Molecular dissection of a basic COOH-terminal domain of Cx32 that inhibits gap junction gating sensitivity

Connexin32(Cx32) mutants were studied by double voltage clamp inXenopus oocytes to determine the roleof basic COOH-terminal residues in gap junction channel gating byCO₂ and transjunctional voltage.Replacement of five arginines with N (5R/N) or T residues in theinitial COOH-terminal domain(CT₁) of Cx32 enhancedCO₂ sensitivity. The positivecharge, rather than the R residue per se, is responsible for theinhibitory role of CT₁, becausemutants replacing the five R residues with K (5R/K) or H (5R/H)displayed CO₂ sensitivitycomparable to that of wild-type Cx32. Mutants replacing R with Nresidues four at a time (4R/N) showed that CO₂ sensitivity is stronglyinhibited by R215 and mildly by R219, whereas R220, R223, and R224 mayslightly increase sensitivity. Neither the 5R/N nor the 4R/N mutantsdiffered in voltage sensitivity from wild-type Cx32. The possibilitythat inhibition of gating sensitivity results from electrostaticinteractions between CT₁ and thecytoplasmic loop is discussed as part of a model that envisions thecytoplasmic loop of Cx32 as a key element of chemical gating.

     

A structural basis for the unequal sensitivity of the major cardiac and liver gap junctions to intracellular acidification: the carboxyl tail length.

The regulation of junctional conductance (Gi) of the major cardiac (connexin43; Cx43) and liver (connexin32; Cx32) gap junction proteins by intracellular hydrogen ion concentration (pH; pHi), as well as well as that of a truncation mutant of Cx43 (M257) with 125 amino acids deleted from the COOH terminus, was characterized in pairs of Xenopus laevis oocytes expressing homologous channels. Oocytes were injected with 40 nl mRNAs (2 micrograms/microliters) encoding the respective proteins; subsequently, cells were stripped, paired, and incubated for 20-24 h. Gj was measured in oocyte pairs using the dual electrode voltage-clamp technique, while pHi was recorded simultaneously in the unstimulated cell by means of a proton-selective microelectrode. Because initial experiments showed that the pH-sensitive microelectrode responded more appropriately to acetate than to CO2 acidification, oocytes expressing Cx32 and wild type and mutant Cx43 were exposed to a sodium acetate saline, which was balanced to various levels of pH using NaOH and HCl. pH was changed in a stepwise manner, and quasi-steady-state Gj -pHi relationships were constructed from data collected at each step after both Gj and pHi had reached their respective asymptotic values. A moderate but significant increase of Gj was observed in Cx43 pairs as pHi decreased from 7.2 to 6.8. In both Cx32 and M257 pairs, Gj increased significantly over a wider pH range (i.e., between 7.2 and 6.3). Further acidification reversibly reduced Gj to zero in all oocyte pairs. Pooled data for the individual connexins obtained during uncoupling were fitted by the Hill equation; apparent 50%-maximum (pK;pKa) values were 6.6 and 6.1 for Cx43 and Cx32, respectively, and Hill coefficients were 4.2 for Cx43 and 6.2 for Cx32. Like Cx32, M257 had a more acidic pKa (6.1) and steeper Hill coefficient (6.0) than wild type Cx43. The pKa and Hill coefficient of M257 were very similar to those of Cx32. These experiments provide the first direct comparison of the effects of acidification on Gj in oocyte pairs expressing Cx43 or Cx32. The results indicate that structural differences in the connexins are the basis for their unequal sensitivity to intracellular acidification in vivo. The data further suggest that a common pH gating mechanism may exist between amino acid residues 1 and 256 in both Cx32 and Cx43. However, the longer carboxyl tail of Cx43 relative to Cx32 or M257 provides additional means to facilitate acidification-induced gating; its presence shifts the pKa from 6.1 (Cx32 and M257) to 6.6 (Cx43) in the conductance of these channels.     

The voltage gates of connexin channels are sensitive to CO(2)

Cx45 channel sensitivity to CO(2), transjunctional voltage (V(j)) and inhibition of calmodulin (CaM) expression was tested in oocytes by dual voltage-clamp. Cx45 channels are very sensitive to V(j) and close preferentially by the slow gate, likely the same as the chemical gate. With CO(2)-induced drop in junctional conductance (G(j)), the speed of V(j)-dependent inactivation of junctional current (I(j)) and V(j) sensitivity increased. With 40 mV V(j), the tau of single exponential I(j) decay reversibly decreased by approximately 40% with CO(2), and G(j steady state)/G(j peak) decreased multiphasically, indicating that kinetics and V(j) sensitivity of chemical/slow-V(j) gating are altered by changes in [H(+)](i) and/or [Ca(2+)](i). With 15 min exposure to CO(2), G(j) dropped to 0% in controls and by approximately 17% following CaM expression inhibition; similarly, V(j) sensitivity decreased significantly. This indicates that the speed and sensitivity of V(j)-dependent inactivation of Cx45 channels are increased by CO(2), and that CaM plays a role in gating. Cx32 channels behaved similarly, but the drop in both G(j steady state)/G(j peak) and tau with CO(2) matched more closely that of G(j peak). In contrast, sensitivity and speed of V(j) gating of Cx40 and Cx26 channels decreased, rather than increased, with CO(2) application.     

Chemical Gating of Heteromeric and Heterotypic Gap Junction Channels

Gap junction channels contain two hemichannels (connexons), each being a connexin (Cx) hexamer. In cells expressing multiple connexins, heteromeric connexons are believed to form, whereas cell pairs expressing different connexins generate heterotypic channels. To define gating behavior of heteromeric and heterotypic channels, CO₂-induced gating was tested in Xenopus oocyte pairs expressing Cx32, or 5R/N (Cx32 mutant), as well as in pairs in which one oocyte (mx) expressed a 50/50 mixture of Cx32 and 5R/N and the other either the mixture (mx), Cx32 (32) or 5R/N (R/N). In 5R/N, replacement of 5 C-terminus arginines with asparagines greatly increased CO₂ sensitivity. In response to 3 and 15 min CO₂ exposures, junctional conductance (G _j ) decreased to 85% and 47%, in 32–32 pairs, and to 7% and 0.9%, in R/N-R/N pairs, respectively. In mx-mx and mix-32 pairs, G _j decreased to similar values (33% and 35%, respectively) with 15 min CO₂. The sensitivity of mx-R/N pairs was similar to that of heterotypic 32-R/N pairs, as G _j dropped to 36% and 38%, respectively, with 3 min CO₂. Monoheteromeric (mx-32 and mx-R/N) and biheteromeric (mx-mx) channels behaved as if Cx32 were dominant, suggesting that hemichannel sensitivity is not an average of the sensitivities of its connexin monomers. In contrast, heterotypic channels behaved as if the two hemichannels of a cell-cell channel had no influence on each other. Received: 15 May 1997/Revised: 8 December 1997     

Slow Gating of Gap Junction Channels and Calmodulin

Certain COOH-terminus mutants of connexin32 (Cx32) were previously shown to form channels with unusual transjuctional voltage (V _j ) sensitivity when tested heterotypically in oocytes against Cx32 wild type. Junctional conductance (G _j ) slowly increased by severalfold or decreases to nearly zero with V _j positive or negative, respectively, at mutant side, and V _j positive at mutant side reversed CO₂-induced uncoupling. This suggested that the CO₂-sensitive gate might be a V _j -sensitive slow gate. Based on previous data for calmodulin (CaM) involvement in gap junction function, we have hypothesized that the slow gate could be a CaM-like pore plugging molecule (cork gating model). This study describes a similar behavior in heterotypic channels between Cx32 and each of four new Cx32 mutants modified in cytoplasmic-loop and/or COOH-terminus residues. The mutants are: ML/NN+3R/N, 3R/N, ML/NN and ML/EE; in these mutants, N or E replace M105 and L106, and N replace R215, R219 and R220. This study also reports that inhibition of CaM expression strongly reduces V _j and CO₂ sensitivities of two of the most effective mutants, suggesting a CaM role in slow and chemical gating. Received: 19 April 2000/Revised: 11 August 2000     

The Voltage Gates of Connexin Channels are Sensitive to CO2

Cx45 channel sensitivity to CO₂, transjunctional voltage (V_j) and inhibition of calmodulin (CaM) expression was tested in oocytes by dual voltage-clamp. Cx45 channels are very sensitive to V_j and close preferentially by the slow gate, likely the same as the chemical gate. With CO₂-induced drop in junctional conductance (G_j), the speed of V_j-dependent inactivation of junctional current (I_j) and V_j sensitivity increased. With 40 mV V_j, the τ of single exponential I_j decay reversibly decreased by ∼40% with CO₂, and G_{j steady state}/G_{j peak} decreased multiphasically, indicating that kinetics and V_j sensitivity of chemical/slow-V_j gating are altered by changes in [H⁺]_i and/or [Ca²⁺]_i. With 15 min exposure to CO₂, G_j dropped to 0% in controls and by ∼17% following CaM expression inhibition; similarly, V_j sensitivity decreased significantly. This indicates that the speed and sensitivity of V_j-dependent inactivation of Cx45 channels are increased by CO₂, and that CaM plays a role in gating. Cx32 channels behaved similarly, but the drop in both G_{j steady state}/G_{j peak} and τ with CO₂ matched more closely that of G_{j peak}. In contrast, sensitivity and speed of V_j gating of Cx40 and Cx26 channels decreased, rather than increased, with CO₂ application.     

The Carboxyl Terminal Residues 220–283 Are Not Required for Voltage Gating of a Chimeric Connexin32 Hemichannel

Connexin hemichannels display two distinct forms of voltage-dependent gating, corresponding to the operation of V_j- or fast gates and loop- or slow gates. The carboxyl terminus (CT) of connexin 32 has been reported to be required for the operation of the V_j (fast) gates, but this conclusion was inferred from the loss of a fast kinetic component in macroscopic currents of CT-truncated intercellular channels elicited by transjunctional voltage. Such inferences are complicated by presence of both fast and slow gates in each hemichannel and the serial head-to-head arrangement of these gates in the intercellular channel. Examination of voltage gating in undocked hemichannels and V_j gate polarity reversal by a negative charge substitution (N2E) in the amino terminal domain allow unequivocal separation of the two gating processes in a Cx32 chimera (Cx32^∗43E1). This chimera expresses currents as an undocked hemichannel in Xenopus oocytes and provides a model system to study the molecular determinants and mechanisms of Cx32 voltage gating. Here, we demonstrate that both V_j- and loop gates are operational in a truncation mutation that removes all but the first four CT residues (ACAR²¹⁹) of the Cx32^∗43E1 hemichannel. We conclude that an operational Cx32 V_j (fast) gate does not require CT residues 220–283, as reported previously by others.     

The Carboxyl Terminal Residues 220–283 Are Not Required for Voltage Gating of a Chimeric Connexin32 Hemichannel

Connexin hemichannels display two distinct forms of voltage-dependent gating, corresponding to the operation of V_j- or fast gates and loop- or slow gates. The carboxyl terminus (CT) of connexin 32 has been reported to be required for the operation of the V_j (fast) gates, but this conclusion was inferred from the loss of a fast kinetic component in macroscopic currents of CT-truncated intercellular channels elicited by transjunctional voltage. Such inferences are complicated by presence of both fast and slow gates in each hemichannel and the serial head-to-head arrangement of these gates in the intercellular channel. Examination of voltage gating in undocked hemichannels and V_j gate polarity reversal by a negative charge substitution (N2E) in the amino terminal domain allow unequivocal separation of the two gating processes in a Cx32 chimera (Cx32^∗43E1). This chimera expresses currents as an undocked hemichannel in Xenopus oocytes and provides a model system to study the molecular determinants and mechanisms of Cx32 voltage gating. Here, we demonstrate that both V_j- and loop gates are operational in a truncation mutation that removes all but the first four CT residues (ACAR²¹⁹) of the Cx32^∗43E1 hemichannel. We conclude that an operational Cx32 V_j (fast) gate does not require CT residues 220–283, as reported previously by others.     

Chemical gating of gap junction channels

Chemical gating of gap junction channels is a complex phenomenon that may involve intra- and intermolecular interactions among connexin domains and a cytosolic molecule (calmodulin?) that may function as channel plug. This article focuses on the methodology we have employed for studying the molecular basis of chemical gating by lowered cytosolic pH. Our approach has combined molecular genetics and biophysics, using exposure to 100% CO(2) for assaying chemical gating efficiency. Chimeras of connexin 32 (Cx32) and connexin 38 (Cx38) and Cx32 mutants modified at residues of the cytoplasmic loop, the initial C-terminus domain, or both have been expressed in Xenopus oocytes, and channel expression and gating have been tested electrophysiologically by double voltage clamp. In addition, various channel forms, including homotypic, heterotypic, and heteromeric channel combinations, have been evaluated for chemical gating sensitivity.     

Is the chemical gate of connexins voltage sensitive? Behavior of Cx32 wild-type and mutant channels

Connexinchannels are gated by transjunctional voltage(V_j)or CO₂ via distinct mechanisms.The cytoplasmic loop (CL) and arginines of a COOH-terminal domain(CT₁) of connexin32 (Cx32) wereshown to determine CO₂sensitivity, and a gating mechanism involvingCL-CT₁ association-dissociationwas proposed. This study reports that Cx32 mutants, tandem, 5R/E, and5R/N, designed to weaken CL-CT₁interactions, display atypicalV_jand CO₂ sensitivities when testedheterotypically with Cx32 wild-type channels inXenopus oocytes. In tandems, two Cx32monomers are linked NH₂-to-COOH terminus. In 5R/E and 5R/N mutants, glutamates or asparagines replaceCT₁ arginines. On the basis of theintriguing sensitivity of the mutant-32 channel toV_jpolarity, the existence of a "slow gate" distinct from theconventionalV_jgate is proposed. To a lesser extent the slow gatemanifests itself also in homotypic Cx32 channels. Mutant-32 channelsare more CO₂ sensitive than homotypic Cx32 channels, andCO₂-induced chemical gating isreversed with relative depolarization of the mutant oocyte, suggesting V_jsensitivity of chemical gating. A hypothetical pore-plugging modelinvolving an acidic cytosolic protein (possibly calmodulin) is discussed.

     

Gap junction gating sensitivity to physiological internal calcium regardless of pH in Novikoff hepatoma cells.

Gap junction conductance (Gj) and channel gating sensitivity to voltage, Ca2+, H+, and heptanol were studied by double whole-cell clamp in Novikoff hepatoma cell pairs. Channel gating was observed at transjunctional voltages (Vj) > +/- 50 mV. The cells readily uncoupled with 1 mM 1-heptanol. With heptanol, single (gap junctional) channel events with unitary conductances (gamma j) of 46 and 97 pS were detected. Both Ca(2+)-loading (EGTA.Ca) and acidifying (100% CO2) solutions caused uncoupling. However, CO2 was effective when Ca2+i was buffered with EGTA (a H(+)-sensitive Ca-buffer) but not with BAPTA (1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid) (a H(+)-insensitive Ca-buffer), suggesting a Ca(2+)-mediated H+ effect on gap junctions. This was tested by monitoring the Gj decay at different pCai values (9, 6.9, 6.3, 6, and 5.5; 1 mM BAPTA) and pHi values (7.2 or 6.1, 10 mM 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid and 2-(N-morpholino)ethansulphonic acid, respectively). With pCai > or = 6.9 (pH 7.2 or 6.1), Gj decreased to 10-70% of initial values in approximately 40 min, following single exponential decays (tau = approximately 28 min). With pCai 6-6.3 (pH 7.2 or 6.1), Gj decreased to 10-25% of initial values in 15 min (tau = approximately 5 min); the Student t gave a P = 0.0178. With pCa 5.5 the cells uncoupled in less than 1 min (tau = approximately 20 s). Low pHi affected neither time course nor shape of Gj decay at any pCai tested. The data indicate that these gap junctions are sensitive to [Ca2+]i in the physiological range (< or = 500 nM) and that low pHi, without an increase in [Ca2+]i, neither decreases Gj nor increases channel sensitivity to Ca2+.     

Characterization of the Structure and Intermolecular Interactions between the Connexin 32 Carboxyl-terminal Domain and the Protein Partners Synapse-associated Protein 97 and Calmodulin

In Schwann cells, connexin 32 (Cx32) can oligomerize to form intracellular gap junction channels facilitating a shorter pathway for metabolite diffusion across the layers of the myelin sheath. The mechanisms of Cx32 intracellular channel regulation have not been clearly defined. However, Ca(2+), pH, and the phosphorylation state can regulate Cx32 gap junction channels, in addition to the direct interaction of protein partners with the carboxyl-terminal (CT) domain. In this study, we used different biophysical methods to determine the structure and characterize the interaction of the Cx32CT domain with the protein partners synapse-associated protein 97 (SAP97) and calmodulin (CaM). Our results revealed that the Cx32CT is an intrinsically disordered protein that becomes α-helical upon binding CaM. We identified the GUK domain as the minimal SAP97 region necessary for the Cx32CT interaction. The Cx32CT residues affected by the binding of CaM and the SAP97 GUK domain were determined as well as the dissociation constants for these interactions. We characterized three Cx32CT Charcot-Marie-Tooth disease mutants (R219H, R230C, and F235C) and identified that whereas they all formed functional channels, they all showed reduced binding affinity for SAP97 and CaM. Additionally, we report that in RT4-D6P2T rat schwannoma cells, Cx32 is differentially phosphorylated and exists in a complex with SAP97 and CaM. Our studies support the importance of protein-protein interactions in the regulation of Cx32 gap junction channels and myelin homeostasis.     

Inversion of both gating polarity and CO2 sensitivity of voltage gating with D3N mutation of Cx50

The effect of CO₂-induced acidification on transjunctional voltage (V_j) gating was studied by dual voltage-clamp in oocytes expressing mouse connexin 50 (Cx50) or a Cx50 mutant (Cx50-D3N), in which the third residue, aspartate (D), was mutated to asparagine (N). This mutation inverted the gating polarity of Cx50 from positive to negative. CO₂ application greatly decreased the V_j sensitivity of Cx50 channels, and increased that of Cx50-D3N channels. CO₂ also affected the kinetics of V_j dependent inactivation of junctional current (I_j), decreasing the gating speed of Cx50 channels and increasing that of Cx50-D3N channels. In addition, the D3N mutation increased the CO₂ sensitivity of chemical gating such that even CO₂ concentrations as low as 2.5% significantly lowered junctional conductance (G_j). With Cx50 channels G_j dropped by 78% with a drop in intracellular pH (pH_i) to 6.83, whereas with Cx50-D3N channels G_j dropped by 95% with a drop in pH_i to just 7.19. We have previously hypothesized that the way in which V_j gating reacts to CO₂ might be related to connexin’s gating polarity. This hypothesis is confirmed here by evidence that the D3N mutation inverts the gating polarity as well as the effect of CO₂ on V_j gating sensitivity and speed. cell communication; lens; gap junctions; chemical gating; channel gating; Xenopus oocytes     

Interplay between cystic fibrosis transmembrane regulator and gap junction channels made of connexins 45, 40, 32 and 50 expressed in oocytes

The cystic fibrosis transmembrane regulator (CFTR) is a Cl(-) channel known to influence other channels, including connexin (Cx) channels. To study the functional interaction between CFTR and gap junction channels, we coexpressed in Xenopus oocytes CFTR and either Cx45, Cx40, Cx32 or Cx50 and monitored junctional conductance (G (j)) and its sensitivity to transjunctional voltage (V (j)) by the dual voltage-clamp method. Application of forskolin induced a Cl(-) current; increased G (j) approximately 750%, 560%, 64% and 8% in Cx45, Cx40, Cx32 and Cx50, respectively; and decreased sensitivity to V (j ) gating, monitored by a change in the ratio between G (j) steady state and G (j) peak (G (j)SS/G (j)PK) at the pulse. In oocyte pairs expressing just Cx45 in one oocyte (#1) and both Cx45 and CFTR in the other (#2), with negative pulses applied to oocyte #1 forskolin application still increased G (j) and decreased the sensitivity to V (j) gating, indicating that CFTR activation is effective even when it affects only one of the two hemichannels and that the G (j) and V (j) changes are not artifacts of decreased membrane resistance in the pulsed oocyte. COOH-terminus truncation reduced the forskolin effect on Cx40 (Cx40TR) but not on Cx32 (Cx32TR) channels. The data suggest a cross-talk between CFTR and a variety of gap junction channels. Cytoskeletal scaffolding proteins and/or other intermediate cytoplasmic proteins are likely to play a role in CFTR-Cx interaction.     

The Voltage Gates of Connexin Channels are Sensitive to CO2

Cx45 channel sensitivity to CO₂, transjunctional voltage (V_j) and inhibition of calmodulin (CaM) expression was tested in oocytes by dual voltage-clamp. Cx45 channels are very sensitive to V_jand close preferentially by the slow gate, likely the same as the chemical gate. With CO₂-induced drop in junctional conductance (G_j), the speed of V_j-dependent inactivation of junctional current (I_j) and V_jsensitivity increased. With 40 mV V_j, the τ of single exponential I_jdecay reversibly decreased by ～40% with CO₂, and G_{j steady state}/G_{j peak}decreased multiphasically, indicating that kinetics and V_jsensitivity of chemical/slow-V_jgating are altered by changes in [H⁺]_iand/or [Ca²⁺]_i. With 15 min exposure to CO₂, G_jdropped to 0% in controls and by ～17% following CaM expression inhibition; similarly, V_jsensitivity decreased significantly. This indicates that the speed and sensitivity of V_j-dependent inactivation of Cx45 channels are increased by CO₂, and that CaM plays a role in gating. Cx32 channels behaved similarly, but the drop in both G_{j steady state}/G_{j peak}and τ with CO₂matched more closely that of G_{j peak}. In contrast, sensitivity and speed of V_jgating of Cx40 and Cx26 channels decreased, rather than increased, with CO₂application.     

Engineering the substrate specificity of porcine kidney D-amino acid oxidase by mutagenesis of the "active-site lid"

Comparison of the primary structures of pig kidney D-amino acid oxidase (DAO) and human brain D-aspartate oxidase (DDO) revealed a notable difference at I215-N225 of DAO and the corresponding region, R216-G220, of DDO. A DAO mutant, in which I215-N225 is substituted by R216-G220 of DDO, showed D-aspartate-oxidizing activity that wild-type DAO does not exhibit, together with a considerable decrease in activity toward D-alanine. These findings indicate that I215-N225 of DAO contributes profoundly to its substrate specificity. Based on these results and the crystal structure of DAO, we systematically mutated the E220-Y224 region within the short stretch in question and obtained five mutants (220D224G, 221D224G, 222D224G, 223D224G, and 224D), in each of which an aspartate residue is mutated to E220-Y224. All of the mutants exhibited decreased apparent K(m) values toward D-arginine, i.e., to one-seventh to one-half that of wild type DAO. The specificity constant, k(cat app)/K(m app), for D-arginine increased by one order of magnitude for the 221D224G or 222D224G mutant, whereas that for D-alanine or D-serine decreased to marginal or nil.     

Molecular dissection of transjunctional voltage dependence in the connexin-32 and connexin-43 junctions.

Most gap junction channels are sensitive to the voltage difference between the two cellular interiors, termed the transjunctional voltage (V(j)). In several junctions, the conductance transitions induced by V(j) show more than one kinetic component. To elucidate the structural basis of the fast and slow components that characterize the V(j )dependence of connexin-32 (Cx32) and connexin-43 (Cx43) junctions, we created deletions of both connexins, where most of the carboxy-terminal (CT) domain was removed. The wild-type and "tailless" mutants were expressed in paired Xenopus oocytes, and the macroscopic gating properties were analyzed using the dual voltage clamp technique. Truncation of the CT domain of Cx32 and Cx43 abolished the fast mechanism of conductance transitions and induced novel gating properties largely attributable to the slow mechanism of gating. The formation of hybrid junctions comprising wild-type and truncated hemichannels allowed us to infer that the fast and slow components of gating reside in each hemichannel and that both gates close at a negative V(j) on the cytoplasmic side. Thus we conclude that the two kinetic components of V(j)-sensitive conductance are a result of the action of two different gating mechanisms. They constitute separate structures in the Cx32 and Cx43 molecules, the CT domain being an integral part of fast V(j) gating.     

Membrane-protein interactions contribute to efficient 27-hydroxylation of cholesterol by mitochondrial cytochrome P450 27A1

Mitochondrial cytochrome P450 27A1 (P450 27A1) catalyzes 27-hydroxylation of cholesterol, the first step in the alternative bile acid biosynthetic pathway. Although several crystal structures of P450s are known, no structural information is available for the mammalian, membrane-bound enzymes involved in the removal of cholesterol from the body. We prepared a three-dimensional model of P450 27A1 based on the structure of P450 BM-3. Conservative and non-conservative mutations were introduced at hydrophobic and positively charged residues in the putative F-G loop and the adjacent helix G (positions 219-237). Subcellular distribution of the mutant P450s expressed in Escherichia coli was used as a measure of membrane-protein interactions. Conservative substitutions of residues located on the surface, according to our model, L219V, L219I, Y220F, F223Y, L224I, R229K, V231L, F234Y, K236R, and R237K, weakened the association of the mutant P450s with the membrane and led to the appearance of up to 21% of P450 27A1 in the bacterial cytosol. It is likely that the mutated side chains are involved in binding to membrane phospholipids. Substitutions in the F-G loop did not significantly affect the K(m) value for cholesterol hydroxylation. However, non-conservative mutants, L219N, Y220A, Y220S, F223A, K226R, and R229A, had significantly impaired catalytic properties, indicating strict requirements for the size and polarity of the side chains at these positions for the catalysis. The results provide insight into the membrane topology of mitochondrial P450s and indicate the importance of membrane-protein interactions in the efficiency of reactions catalyzed by P450 27A1.     

Stoichiometry of transjunctional voltage-gating polarity reversal by a negative charge substitution in the amino terminus of a connexin32 chimera

Gap junctions are intercellular channels formed by the serial, head to head arrangement of two hemichannels. Each hemichannel is an oligomer of six protein subunits, which in vertebrates are encoded by the connexin gene family. All intercellular channels formed by connexins are sensitive to the relative difference in the membrane potential between coupled cells, the transjunctional voltage (Vj), and gate by the separate action of their component hemichannels (Harris, A.L., D.C. Spray, and M.V. Bennett. 1981. J. Gen. Physiol. 77:95-117). We reported previously that the polarity of Vj dependence is opposite for hemichannels formed by two closely related connexins, Cx32 and Cx26, when they are paired to form intercellular channels (Verselis, V.K., C.S. Ginter, and T.A. Bargiello. 1994. Nature. 368:348-351). The opposite gating polarity is due to a difference in the charge of the second amino acid. Negative charge substitutions of the neutral asparagine residue present in wild-type Cx32 (Cx32N2E or Cx32N2D) reverse the gating polarity of Cx32 hemichannels from closure at negative Vj to closure at positive Vj. In this paper, we further examine the mechanism of polarity reversal by determining the gating polarity of a chimeric connexin, in which the first extracellular loop (E1) of Cx32 is replaced with that of Cx43 (Cx43E1). The resulting chimera, Cx32*Cx43E1, forms conductive hemichannels when expressed in single Xenopus oocytes and intercellular channels in pairs of oocytes (Pfahnl, A., X.W. Zhou, R. Werner, and G. Dahl. 1997. Pflügers Arch. 433:733-779). We demonstrate that the polarity of Vj dependence of Cx32*Cx43E1 hemichannels in intercellular pairings is the same as that of wild-type Cx32 hemichannels and is reversed by the N2E substitution. In records of single intercellular channels, Vj dependence is characterized by gating transitions between fully open and subconductance levels. Comparable transitions are observed in Cx32*Cx43E1 conductive hemichannels at negative membrane potentials and the polarity of these transitions is reversed by the N2E substitution. We conclude that the mechanism of Vj dependence of intercellular channels is conserved in conductive hemichannels and term the process Vj gating. Heteromeric conductive hemichannels comprised of Cx32*Cx43E1 and Cx32N2E*Cx43E1 subunits display bipolar Vj gating, closing to substates at both positive and negative membrane potentials. The number of bipolar hemichannels observed in cells expressing mixtures of the two connexin subunits coincides with the number of hemichannels that are expected to contain a single oppositely charged subunit. We conclude that the movement of the voltage sensor in a single connexin subunit is sufficient to initiate Vj gating. We further suggest that Vj gating results from conformational changes in individual connexin subunits rather than by a concerted change in the conformation of all six subunits.     

CO<Subscript>2</Subscript> Sensitivity of Voltage Gating and Gating Polarity of GapJunction Channels—Connexin40 and its COOH-Terminus-Truncated Mutant

The CO₂ sensitivity of transjunctional voltage (V _j) gating was studied by dual voltage clamp in oocytes expressing mouse Cx40 or its COOH terminus (CT)-truncated mutant (Cx40-TR). V _j sensitivity, determined by a standard V _j protocol (20 mV V _j steps, 120 mV maximal), decreased significantly with exposure to 30% CO₂. The Boltzmann values of control versus CO₂-treated oocytes were: V ₀ = 36.3 and 48.7 mV, n = 5.4 and 3.7, and G _{j min} = 0.21 and 0.31, respectively. CO₂ also affected the kinetics of V _j-dependent inactivation of junctional current (I _j); the time constants of two-term exponential I _j decay, measured at V _j = 60 mV, increased significantly with CO₂ application. Similar results were obtained with Cx40-TR, suggesting that CT does not play a role in this phenomenon. The sensitivity of Cx40 channels to 100% CO₂ was also unaffected by CT truncation. There is evidence that CO₂ decreases the V _j sensitivity of Cx26, Cx50 and Cx37 as well, whereas it increases that of Cx45 and Cx32 channels. Since Cx40, Cx26, Cx50 and Cx37 gate at the positive side of V _j, whereas Cx45 and Cx32 gate at negative V _j, it is likely that V _j behavior with respect to CO₂-induced acidification varies depending on gating polarity, possibly involving the function of the postulated V _j sensor (NH₂-terminus).This revised version was published online in June 2005 with a corrected cover date.