Apolipophorin-III-like protein expressed in the antenna of the red imported fire ant, Solenopsis invicta Buren (Hymenoptera: Formicidae)

Antennal proteins of the male fire ant (Solenopsis invicta) were analyzed by two-dimensional gel electrophoresis, with the objective of identifying pheromone-binding proteins, which have not previously been found in ant antennae. The major low-molecular weight protein found in the male fire ant antenna was subjected to Edman degradation to determine the N-terminal amino acid sequence. Degenerate PCR primers based on this sequence were used to obtain a cDNA sequence corresponding to the full-length protein sequence. In-gel trypsin digestion followed by MALDI-TOF mass spectrometry and HPLC-ESI/MS/MS demonstrated that the protein gel spot contained only the protein corresponding to the cDNA sequence obtained by PCR. The sequence is similar to apolipophorin-III, an exchangeable lipid-binding protein. Fire ant apolipophorin-III is expressed in the antenna as well as the head, thorax and abdomen.

Estimation of Helix−Helix Association Free Energy from Partial Unfolding of Bacterioopsin

To obtain thermodynamic information about interactions between transmembrane helices in integral membrane proteins, partial unfolding of bacterioopsin in ethanol/water mixtures was studied by Förster-type resonance energy transfer (FRET) from tryptophan to a dansyl group on Lys 41. Tryptophan to dansyl FRET was detected by measuring sensitized emission at 490-500 nm from 285 nm excitation. FRET was observed in dansylbacterioopsin in apomembranes and in detergent micelles but not in 90% ethanol/water or in the chymotrypsin fragment C2 (residues 1-71). The main fluorescence donors are Trp 86 and Trp 182. Increase of FRET from C2 with added chymotrypsin fragment C1 (residues 72-248) provides an estimate of the C1-C2 association constant as 7.7 x 10(6) M(-1). With increasing ethanol concentration, the FRET signal from dansylbacterioopsin in detergent micelles disappeared with a sharp transition above 60% ethanol. No transition occurred in Trp fluorescence from bacterioopsin lacking the dansyl acceptor, nor did dansyl model compounds undergo a similar transition. Light scattering measurements show that the detergent micelles dissipate below 50% ethanol. Thus the observed transition is likely to be a partial unfolding of bacterioopsin. Assuming a two-state unfolding model, the free energy of unfolding was obtained by extrapolation as 9.0 kcal/mol. The slope of the transition (m-value) was -0.8 kcal mol(-1) M(-1). The unfolding process probably involves dissociation of several helices. The rate of association was measured by stopped-flow fluorometry. Two first-order kinetic processes were observed, having approximately equal weights, with rate constants of 2.32 s (-1) and 0.185 s(-1).

Structure and distribution of antennal sensilla of the red imported fire ant

The morphology of the antenna of the red imported fire ant, Solenopsis invicta, was examined by light microscopy, scanning electron microscopy, and transmission electron microscopy. The antennae are sexually dimorphic: the worker antenna has porous sensilla on the two distal segments (the antennal club), whereas the clubless male antenna has porous sensilla on all segments past the pedicel. The major type of porous sensilla on both male and female is sensilla tricodea curvata. However, the male s. tricodea curvata are rather uniform in size, whereas the female s. tricodea curvata vary considerably in thickness. The number of sensilla on the distal segment of the worker antenna increases with segment length. This suggests a possible mechanism by which task assignments in S. invicta could be determined by the presence or absence of sensilla sensitive to specific task-related odor or pheromone cues. The sensilla basiconica have an invariant spatial pattern on worker and queen antennae.

Self-association of helical peptides in a lipid environment

The self-association of two model transmembrane helical peptides, differing in their surface topography, was compared in mixed micelles containing 3-([3-cholamidopropyl]dimethylammonio)-1-propanesulfonate (CHAPS) and dimyristoylphosphatidylcholine (DMPC). One peptide, Ac-KKL24KK-amide (L24), has large, rotationally mobile leucine side chains and a relatively rough surface. The other peptide, Ac-KKLLLLLLAALLALLAALLALLLLLLKK-amide (L18A6), has a patch of small alanines on one side of the helix that forms a smooth surface. The aggregation state of the peptides was sampled by chemical cross-linking with bis-sulfosuccinimidyl suberate (B53). A monomer-aggregate association constant was obtained from the cross-linking results in the range of 2 x 10(5) M(-1) to 3 x I0(5) M(-1) for both peptides. Kinetics of formation of cross-linked dimers indicated that the ratio of dimerization constants for L18A6 to L24 was between 10 and 20. This suggests that the alanine patch contributes about 1.5 Kcal/mol more stabilization free energy to dimer formation of L18A6 compared to L24.

Water and carboxyl group environments in the dehydration blueshift of bacteriorhodopsin

The proton channels of the bacteriorhodopsin (BR) proton pump contain bound water molecules. The channels connect the purple membrane surfaces with the protonated retinal Schiff base at the membrane center. Films of purple membrane equilibrated at low relative humidity display a shift of the 570 nm retinal absorbance maximum to 528 nm, with most of the change occurring below 15% relative humidity. Purple membrane films were dehydrated to defined humidities between about 50 and 4.5% and examined by Fourier transform infrared difference spectroscopy. In spectra of dehydrated-minus-hydrated purple membrane, troughs are observed at 3645 and 3550 cm-1, and peaks are observed at 3665 and 3500 cm-1. We attribute these changes to water dissociation from the proton uptake channel and the resulting changes in hydrogen bonding of water that remains bound. Also, in the carboxylic acid spectral region, a trough was observed at 1742 cm-1 and a peak at 1737 cm-1. The magnitude of the trough to peak difference between 1737 and 1742 cm-1 correlates linearly with the extent of the 528 nm pigment. This suggests that a carboxylic acid group or groups is undergoing a change in environment as a result of dehydration, and that this change is linked to the appearance of the 528 nm pigment. Dehydration difference spectra with BR mutants D96N and D115N show that the 1737-1742 cm-1 change is due to Asp 96 and Asp 115. A possible mechanism is suggested that links dissociation of water in the proton uptake channel to the environmental change at the Schiff base site.

Transmembrane and water-soluble helix bundles display reverse patterns of surface roughness

Amino acid exposure and surface roughness were calculated for 12 helices from three transmembrane alpha-helix bundles and 13 helices from seven water-soluble alpha-helix bundles. Transmembrane helix bundles have relatively rough surfaces exposed to the lipid bilayer hydrocarbon chains and relatively smooth surfaces along helix-helix interfaces. This pattern is the reverse of what occurs in water-soluble helix bundles, where relatively rough surfaces are at the helix-helix interfaces and relatively smooth surfaces are exposed to water. The relatively rough exposed surfaces and buried smooth surfaces of transmembrane helices are likely to contribute to the stability of transmembrane helical bundles in a phospholipid environment.

Conformational change in bacterio-opsin on binding to retinal

The detailed mechanism of retinal binding to bacterio-opsin is important to understanding retinal pigment formation as well as to the process of membrane protein folding. We have measured the temperature dependence of bacteriorhodopsin formation from bacterio-opsin and all-trans retinal. An Arrhenius plot of the apparent second-order rate constants gives an activation energy of 11.6 +/- 0.7 kcal/mol and an activation entropy of -4 +/- 2 cal/mol deg. Comparison of the activation entropy to model compound reactions suggests that chromophore formation in bacteriorhodopsin involves a substantial protein conformational change. Cleavage of the polypeptide chain between residues 71 and 72 has little effect on the activation energy or entropy, indicating that the connecting loop between helices B and C is not involved in this conformational change.

Guanidinium restores the chromophore but not rapid proton release in bacteriorhodopsin mutant R82Q

Replacement of the Arg residue at position 82 in bacteriorhodopsin by Gln or Ala was previously shown to slow the rate of proton release and raise the pK of Asp 85, indicating that R82 is involved both in the proton release reaction and in stabilizing the purple form of the chromophore. We now find that guanidinium chloride lowers the pK of D85, as monitored by the shift of the 587-nm absorbance maximum to 570 nm (blue to purple transition) and increased yield of photointermediate M. The absorbance shift follows a simple binding curve, with an apparent dissociation constant of 20 mM. When membrane surface charge is taken into account, an intrinsic dissociation constant of 0.3 M fits the data over a range of 0.2-1.0 M cation concentration (Na+ plus guanidinium) and pH 5.4-6.7. A chloride counterion is not involved in the observed spectral changes, as chloride up to 0.2 M has little effect on the R82Q chromophore at pH 6, whereas guanidinium sulfate has a similar effect to guanidinium chloride. Furthermore, guanidinium does not affect the chromophore of the double mutant R82Q/D85N. Taken together, these observations suggest that guanidinium binds to a specific site near D85 and restores the purple chromophore. Surprisingly, guanidinium does not restore rapid proton release in the photocycle of R82Q. This result suggests either that guanidinium dissociates during the pump cycle or that it binds with a different hydrogen-bonding geometry than the Arg side chain of the wild type.

Effect of transmembrane helix packing on tryptophan and tyrosine environments in detergent-solubilized bacterio-opsin

Bacterio-opsin (bO) is folded in a nearly native conformation in mixed micelles of dimyristoyl phosphatidyl choline (DMPC) and 3-[(3-cholamidopropyl)-dimehtylamonio]-1-propane sulfonic acid (CHAPS), but bO is partially unfolded in sodium dodecyl sulfate (SDS). UV difference spectroscopy was used to study the changes in environment of bO aromatic amino acid side chains that occur upon partial unfolding. The UV difference spectra of peptides in CHAPS/DMPC minus peptides in SDS were measured for bO and the following subfragments of bO: C1 (residues 72-248), C2 (1-71), V1 (1-166), V2 (167-248), CB7 (119-145), CB9 (164-209), and CB10 (72-118). The spectra show that, in partially unfolded bO in SDS, the Tyr and Trp absorbance is blue-shifted. The difference spectra were compared to solvent perturbation difference spectra of N-acetyl-L-tyrosine ethyl ester and N-acetyl-L-tryptophanamide. The exposure change calculated from the difference spectra was found to correlate with the change in the number of van der Waals contacting atoms upon partial unfolding, and also with the number of transmembrane helical segments. This result suggests a simple experimental method of testing helix packing arrangements derived from hydropathy plots and model building.

Long-range effects on the retinal chromophore of bacteriorhodopsin caused by surface carboxyl group modification

Carboxyl groups of bacteriorhodopsin (bR) that are modified by 1-ethyl-3-[3-(trimethylamino)-propyl]carbodiimide (ETC) have been identified. Reaction of deionized purple membrane with a 400-fold molar excess of ETC or [14C]ETC for 1 h at 0 degree C incorporates about 3.5 mol of ETC/mol of bR. Proteinase K cleavage of ETC-modified bacterioopsin (bO) produced small 14C-labeled peptides. Amino acid sequence analysis showed three major ETC-modified residues: Glu 234, Asp 38, and Glu 74. Proteolysis of purple membrane with papain removes the ETC site at Glu 234. Treatment of ETC-modified, papain-cleaved purple membrane with hydroxylamine removes half of the remaining ETC label. Subsequent cleavage with chymotrypsin, followed by amino acid sequence analysis, revealed that most of the remaining label was at Glu 74. bR modified by ETC primarily at Glu 74 displays two alterations in the retinal chromophore, located in the membrane interior at a distance more than 2 nm away from the modified carboxyl group. (1) The acid-induced purple-to-blue transition undergoes a shift in apparent pK from 3.2 to 2.3. (2) The second-order rate constant for chromophore regeneration from bO and retinal is diminished from 3600 to 1700 M-1 s-1 in membrane sheets. Most of the shift in the pK of the purple-to-blue transition can be explained by the quaternary ammonium ion of ETC attached to Glu 74 overlapping the postulated location of the guanidinium group of Arg 82.(ABSTRACT TRUNCATED AT 250 WORDS)

Beta IV is the major beta-tubulin isotype in bovine cilia

Four different isotypes of beta-tubulin are known to be expressed in mammalian brain. Monoclonal antibodies against beta II, beta III, and beta IV were used to characterize the beta-tubulin isotypes in two ciliated bovine tissues: non-motile sensory cilia of retinal rod cells and motile cilia of tracheal epithelium. Retinal rod outer segment (ROS) connecting cilia and cytoskeletons were purified by density gradient centrifugation. This preparation contained more than 20 major protein components, as shown by dodecyl sulfate polyacrylamide gel electrophoresis. Electroblots were used to quantitate the relative amounts of beta II, beta III, and beta IV. The connecting cilium and cytoskeleton of the rod outer segment has less type III beta-tubulin than brain and more type IV. The ratio of beta IV to beta II in the ROS is nearly a factor of 8 larger than in brain. Electron microscopic immunocytochemistry showed extensive labeling of cilia by anti-type IV in thin sections of retinas and trachea, and also in purified ROS cilia and cytoskeletons. Labeling of cilia by anti-beta II was also observed, although in the purified ROS cilia and cytoskeleton, the anti-beta II labeling was primarily on amorphous non-ciliary material. The results suggest that both motile and non-motile cilia are enriched in the type IV beta-tubulin subunit.

Regeneration of bacteriorhodopsin in mixed micelles

Regeneration of bacteriorhodopsin from bacterioopsin and all-trans-retinal was studied in a mixed micelle system consisting of dodecyl sulfate, CHAPS and a water-soluble phospholipid dihexanoylphosphatidylcholine (hex2-PhosChol). Regeneration to approximately 40,000 M-1.cm-1 extinction at 550 nm (epsilon 550) was obtained with either 2.3 mM or 6.5 mM CHAPS along with 6.9 mM dodecyl sulfate and 4.5 mM hex2-PhosChol in 0.16 M NaCl and 40 mM phosphate (pH 6.0). Without CHAPS, the regeneration in 4.5 mM Hex2-PhosChol gave epsilon 555 = 27,800; without PhosChol, the 1:3 CHAPS/dodecyl sulfate mixture gave epsilon 550 approximately 20,000; and without PhosChol the nearly equimolar CHAPS/dodecyl sulfate mixture gave epsilon 550 approximately 10,000. The composition of the mixed micelles was estimated from fluorescence spectroscopy using pyrene butyryl hydrazine. The molecular weight was estimated by molecular seive chromatography to be 87,100 for 2.3 mM CHAPS, 6.9 mM dodecyl sulfate and 0.67 mM hex2-PhosChol; and 83,200 for 7.0 mM CHAPS, 6.9 mM dodecyl sulfate, and 1.1 mM hex2-PhosChol. These results are consistent with the idea that at low concentrations of CHAPS and dodecyl sulfate, CHAPS organizes the dodecyl sulfate into disk shaped bilayer micelles that are favorable for bacterioopsin refolding. However, a high concentration of either detergent inhibits regeneration. Added hex2-PhosChol can overcome the inhibitory effects of high concentrations of either CHAPS or dodecyl sulfate.

Control of bacteriorhodopsin color by chloride at low pH. Significance for the proton pump mechanism

The chromophore of bacteriorhodopsin undergoes a transition from purple (570 nm absorbance maximum) to blue (605 nm absorbance maximum) at low pH or when the membrane is deionized. The blue form was stable down to pH 0 in sulfuric acid, while 1 M NaCl at pH 0 completely converted the pigment to a purple form absorbing maximally at 565 Other acids were not as effective as sulfuric in maintaining the blue form, and chloride was the best anion for converting blue membrane to purple membrane at low pH. The apparent dissociation constant for Cl- was 35 mM at pH 0, 0.7 M at pH 1 and 1.5 M at pH 2. The pH dependence of apparent Cl- binding could be modeled by assuming two different types of chromophore-linked Cl- binding site, one pH-dependent. Chemical modification of bacteriorhodopsin carboxyl groups (probably Asp-96, -102 and/or -104) by 1-ethyl-3-dimethlyaminopropyl carbodiimide, Lys-41 by dansyl chloride, or surface arginines by cyclohexanedione had no effect on the conversion of blue to purple membrane at pH 1. Fourier transform infrared difference spectroscopy of chloride purple membrane minus acid blue membrane showed the protonation of a carboxyl group (trough at 1392 cm -1 and peak at 1731 cm -1). The latter peak shifted to 1723 cm -1 in D2O. Ultraviolet difference spectroscopy of chloride purple membrane minus acid blue membrane showed ionization of a phenolic group (peak at 243 nm and evidence for a 295 nm peak superimposed on a tryptophan perturbation trough). This suggests the possibility of chloride-induced proton transfer from a tyrosine phenolic group to a carboxylate side-chain. We propose a mechanism for the purple to acid blue to chloride purple transition based on these results and the proton pump model of Braiman et al. (Biochemistry 27 (1988) 8516-8520).

Altered protein-chromophore interaction in dicyclohexylcarbodiimide-modified purple membrane sheets

Previous studies of N,N'-dicyclohexylcarbodiimide (DCCD)-modified bacteriorhodopsin (Renthal, R. et al. (1985) Biochemistry 24, 4275-4279) used reaction conditions (detergent micelles) that are not optimal for subsequent physical studies. The present work describes new conditions for reaction of bacteriorhodopsin with DCCD in intact purple membrane sheets in the presence of 4.5% (v/v) diethylether and light. Like the detergent reaction system, the reaction is light induced, incorporates approximately 1 mol [14C]DCCD per mol bacteriorhodospin, and results in a bleached chromophore. Peptide mapping indicates that the likely site of modification in intact membranes is identical to the site in the detergent reaction system: Asp 115. The retinal chromophore of DCCD-modified purple membrane has an absorbance maximum at 390 nm and very little induced circular dichroism. The retinal is easily extracted in hexane, yielding a 3:1 ratio of all-trans to 13-cis retinal. Borohydride reduces the retinal onto the protein within the 1-71 region of the amino acid sequence. These results suggest that Asp-115 is near the retinal binding cavity of bacteriorhodopsin. When DCCD reacts with Asp 115, retinal is displaced from its binding site.

Fluorescent labeling of bacteriorhodopsin: implications for helix connections

Purple membrane from Halobacterium halobium was reacted with dansyl (5-dimethylamino-1-naphthalenyl fluorescent labels that have specificity for different protein side chains of bacteriorhodopsin. Dansyl chloride was found to react primarily with Lys-41. Dansyl hydrazine was coupled, with water-soluble carbodiimide, to Glu-74 and/or Asp-85, which was the major modified site after papain-cleavage of the carboxyl-terminal 17 amino acids. Fluorescence energy transfer was used to probe the proximity of the modified sites to the retinal chromophore of bacteriorhodopsin. The dansyl group on Lys-41 was greater than 2.99 nm from retinal, while the dansyl group on Glu-74/Asp-85 was greater than 2.10 nm from retinal. Information available on the location of retinal in the transmembrane profile and probable surface locations of the fluorescent labels was combined with the energy transfer results to calculate distances projected in the plane of the membrane. The projected distances to retinal were 1.64 nm (Lys-41) and 1.65 nm (Gly-74). These measurements, combined with many other labeling experiments that have been reported, restrict the number of likely helix-connection models to only three: EDCABGF, FEDCBAG and FGEABDC (in the nomenclature of Engelman et al. (1980) Proc. Natl. Acad. Sci. USA 77, 2023-2027).

Light activates the reaction of bacteriorhodopsin aspartic acid-115 with dicyclohexylcarbodiimide

Conditions for a light-induced reaction between the carboxyl-modifying reagent N,N'-dicyclohexylcarbodiimide (DCCD) and bacteriorhodopsin in Triton X-100 micelles were previously reported [Renthal, R., Dawson, N., & Villarreal, L. (1981) Biochem. Biophys. Res. Commun. 101, 653-657]. We have now located the DCCD site in the bacteriorhodopsin amino acid sequence. [14C]DCCD-bacteriorhodopsin (0.67 mol/mol of bacteriorhodopsin) was cleaved with CNBr. The resulting peptides were purified by gel filtration and reverse-phase high-performance liquid chromatography (HPLC). One major 14C peptide (50%) and two minor fractions were obtained. The modified peptides were completely absent in the absence of DCCD, and 10 times less was obtained when the reaction was run in the dark. Amino acid analysis and sequence analysis showed that the major fraction contained residues 69-118. This region includes six carboxyl side chains. Quantitative sequence analysis ruled out significant amounts of DCCD at Glu-74, Asp-85, Asp-96, Asp-102, and Asp-104. The major 14C peptide was also subjected to pepsin hydrolysis. HPLC analysis of the product gave only a single major radioactive subfragment. Amino acid analysis of the peptic peptide showed that it contained residues 110-118. The only carboxyl side chain in this region is Asp-115. Thus, we conclude that Asp-115 is the major DCCD site. The light sensitivity of this reaction suggests that Asp-115 becomes more exposed or that its environment becomes more acidic during proton pumping. The DCCD reaction blue-shifts the retinal chromophore. Such a result would be expected if Asp-115 is the negative point charge predicted to be near the cyclohexene ring of retinal.

Difference between inactive renins in amniotic fluid and in control or pregnancy plasma

Phenylethylamine-agarose column chromatography has been used to compare inactive renins in amniotic fluid, in control plasma during estrogen treatment and in maternal plasma during normal pregnancy. Inactive renin in all three was retained by the column and separated from renin substrate. Inactive renin in control and maternal plasma desorbed similarly and was different than that in amniotic fluid. The results suggest that during normal pregnancy the elevated concentrations of inactive renin in maternal plasma are more likely of renal than placental origin.

Charge asymmetry of the purple membrane measured by uranyl quenching of dansyl fluorescence

Purple membrane was covalently labeled with 5-(dimethylamino) naphthalene-1-sulfonyl hydrazine (dansyl hydrazine) by carbodiimide coupling to the cytoplasmic surface (carboxyl-terminal tail: 0.7 mol/mol bacteriorhodopsin) or by periodate oxidation and dimethylaminoborane reduction at the extracellular surface (glycolipids: 1 mol/mol). In 2 mM acetate buffer, pH 5.6, micromolar concentrations of UO2 +(2) were found to quench the dansyl groups on the cytoplasmic surface (maximum = 26%), while little quenching was observed at the extracellular surface (maximum = 4%). Uranyl ion quenched dansyl hydrazine in free solution at much higher concentrations. Uranyl also bound tightly to unmodified purple membrane, (apparent dissociation constant = 0.8 microM) as measured by a centrifugation assay. The maximum stoichiometry was 10 mol/mol of bacteriorhodopsin, which is close to the amount of phospholipid phosphorus in purple membrane. The results were analyzed on the assumptions that UO2 +(2) binds in a 1:1 complex with phospholipid phosphate and that the dansyl distribution and quenching mechanisms are the same at both surfaces. This indicates a 9:1 ratio of phosphate between the cytoplasmic and extracellular surfaces. Thus, the surface change density of the cytoplasmic side of the membrane is more negative than -0.010 charges/A2.

A cleavable cross-linking reaction for protein carboxyl groups

L-(+)-tartaric acid dihydrazide was coupled to the purple membrane from Halobacterium halobium with a water soluble carbodiimide. Gel electrophoresis analysis of the product revealed the formation of bacteriorhodopsin dimers, trimers and higher polymers. Most of the cross-links were removed by treatment with papain, demonstrating involvement of the carboxyl-rich carboxyl-terminal region of bacteriorhodopsin in the reaction. The cross-links were cleavable by periodate oxidation.