mutations causing sensorineural hearing impairment in Ghana. 2001, Pubmed
Han, Carrier frequency of GJB2 (connexin-26) mutations causing inherited deafness in the Korean population. 2008, Pubmed
Hashemi, Prevalence of GJB2 (CX26) gene mutations in south Iranian patients with autosomal recessive nonsyndromic sensorineural hearing loss. 2012, Pubmed , Xenbase
Hülser, Dispersed and aggregated gap junction channels identified by immunogold labeling of freeze-fractured membranes. 1997, Pubmed
Jordan, Trafficking, assembly, and function of a connexin43-green fluorescent protein chimera in live mammalian cells. 1999, Pubmed
Kenna, Connexin 26 studies in patients with sensorineural hearing loss. 2001, Pubmed
Kudo, Novel mutations in the connexin 26 gene (GJB2) responsible for childhood deafness in the Japanese population. 2000, Pubmed
Lee, Connexin mutations causing skin disease and deafness increase hemichannel activity and cell death when expressed in Xenopus oocytes. 2009, Pubmed , Xenbase
Lee, Connexin-26 mutations in deafness and skin disease. 2009, Pubmed
Lentz, Rescue of hearing and vestibular function by antisense oligonucleotides in a mouse model of human deafness. 2013, Pubmed
Leshinsky-Silver, A novel missense mutation in the Connexin 26 gene associated with autosomal recessive sensorineural deafness. 2005, Pubmed
Maeda, Structure of the connexin 26 gap junction channel at 3.5 A resolution. 2009, Pubmed
Martin, Mammalian cell-based optimization of the biarsenical-binding tetracysteine motif for improved fluorescence and affinity. 2005, Pubmed
McRee, Differential evolution for protein crystallographic optimizations. 2004, Pubmed
Meşe, Connexin26 deafness associated mutations show altered permeability to large cationic molecules. 2008, Pubmed
Morlé, A novel C202F mutation in the connexin26 gene (GJB2) associated with autosomal dominant isolated hearing loss. 2000, Pubmed
Oshima, Projection structure of a N-terminal deletion mutant of connexin 26 channel with decreased central pore density. 2008, Pubmed
Oshima, Asymmetric configurations and N-terminal rearrangements in connexin26 gap junction channels. 2011, Pubmed , Xenbase
Oshima, Roles of Met-34, Cys-64, and Arg-75 in the assembly of human connexin 26. Implication for key amino acid residues for channel formation and function. 2003, Pubmed
Oshima, Three-dimensional structure of a human connexin26 gap junction channel reveals a plug in the vestibule. 2007, Pubmed
Pettersen, UCSF Chimera--a visualization system for exploratory research and analysis. 2004, Pubmed
Pfenniger, Mutations in connexin genes and disease. 2011, Pubmed
Putcha, A multicenter study of the frequency and distribution of GJB2 and GJB6 mutations in a large North American cohort. 2007, Pubmed
Saez, Plasma membrane channels formed by connexins: their regulation and functions. 2003, Pubmed
Scott, Key functions for gap junctions in skin and hearing. 2011, Pubmed
Skerrett, Applying the Xenopus oocyte expression system to the analysis of gap junction proteins. 2001, Pubmed , Xenbase
Snoeckx, GJB2 mutations and degree of hearing loss: a multicenter study. 2005, Pubmed
Sosinsky, Structural organization of gap junction channels. 2005, Pubmed
Söhl, Gap junctions and the connexin protein family. 2004, Pubmed , Xenbase
Tamayo, Molecular studies in the GJB2 gene (Cx26) among a deaf population from Bogotá, Colombia: results of a screening program. 2009, Pubmed
Unger, Three-dimensional structure of a recombinant gap junction membrane channel. 1999, Pubmed
Wang, A novel missense mutation in the connexin30 causes nonsyndromic hearing loss. 2011, Pubmed
Wu, Effectiveness of sequencing connexin 26 (GJB2) in cases of familial or sporadic childhood deafness referred for molecular diagnostic testing. 2002, Pubmed
Xiao, Impaired membrane targeting and aberrant cellular localization of human Cx26 mutants associated with inherited recessive hearing loss. 2011, Pubmed
Xu, The role of connexins in ear and skin physiology - functional insights from disease-associated mutations. 2013, Pubmed
Yilmaz, Two novel missense mutations in the connexin 26 gene in Turkish patients with nonsyndromic hearing loss. 2010, Pubmed
Yuan, Comprehensive molecular etiology analysis of nonsyndromic hearing impairment from typical areas in China. 2009, Pubmed
Yum, Dominant connexin26 mutants associated with human hearing loss have trans-dominant effects on connexin30. 2010, Pubmed
Zainal, Mutation detection in GJB2 gene among Malays with non-syndromic hearing loss. 2012, Pubmed
Zhang, Dominant Cx26 mutants associated with hearing loss have dominant-negative effects on wild type Cx26. 2011, Pubmed