Tertiary contacts of helix V in the lactose permease determined by site-directed chemical cross-linking in situ

The six N-terminal transmembrane helices (N6) and the six C-terminal transmembrane helices (C6) in lactose permease, each containing a single Cys residue, were coexpressed, and cross-linking was studied. The proximity of paired Cys residues in helices V and VII, VIII, or X was studied by thiol-specific chemical cross-linking. The results demonstrate that Cys residues in the periplasmic half of helix V cross-link with Cys residues in the periplasmic half of helix VII. In contrast, no cross-linking is evident with paired Cys residues in the cytoplasmic halves of helices V and VII. Moreover, Cys residues on one entire face of helix V cross-link with Cys residues on one face of helix VIII. Finally, paired Cys residues at the cytoplasmic ends of helices V and X cross-link, but no cross-linking is observed when paired Cys residues are placed at the periplasmic ends of the two helices. Taken together, the results indicate that the periplasmic halves of helices V and VII are in close proximity and that the two helices tilt away from one another toward the cytoplasmic side of the membrane. Furthermore, helices V and VIII are in close proximity throughout their lengths and do not tilt appreciably with respect to one another, and helices V and X are in close proximity at the cytoplasmic but not at the periplasmic face of the membrane.     

Helix packing in the lactose permease of Escherichia coli determined by site-directed thiol cross-linking: helix I is close to helices V and XI

Coexpression of lacY gene fragments encoding the first two transmembrane domains and the remaining 10 transmembrane domains complement in the membrane and catalyze active lactose transport [Wrubel, W., Stochaj, U., et al. (1990) J. Bacteriol. 172, 5374-5381]. Accordingly, a plasmid encoding contiguous, nonoverlapping permease fragments with a discontinuity in the cytoplasmic loop between helices II and III (loop II/III) was constructed (N2C10 permease). When Phe27 (helix I) is replaced with Cys, cross-linking is observed with two native Cys residues, Cys148 (helix V) and Cys355 (helix XI). Cross-linking of a Cys residue at position 27 to Cys148 occurs with N,N'-o-phenylenedimaleimide (o-PDM; rigid 6 A), with N,N'-p-phenylenedimaleimide (p-PDM; rigid 10 A), or with 1,6-bis(maleimido)hexane (BMH; flexible 16 A). On the other hand, with the Phe27-->Cys/Cys355 pair, cross-linking is observed with p-PDM or BMH but not o-PDM. In neither case is cross-linking observed with iodine. It is suggested that a Cys residue at position 27 is within 6-10 A from Cys148 and about 10 A from Cys355. The results provide evidence for proximity between helix I and helices V or XI in the tertiary structure of the permease. In addition, the findings are consistent with other results [Venkatesan, P., Kaback, H. R. (1998) Proc. Natl. Acad. Sci. U.S.A. 95, 9802-9807] indicating that Glu126 (helix IV) and Arg144 (helix V) are within the membrane, rather than at the membrane-water interface on the cytoplasmic face.     

Thiol cross-linking of transmembrane domains IV and V in the lactose permease of Escherichia coli

Glu126 (helix IV) and Arg144 (helix V) in the lactose permease of Escherichia coli are critical for substrate binding and transport, and the two residues are in close proximity and charge-paired. By using a functional permease construct with two tandem factor Xa protease sites in the cytoplasmic loop between helices IV and V, it is shown here that Cys residues in place of Glu126 and Arg144, as well as Ala122 and Val149, spontaneously form disulfide bonds in situ, indicating that this region of transmembrane domains IV and V is in the alpha-helical conformation. To determine if the local structure or environment is perturbed by the presence of an unpaired charge, either Glu126 or Arg144 or both were replaced with Ala, and cross-linking between the Cys pair Ala122-->Cys/Val149-->Cys was studied. Ala replacement for Arg144 causes a marked decrease in cross-linking, while Ala replacement for Glu126 alone or for both Glu126 and Arg144 has little effect. The data provide strong support for the argument that Glu126 and Arg144 are within close proximity and suggest that an unpaired carboxylate at position 126 causes a structural change at the interface between helices IV and V.     

Helices VII and X in the lactose permease of Escherichia coli: proximity and ligand-induced distance changes.

By using functional lactose permease devoid of native Cys residues with a discontinuity in the periplasmic loop between helices VII and VIII (N(7)/C(5) split permease), cross-linking between engineered paired Cys residues in helices VII and X was studied with the homobifunctional, thiol-specific cross-linkers 1,1-methanediyl bismethanethiosulfonate (3 A), N,N'-o- phenylenedimaleimide (6 A) and N,N'-p-phenylenedimaleimide (10 A). Mutant Asp240-->Cys (helix VII)/Lys319-->Cys (helix X) cross-links most efficiently with the 3 A reagent, providing direct support for studies indicating that Asp240 and Lys319 are in close proximity and charge paired. Furthermore, cross-linking the two positions inactivates the protein. Other Cys residues more disposed towards the middle of helix VII cross-link to Cys residues in the approximate middle of helix X, while no cross-linking is evident with paired Cys residues at the periplasmic or cytoplasmic ends of these helices. Thus, helices VII and X are in close proximity in the middle of the membrane. In the presence of ligand, the distance between Cys residues at positions 240 (helice VII) and 319 (helix X) increases. In contrast, the distance between paired Cys residues more disposed towards the cytoplasmic face of the membrane decreases in a manner suggesting that ligand binding induces a scissors-like movement between the two helices. The results are consistent with a recently proposed mechanism for lactose/H(+) symport in which substrate binding induces a conformational change between helices VII and X, during transfer of H(+) from His322 (helix X)/Glu269 (helix VIII) to Glu325 (helix X).     

Proximity relationships between helices I and XI or XII in the lactose permease of Escherichia coli determined by site-directed thiol cross-linking.

The lactose permease of Escherichia coli was expressed in two fragments (split permease), each with a Cys residue, and cross-linking was studied. Split permease with a discontinuity in either loop II/III (N2C10permease) or loop VI/VII (N6C6permease) was used. Proximity of multiple pairs of Cys residues in helices I and XI or XII was examined by using three homobifunctional thiol-specific cross-linking reagents of different lengths and flexibilities (6 A, rigid; 10 A, rigid; 16 A, flexible) or iodine. Cys residues in the periplasmic half of helix I cross-link to Cys residues in the periplasmic half of helix XI. In contrast, no cross-linking is evident with paired Cys residues near the cytoplasmic ends of helices I and XI. Therefore, the periplasmic halves of helices I and XI are in close proximity, and the helices tilt away from each other towards the cytoplasmic face of the membrane. Cross-linking is also found with paired Cys residues near the middle of helices I and XII, but not with paired Cys residues near either end of the helices. Thus, helices I and XII are in close proximity only in the approximate middle of the membrane. Based on the findings, a modified helix packing model is proposed.     

Proximity between periplasmic loops in the lactose permease of Escherichia coli as determined by site-directed spin labeling

Site-directed thiol cross-linking indicates that the first periplasmic loop (loop I/II) in the lactose permease of Escherichia coli is in close proximity to loops VII/VIII and XI/XII [Sun, J., and Kaback, H. R. (1997) Biochemistry 36, 11959-11965]. To determine whether thiol cross-linking reflects proximity as opposed to differences in the reactivity and/or dynamics of the Cys residues that undergo cross-linking, single-Cys mutants in loops I/II, VII/VIII, and XI/XII and double-Cys mutants in loop I/II and VII/VIII or XI/XII were purified and labeled with a sulfhydryl-specific nitroxide spin label. The labeled mutants were then analyzed by electron paramagnetic resonance (EPR) spectroscopy, and interspin distance was estimated from the extent of line shape broadening in the double-labeled proteins. Out of six paired double-Cys mutants that exhibit thiol cross-linking, five display significant spin-spin interaction. Furthermore, there is a qualitative correlation between distances estimated by site-directed cross-linking and EPR. Taken as a whole, the results are consistent with the conclusion that site-directed thiol cross-linking is primarily a reflection of proximity.     

Site-directed chemical cross-linking demonstrates that helix IV is close to helices VII and XI in the lactose permease

The N-terminal six transmenbrane helices (N6) and the C-terminal six transmembrane helices (C6) of the lactose permease, each containing a single-Cys residue, were coexpressed, and proximity was studied. Paired Cys residues in helices IV (positions 114, 116, 119, 122, 125, or 129) and VII (227, 231, 232, 234, 235, 238, 239, 242, 243, 245, or 246) or XI (350, 353, 354, 357, 361, or 364) were tested for cross-linking in the presence of two rigid homobifunctional thiol-specific cross-linkers, N,N'-o-phenylenedimaleimide (o-PDM; 6 A) and N,N'-p-phenylenedimaleimide (p-PDM; 10 A). Cys residues in the middle of helix IV (position 119 or 122) cross-link to Cys residues in the middle of helix VII (position 238, 239, 242, or 243). In contrast, no cross-linking is evident with paired Cys residues at either end of helix IV (position 114, 116, 125, or 129) or helix VII (position 227, 231, 232, 234, 235, 245, or 246). On the other hand, Cys residues in the cytoplasmic half of helix IV (position 125 or 129) cross-link with Cys residues in the cytoplasmic half of helix XI (position 350, 353, or 354), while paired Cys residues at the periplasmic ends of the two helices do not cross-link. The results indicate that helices IV and VII cross in a scissors-like manner with the cytoplasmic end of helix IV tilting toward helix XI.     

Estimating loop-helix interfaces in a polytopic membrane protein by deletion analysis.

Insertions of amino acids into transmembrane helices of polytopic membrane proteins disrupt helix-helix interactions with loss of function, while insertions into loops have little effect on transmembrane helices and therefore little effect on activity [Braun, P., Persson, B., Kaback, H. R., and von Heijne, G. (1997) J. Biol. Chem. 272, 29566-29571]. Here the inverse approach, amino acid deletion, is utilized systematically to approximate loop-helix boundaries in the lactose permease of Escherichia coli. Starting with deletion mutants in the periplasmic loop between helices VII and VIII (loop VII/VIII), which has been defined by immunological analysis and nitroxide-scanning electron paramagnetic resonance spectroscopy, it is shown that mutants with single or multiple deletions in the central portion of the loop retain significant transport activity, while deletion of amino acid residues near the loop-helix boundaries or within the flanking helices leads to complete inactivation. Results consistent with hydropathy analysis are obtained with loops VI/VII, VIII/IX, and IX/X and the flanking helices. In contrast, deletion analysis of loops III/IV, IV/V, and V/VI and the flanking helices indicates that this region of the permease differs from hydropathy predictions. More specifically, evidence is presented supporting the contention that Glu126 and Arg144 which are charge paired and critical for substrate binding are within helices IV and V, respectively.     

Site-directed sulfhydryl labeling of the lactose permease of Escherichia coli: helices IV and V that contain the major determinants for substrate binding

Helices IV and V in the lactose permease of Escherichia coli contain the major determinants for substrate binding [Glu126 (helix IV), Arg144 (helix V), and Cys148 (helix V)]. Structural and dynamic features of this region were studied by using site-directed sulfhydryl modification of 48 single-Cys replacement mutants with N-[(14)C]ethylmaleimide (NEM) in the absence or presence of ligand. In right-side-out membrane vesicles, Cys residues in the cytoplasmic halves of both helices react with NEM in the absence of ligand, while Cys residues in the periplasmic halves do not. Five Cys replacement mutants at the periplasmic end of helix V and one at the cytoplasmic end of helix V label only in the presence of ligand. Interestingly, in addition to native Cys148, a known binding-site residue, labeling of mutant Ala122 --> Cys, which is located in helix IV across from Cys148, is markedly attenuated by ligand. Furthermore, alkylation of the Ala122 --> Cys mutant blocks transport, and protection is afforded by substrate, indicating that Ala122 is also a component of the sugar binding site. Methanethiosulfonate ethylsulfonate, an impermeant thiol reagent shown clearly in this paper to be impermeant in E. coli spheroplasts, was used to identify substituted Cys side chains exposed to water and accessible from the periplasmic side. Most of the Cys mutants in the cytoplasmic halves of helices IV and V, as well as two residues in the intervening loop, are accessible to the aqueous phase from the periplasmic face of the membrane. The findings indicate that the cytoplasmic halves of helices IV and V are more reactive/accessible to thiol reagents and more exposed to solvent than the periplasmic half. Furthermore, positions that exhibit ligand-induced changes are located for the most part in the vicinity of the residues directly involved in substrate binding, as well as the cytoplasmic loop between helices IV and V.     

Engineering conformational flexibility in the lactose permease of Escherichia coli: use of glycine-scanning mutagenesis to rescue mutant Glu325-->Asp

Lactose/H(+) symport by lactose permease of Escherichia coli involves interactions between four irreplaceable charged residues in transmembrane helices that play essential roles in H(+) translocation and coupling [Glu269 (helix VIII) with His322 (helix X) and Arg302 (helix IX) with Glu325 (helix X)], as well as Glu126 (helix IV) and Arg144 (helix V) which are obligatory for substrate binding. The conservative mutation Glu325-->Asp causes a 10-fold reduction in the V(max) for active lactose transport and markedly decreased lactose-induced H(+) influx with no effect on exchange or counterflow, neither of which involves H(+) symport. Thus, shortening the side chain may weaken the interaction of the carboxyl group at position 325 with the guanidino group of Arg302. Therefore, Gly-scanning mutagenesis of helices IX and X and the intervening loop was employed systematically with mutant Glu325-->Asp in an effort to rescue function by introducing conformational flexibility between the two helices. Five Gly replacement mutants in the Glu325-->Asp background are identified that exhibit significantly higher transport activity. Furthermore, mutant Val316-->Gly/Glu325-->Asp catalyzes active transport, efflux, and lactose-induced H(+) influx with kinetic properties approaching those of wild-type permease. It is proposed that introduction of conformational flexibility at the interface between helices IX and X improves juxtapositioning between Arg302 and Asp325 during turnover, thereby allowing more effective deprotonation of the permease on the inner surface of the membrane [Sahin-Tóth, M., Karlin, A., and Kaback, H. R. (2000) Proc. Natl. Acad. Sci. U.S.A. 97, 10729-10732.     

Functional estimation of loop-helix boundaries in the lactose permease of Escherichia coli by single amino acid deletion analysis

Mutants with single amino acid deletions in the loops of lactose permease retain activity, while mutants with single deletions in transmembrane helices are inactive, and the loop--helix boundaries of helices IV, V, VII, VIII, and IX have been approximated functionally by the systematic deletion of single residues [Wolin, C. D., and Kaback, H. R. (1999) Biochemistry 38, 8590-8597]. The experimental approach is applied here to the remainder of the permease. Periplasmic and cytoplasmic loop-helix boundaries for helices I, II, X, XI, and XII and the cytoplasmic boundary of helix III are in reasonable agreement with structural predictions. In contrast, the periplasmic end of helix III appears to be five to eight residues further into the transmembrane domain than predicted. Taken together with the previous findings, the analysis estimates that 11 of the 12 transmembrane helices have an average length of 21 residues. Surprisingly, deletion analysis of loop V/VI, helix VI, and loop VI/VII does not yield an activity profile typical of the rest of the protein, as individual deletion of only three residues in this region abolishes activity. Thus, transmembrane domain VI which is probably on the periphery of the 12-helix bundle may make few functionally important contacts.     

Loop X/XI, the largest cytoplasmic loop in the membrane-bound melibiose carrier of Escherichia coli, is a functional re-entrant loop

The melibiose carrier of Escherichia coli is a membrane-bound sugar-cation cotransporter consisting of 12 transmembrane helices connected by cytoplasmic and periplasmic loops, with both N- and C-terminus on the cytoplasmic side. Using a functional cysteine-less carrier, cysteine was substituted individually for residues 347-378 that comprise the largest cytoplasmic loop X/XI. The majority of the cysteine mutants have good protein expression levels. The cysteine mutants were studied for their transport activities, and the inhibitory effects of two sulfhydryl reagents, PCMBS (7-A long) and BM (29-A long). Cysteine substitution resulted in substantial loss of transport in 12 mutants. While PCMBS caused significant inhibition in only two mutants, T373C and V376C, from the periplasmic side (in a substrate-protective manner), more extensive inhibition pattern was observed from the cytoplasmic side, in seven mutants: V353C, Y358C, V371C, Q372C, T373C, V376C and G378C, suggesting that these residues are along the sugar pathway in the aqueous channel, close to the cytoplasmic side. Furthermore, the inhibitory effect of BM on the inside-out vesicles of the above mutants was clearly less than that of PCMBS, suggesting channel space limitation to large molecules, consistent with those residues being inside the channel. Three second-site revertants (A350C/F268L, A350C/I22S, and A350C/I22N) were selected. They may suggest proximities between loop X/XI and helices I and VIII, in agreement with a re-entrant loop structure. Self thiol cross-linkings of the cysteine mutants on loop X/XI failed to form dimers, suggesting that most of the loop is not surface-exposed from cytoplasmic side. Together, these results strongly indicated a functional re-entrant loop mechanistically important in Na+-coupled transporters.     

Proximity of cytoplasmic and periplasmic loops in NhaA Na+/H+ antiporter of Escherichia coli as determined by site-directed thiol cross-linking

The unique trypsin cleavable site of NhaA, the Na(+)/H(+) antiporter of Escherichia coli, was exploited to detect a change in mobility of cross-linked products of NhaA by polyacrylamide gel electrophoresis. Double-Cys replacements were introduced into loops, one on each side of the trypsin cleavage site (Lys 249). The proximity of paired Cys residues was assessed by disulfide cross-linking of the two tryptic fragments, using three homobifunctional cross-linking agents: 1,6-bis(maleimido)hexane (BMH), N,N'-o-phenylenedimaleimide (o-PDM), and N,N'-p-phenylenedimaleimide (p-PDM). The interloop cross-linking was found to be very specific, indicating that the loops are not merely random coils that interact randomly. In the periplasmic side of NhaA, two patterns of cross-linking are observed: (a) all three cross-linking reagents cross-link very efficiently between the double-Cys replacements A118C/S286C, N177C/S352C, and H225C/S352C; (b) only BMH cross-links the double-Cys replacements A118C/S352C, N177C/S286C, and H225C/S286C. In the cytoplasmic side of NhaA, three patterns of cross-linking are observed: (a) all three cross-linking reagents cross-link very efficiently the pairs of Cys replacements L4C/E252C, S146C/L316C, S146C/R383C, and E241C/E252C; (b) BMH and p-PDM cross-link efficiently the pairs of Cys replacements S87C/E252C, S87C/L316C, and S146C/E252C; (c) none of the reagents cross-links the double-Cys replacements L4C/L316C, L4C/R383C, S87C/R383C, A202C/E252C, A202C/L316C, A202C/R383C, E241C/L316C, and E241C/R383C. The data reveal that the N-terminus and loop VIII-IX that have previously been shown to change conformation with pH are in close proximity within the NhaA protein. The data also suggest close proximity between N-terminal and C-terminal helices at both the cytoplasmic and the periplasmic face of NhaA.     

Characterization of a lactose permease mutant that binds IIAGlc in the absence of ligand

Enzyme IIA(Glc) of the Escherichia coli phosphoenolpyruvate:glucose phosphotransferase system plays a direct role in regulating inducible transport systems. Dephosphorylated IIA(Glc) binds directly to lactose permease in a reaction that requires binding of a galactosidic substrate. A double-Cys mutation (Ile129 --> Cys/Lys131 --> Cys) was introduced into helix IV of the permease near the IIA(Glc) binding site in cytoplasmic loop IV/V and in the vicinity of the galactoside binding site at the interface of helices IV, V, and VIII. The mutant no longer requires galactoside for IIA(Glc) binding as demonstrated by both a [(125)I]IIA(Glc) binding assay and a newly developed fluorescence anisotropy assay. Further characterization of the mutant shows that it binds substrate with high affinity, but is almost completely defective in all modes of translocation across the cytoplasmic membrane. The data are consistent with the interpretation that the double mutant is locked in an inward-facing conformation.     

The cytoplasmic loops of subunit a of Escherichia coli ATP synthase may participate in the proton translocating mechanism

Subunit a plays a key role in promoting H(+) transport and the coupled rotary motion of the subunit c ring in F(1)F(0)-ATP synthase. H(+) binding and release occur at Asp-61 in the middle of the second transmembrane helix (TMH) of F(0) subunit c. H(+) are thought to reach Asp-61 via aqueous pathways mapping to the surfaces of TMHs 2-5 of subunit a based upon the chemical reactivity of Cys substituted into these helices. Here we substituted Cys into loops connecting TMHs 1 and 2 (loop 1-2) and TMHs 3 and 4 (loop 3-4). A large segment of loop 3-4 extending from loop residue 192 loop to residue 203 in TMH4 at the lipid bilayer surface proved to be very sensitive to inhibition by Ag(+). Cys-161 and -165 at the other end of the loop bordering TMH3 were also sensitive to inhibition by Ag(+). Further Cys substitutions in residues 86 and 93 in the middle of the 1-2 loop proved to be Ag(+)-sensitive. We next asked whether the regions of Ag(+)-sensitive residues clustered together near the surface of the membrane by combining Cys substitutions from two domains and testing for cross-linking. Cys-161 and -165 in loop 3-4 were found to cross-link with Cys-202, -203, or -205, which extend into TMH4 from the cytoplasm. Further Cys at residues 86 and 93 in loop 1-2 were found to cross-link with Cys-195 in loop 3-4. We conclude that the Ag(+)-sensitive regions of loops 1-2 and 3-4 may pack in a single domain that packs at the ends of TMHs 3 and 4. We suggest that the Ag(+)-sensitive domain may be involved in gating H(+) release at the cytoplasmic side of the aqueous access channel extending through F(0).     

Proximity between Glu126 and Arg144 in the lactose permease of Escherichia coli.

Evidence has been presented [Venkatesan, P., and Kaback, H. R. (1998) Proc. Natl. Acad. Sci. U.S.A. 95, 9802-9807] that Glu126 (helix IV) and Arg144 (helix V) which are critical for substrate binding in the lactose permease of Escherichia coli are charge paired and therefore in close proximity. To test this conclusion more directly, three different site-directed spectroscopic techniques were applied to permease mutants in which Glu126 and/or Arg144 were replaced with either His or Cys residues. (1) Glu126-->His/Arg144-->His permease containing a biotin acceptor domain was purified by monomeric avidin affinity chromatography, and Mn(II) binding was assessed by electron paramagnetic resonance spectroscopy. The mutant protein binds Mn(II) with a KD of about 40 microM at pH 7.5, while no binding is observed at pH 5.5. In addition, no binding is detected with Glu126-->His or Arg144-->His permease. (2) Permease with Glu126-->Cys/Arg144-->Cys and a biotin acceptor domain was purified, labeled with a thiol-specific nitroxide spin-label, and shown to exhibit spin-spin interactions in the frozen state after reconstitution into proteoliposomes. (3) Glu126-->Cys/Arg144-->Cys permease with a biotin acceptor domain was purified and labeled with a thiol-specific pyrene derivative, and fluorescence spectra were obtained after reconstitution into lipid bilayers. An excimer band is observed with the reconstituted E126C/R144C mutant, but not with either single-Cys mutant or when the single-Cys mutants are mixed prior to reconstitution. The results provide strong support for the conclusion that Glu126 (helix IV) and Arg144 (helix V) are in close physical proximity.     

Sequence dependent conformations of oligomeric DNA's in aqueous solutions and in crystals

In order to determine the sequence dependence of the conformation of deoxynucleotides, Raman spectra have been obtained for the following oligodeoxynucleotides in aqueous salt solutions and in crystals: d(CpG)(I), d(TGCGCGCA)(II), d(CACGCGTG)(III), d(CGTGCACG)(IV), d(CGCATGCG)(V), d(ACGCGCGT)(VI), d(CGCGTACGCG)(VII), d(CGCACGTGCG)(VIII) and d(CGTGCGCACG)(IX), d(GCTATAGC) (X), d(GCATATGC) (XI), d(GGTATACC) (XII) and d(GGATATCC) (XIII). The normal B type conformation is observed for all the oligomer DNA's at low salt (0.1-1.0 M NaCl) concentration in the temperature range of 0-25 degrees C. It was considered possible that all of the first nine oligomers could go into the Z form in aqueous high salt (5.0-6.0 M NaCl) solutions, and under these conditions the last four were considered candidates to go into the A form. The B-type conformation was found to exist in high salt solutions for (I), (IV), (V), (VI), (X), (XI) and (XIII); the Z or partial Z conformation appears in high salt solution for the oligomers, (II), (III), (VII), (VIII) and (IX); an A or partial A conformation appears in high salt solution for (XII). In the crystalline state, (IV), (VIII), (X), and (XI) stay in the B-form and all of the other oligomers adopt the complete Z-form except for (XII) which crystallizes in the A form. In both the crystal and in aqueous solutions, the identification of the conformation genus was made by means of Raman spectroscopy. In the crystal of (I), grown at pH7.0, guanosine is found to be in C3'-endo/syn conformation and cytidine in C2'-endo/anti, which may be taken as the ideal building block of the typical Z conformation. At pH4, (I) crystallizes in a conformation similar to the B genus. A study of the thermally induced B to Z transition has been carried out for (II) and (III). Based on the analysis of Raman spectra of the alternating pyrimidine-purine oligomers which might be expected to go into the Z form, the tendency for these oligonucleotides to adopt the Z form can be ranked as: d(CGCGCGCG) greater than (II) greater than (III) greater than (V) approximately (VI) greater than (IV) for octamers and (VII) greater than (VIII) greater than (IX) for the decamers. Similarly, those oligomers which might have a tendency to go into the A form could be ranked as (XII) greater than (XIII) approximately (X) greater than (XI). These data should provide help in formulating rules for predicting the sequence dependence of the B to A and B to Z transitions. Some possible rules are explored, but precautions should be taken.     

Manipulating conformational equilibria in the lactose permease of Escherichia coli.

A mechanism proposed for lactose/H(+) symport by the lactose permease of Escherichia coli indicates that lactose permease is protonated prior to ligand binding. Moreover, in the ground state, the symported H(+) is shared between His322 (helix X) and Glu269 (helix VIII), while Glu325 (helix X) is charge-paired with Arg302 (helix IX). Substrate binding at the outer surface between helices IV (Glu126) and V (Arg144, Cys148) induces a conformational change that leads to transfer of the H(+) to Glu325 and reorientation of the binding site to the inner surface. After release of substrate, Glu325 is deprotonated on the inside due to re-juxtapositioning with Arg302. The conservative mutation Glu269-->Asp causes a 50-100-fold decrease in substrate binding affinity and markedly reduced active lactose transport, as well as decreased rates of equilibrium exchange and efflux. Gly-scanning mutagenesis of helix VIII was employed systematically with mutant Glu269-->Asp in an attempt to rescue function, and two mutants with increased activity are identified and characterized. Mutant Thr266-->Gly/Met267-->Gly/Glu269-->Asp binds ligand with increased affinity and catalyzes active lactose transport with a marked increase in rate; however, little improvement in efflux or equilibrium exchange is observed. In contrast, mutant Gly262-->Ala/Glu269-->Asp exhibits no improvement in ligand binding but a small increase in the rate of active transport; however, an increase in the steady-state level of accumulation, as well as efflux and equilibrium exchange is observed. Remarkably, when the two sets of mutations are combined, all translocation reactions are rescued to levels approximating those of wild-type permease. The findings support the contention that Glu269 plays a pivotal role in the mechanism of lactose/H(+) symport. Moreover, the results suggest that the two classes of mutants rescue activity by altering the equilibrium between outwardly and inwardly facing conformations of the permease such that impaired protonation and/or H(+) transfer is enhanced from one side of the membrane or the other. When the two sets of mutants are combined, the equilibrium between outwardly and inwardly facing conformations and thus protonation and H(+) transfer are restored.     

Identification of the cadaverine recognition site on the cadaverine-lysine antiporter CadB

Amino acid residues involved in cadaverine uptake and cadaverine-lysine antiporter activity were identified by site-directed mutagenesis of the CadB protein. It was found that Tyr(73), Tyr(89), Tyr(90), Glu(204), Tyr(235), Asp(303), and Tyr(423) were strongly involved in both uptake and excretion and that Tyr(55), Glu(76), Tyr(246), Tyr(310), Cys(370), and Glu(377) were moderately involved in both activities. Mutations of Trp(43), Tyr(57), Tyr(107), Tyr(366), and Tyr(368) mainly affected uptake activity, and Trp(41), Tyr(174), Asp(185), and Glu(408) had weak effects on uptake. The decrease in the activities of the mutants was reflected by an increase in the K(m) value. Mutation of Arg(299) mainly affected excretion, suggesting that Arg(299) is involved in the recognition of the carboxyl group of lysine. These results indicate that amino acid residues involved in both uptake and excretion, or solely in excretion, are located in the cytoplasmic loops and the cytoplasmic side of transmembrane segments, whereas residues involved in uptake were located in the periplasmic loops and the transmembrane segments. The SH group of Cys(370) seemed to be important for uptake and excretion, because both were inhibited by the existence of Cys(125), Cys(389), or Cys(394) together with Cys(370). The relative topology of 12 transmembrane segments was determined by inserting cysteine residues at various sites and measuring the degree of inhibition of transport through crosslinking with Cys(370). The results suggest that a hydrophilic cavity is formed by the transmembrane segments II, III, IV, VI, VII, X, XI, and XII.     

Studies on heterocyclic compounds: 1,3-thiazolidin-4-one derivatives. IV. Biological activity of variously substituted 2,3-diaryl-1,3-thiazolidin-4-ones

The following 2,3-diaryl-1,3-thiazolidin-4-ones of general formula (A) were synthesized and screened for antimicrobial activity. (formula; see text) where: X = H (I, III, V, VII, IX, XI, XIII, XV, XVII, XIX, XXI, XXIII), CH3 (II, IV, VI, VIII, X, XII, XIV, XVI, XVIII, XX, XXII, XXIV); R = H (I, II, V, VI, VII, VIII, XI, XIII), 4-CH3 (XXI, XXII, XXIII, XXIV), 4-Br (III, IV, IX, X), 2-NO2 (XIII, XIV), 3-NO2 (XV, XVI), 4-NO2 (XVII, XVIII), 4-OCH3 (XIX, XX); R' = H (I, II, III, IV, XIII, XIV, XV, XVI, XVII, XVIII, XIX, XX, XXI, XXII), 4-CH3 (XXIII, XXIV), 3-Br (V, VI), 4-Br (VII, VIII, IX, X), 4-J (XI, XII). These compounds were prepared by the general synthetic procedure previously reported for the 1,3-thiazolidin-4-one derivatives already prepared and screened in this SARs program. The synthetic approach involves the cyclocondensation of the appropriate Schiff bases with alpha-mercaptoalkanoic acids. The prepared compounds were screened against S. aureus, S. beta-haemolititicus, B. subtilis, M. paratuberculosis 607, S. typhi, Kl. pneumoniae, E. coli Bb, Ps, aeruginosa, C. albicans, A. niger, S. cerevisiae by a disk-diffusion assay (Kirby-Bauer modified). The results obtained in this investigation showed that the prepared compounds exhibited varying degrees of antimicrobial activity. They were especially inhibitory toward Gram-positive bacteria, and fungi. 4-Nitroderivatives (XVII), (XVIII), and 2-nitroderivatives (XIV) and (XIII) possessed marked antimicrobial activity against S. aureus, S. beta-haemoliticus, and B. subtilis.(ABSTRACT TRUNCATED AT 250 WORDS)