Bacteriorhodospin: a trans-membrane pump containing alpha-helix.

The probable arrangement of the bacteriorhodopsin molecules in the purple membrane of Halobacterium halobium is in clusters of three, with a 3-fold axis at the centre of each cluster; the axis is at right angles to the plane of the membrane. The proposed arrangement and the results of model calculations together indicate that each protein molecule spans the entire thickness of the membrane. An earlier proposal for the structure had the protein molecules in two layers, and it was symmetric in projection onto the profile-axis. This model is now rejected since it would be difficult to account for the recently discovered function of pumping protons. There remains a discrepancy in that the calculated number of protein molecules in the unit-cell is 3.4 compared to the three expected.The X-ray diffraction patterns from dispersions of the lipids extracted from the red and purple membranes of H. halobium are described.Model calculations are reported, which are based on the bilayer profile calculated for the extracted lipids and on two simple profiles for the protein. The calculations favour a structure for the purple membrane having the lipid molecules in two layers, as in a bilayer, although there may be more of the lipid on one side of the membrane than on the other. Assuming bilayer structure, the diffraction nearest the centre of the oriented pattern suggests that the lipid molecules may be located mainly in a few discrete regions, roughly 20 Å across, between the protein molecules. An uninterrupted monolayer of the lipid on one surface of a sheet of the protein molecules gives poor agreement with the observed profile-diffraction.The X-ray diffraction pattern from the oriented membranes suggested α-helix in the bacteriorhodopsin, and this has been confirmed by recording a 1.5 Å-reflection oriented on the profile-axis. There appear to be at least two segments of α-helix, which are somewhat inclined to one another, and the two may be packed together. Prominent diffraction on the in-plane axis near 10 Å is consistent with the segments lying more or less perpendicular to the plane of the membrane.     

Topography of surface-exposed amino acids in the membrane protein bacteriorhodopsin determined by proteolysis and micro-sequencing

The topography of membrane-surface-exposed amino acids in the light-driven proton pump bacteriorhodopsin (BR) was studied. By limited proteolysis of purple membrane with papain or proteinase K, domains were cleaved, separated by SDS-PAGE, and electroblotted onto polyvinylidene difluoride (PVDF) membranes. Fragments transferred were sequenced in a gas-phase sequencer. Papain cleavage sites at Gly-65, Gly-72, and Gly-231, previously only deduced from the apparent molecular weight of the digestion fragments, could be confirmed by N-terminal micro-sequencing. By proteinase K, cleavage occurred at Gln-3, Phe-71, Gly-72, Tyr-131, Tyr-133, and Ser-226, i.e., in regions previously suggested to be surface-exposed. Additionally, proteinase-K cleavage sites at Thr-121 and Leu-127 were identified, which are sites predicted to be in the alpha-helical membrane-spanning segment D. Our results, especially that the amino acids Gly-122 to Tyr-133 are protruding into the aqueous environment, place new constraints on the amino-acid folding of BR across the purple membrane. The validity of theoretical prediction methods of the secondary structure and polypeptide folding for membrane proteins is challenged. The results on BR show that micro-sequencing of peptides separated by SDS-PAGE and blotted to PVDF can be successfully applied to the study of membrane proteins.     

Structure and orientation of halorhodopsin in the membrane: a proteolytic fragmentation study.

Halorhodopsin (HR), the light-driven chloride pump in halobacteria, was digested with various proteolytic enzymes. As expected, carboxypeptidase A removed 14 amino acids from the C-terminal tail of detergent-solubilized HR, producing a fragment of 25.2 kd in size. Membrane-associated HR could be digested as well, but not in right-side-out sealed cell envelope vesicles. We conclude, therefore, that the orientation of HR in the cytoplasmic membrane is such that the C-terminal tail faces the cytoplasmic side. Tryptic digestion of detergent-solubilized HR resulted in the removal of the same C-terminal segment, but also in the production of two more cleavage products (molecular masses of 20.9 and 16.8 kd respectively). These cleavage sites were determined by amino acid sequencing of the newly produced N termini, and they turned out to be within interhelical loops in an earlier proposed structural model for HR. Incubation with chymotrypsin and thermolysin yielded different sites of cleavage, but also in regions which were proposed to be accessible on the surface of the protein. Since the results show that three of six proposed interhelical loop segments contain proteolytic digestion sites, they support the proposed structural model for HR.     

Phase transitions of the purple membrane and the brown holo-membrane X-ray diffraction,circular dichroism spectrum and absorption spectrum studies

The phase transition of the purple membrane observed by differential scanning calorimetry (Jackson, M.B. and Sturtevant, J.M. (1978) Biochemistry 17, 911–915) has been investigated by X-ray diffraction, circular dichroism and absorption spectrum, in comparison with the phase transition in the brown holo-membrane. The two-dimensional crystal of bacteriorhodopsin transformed into two-dimensional liquid around 74–78°C in the purple membrane and around 50–60°C in the brown holo-membrane. The X-ray diffraction patterns obtained at 78°C for the purple membrane and at 60°C for the brown holo-membrane exhibit several broad peaks. Analysis of the pattern suggests that bacteriorhodopsin molecules aggregate in trimers even above the phase transition temperature. The negative circular dichroism band in the visible region is still present at 80°C in the purple membrane and at 60°C in the brown holo-membrane, but becomes negligibly small at 70°C in the brown holo-membrane. The 560 nm absorption peak due to bacteriorhodopsin changes its position and height drastically around 80°C in the brown holo-membrane as in the purple membrane. X-ray diffraction studies have been made on membranes of total lipids extracted from the purple membrane. No indication of the phase transition has been found between ?81°C and 77°C.     

Tertiary structure of bacteriorhodopsin. Positions and orientations of helices A and B in the structural map determined by neutron diffraction

Positions and rotations of two helices in the tertiary structure of bacteriorhodopsin have been studied by neutron diffraction using reconstituted, hybrid purple membrane samples. Purple membrane was biosynthetically 2H-labeled at non-exchangeable hydrogen positions of leucine and tryptophan residues. Two chymotryptic fragments were purified, encompassing either the first two or the last five of the seven putative transmembrane segments identified in the amino acid sequence of bacteriorhodopsin. The 2H-labeled fragments, diluted to variable extents with the identical, unlabeled fragment, were mixed with their unlabeled counterpart; bacteriorhodopsin was then renatured and reconstituted. The crystalline purple membrane samples thus obtained contained hybrid bacteriorhodopsin molecules in which certain transmembrane segments had been selectively 2H-labeled to various degrees. Neutron diffraction powder patterns were recorded and analyzed both by calculating difference Fourier maps and by model building. The two analyses yielded consistent results. The first and second transmembrane segments in the sequence correspond to helices 1 and 7 of the three-dimensional structure, respectively. Rotational orientations of these two helices were identified using best fits to the observed diffraction intensities. The data also put restrictions on the position of the third transmembrane segment. These observations are discussed in the context of folding models for bacteriorhodopsin, the environment of the retinal Schiff base, and site-directed mutagenesis experiments.     

Protease digestion of membranes. Ultrastructural and biochemical effects.

(1) Nagarse, a bacterial protease, was permitted to react with sarcoplasmic reticulum, submitochondrial and plasma membranes. Gel electrophoresis indicated that all polypeptides were labile to the enzyme, and therefore must be at least partially exposed at membrane surfaces. However, hydrolysis did not proceed to completion, and in each membrane 30-50% of the original protein mass remained after extensive digestion. Gel patterns showed that remaining polypeptide fragments were in the range of 10000 molecular weight. (2) Amino acid analysis of the original protein and membrane-bound digestion product was performed. Only minor changes were observed following digestion, suggesting that the peptide fragments remaining with the membrane did not have specialized amino acid compositions. (3) freeze-fracture analysis of Nagarse-treated sarcoplasmic and plasma membranes showed that particulate structures were present, although particle density and asymmetry of fistribution between fracture faces were decreased. In submitochondrial membranes, digested membranes were indistinguishable from the original membranes in particle density and distribution. We conclude that high molecular weight polypeptides are not required for the production particulate structures in freeze-fracture images of membranes.     

Carboxypeptidase Y digestion of band 3, the anion transport protein of human erythrocyte membranes

The exposure of the carboxyl-terminal of the Band 3 protein of human erythrocyte membranes in intact cells and membrane preparations to proteolytic digestion was determined. Carboxypeptidase Y digestion of purified Band 3 in the presence of non-ionic detergent released amino acids from the carboxyl-terminal of Band 3. The release of amino acids was very pH dependent, digestion being most extensive at pH 3, with limited digestion at pH 6 or above. The 55,000 dalton carboxyl-terminal fragment of Band 3, generated by mild trypsin digestion of ghost membranes, had the same carboxyl-terminal sequence as intact Band 3, based on carboxypeptidase Y digestion. Treatment of intact cells with trypsin or carboxypeptidase Y did not release any amino acids from the carboxyl-terminal of Band 3. In contrast, carboxypeptidase Y readily digested the carboxyl-terminal of Band 3 in ghosts that were stripped of extrinsic membrane proteins by alkali or high salt. This was shown by a decrease in the molecular weight of a carboxyl-terminal fragment of Band 3 after carboxypeptidase Y digestion of stripped ghost membranes. No such decrease was observed after carboxypeptidase Y treatment of intact cells. In addition, Band 3 purified from carboxypeptidase Y-treated stripped ghost membranes had a different carboxyl-terminal sequence from intact Band 3. Cleavage of the carboxyl-terminal of Band 3 was also observed when non-stripped ghosts or inside-out vesicles were treated with carboxypeptidase Y. However, the digestion was less extensive. These results suggest that the carboxyl-terminal of Band 3 may be protected from digestion by its association with extrinsic membrane proteins. We conclude, therefore, that the carboxyl-terminal of Band 3 is located on the cytoplasmic side of the red cell membrane. Since the amino-terminal of Band 3 is also located on the cytoplasmic side of the erythrocyte membrane, the Band 3 polypeptide crosses the membrane an even number of times. A model for the folding of Band 3 in the erythrocyte membrane is presented.     

Assignment of segments of the bacteriorhodopsin sequence to positions in the structural map.

Specific amino acid sequence segments have been assigned to locations in the structural map of bacteriorhodopsin using two-dimensional neutron diffraction data and a model building analysis. Models are constructed computationally by building specific regions of the amino acid sequence as alpha helices and then positioning the helices on axes indicated by the density map of Henderson and Unwin (Nature [Lond.]. 1975, 257:28-32). Neutron diffraction data were collected from samples of stacked, oriented "native" purple membranes as well as purple membranes containing different kinds of deuterated amino acids. Models differing in the assignments of helices to specific axes and in rotations of the helices about those axes were tested against the neutron data using a weighted residual factor to rank the models. This residual factor was calculated between observed and predicted intensity differences for pairs of data sets. Using this approach, a small set of related models has been found that predicts the observed intensity changes between five independent data sets. These models are inconsistent with the proposed locations of the retinal chromophore and the carboxyl terminus and with any of the previously proposed models for bacteriorhodopsin.     

Topology of mannosidase II in rat liver Golgi membranes and release of the catalytic domain by selective proteolysis

The orientation of mannosidase II, an integral Golgi membrane protein involved in asparagine-linked oligosaccharide processing, has been examined in rat liver Golgi membranes. Previous studies on mannosidase II purified from Golgi membranes revealed an intact subunit of 124,000 daltons, as well as a catalytically active 110,000-dalton degradation product generated during purification (Moremen, K. W., and Touster, O. (1985) J. Biol. Chem. 260, 6654-6662). In Triton X-100 extracts of Golgi membranes, the intact enzyme was cleaved by a variety of proteases to generate degradation products similar to those observed previously. At appropriate concentrations, chymotrypsin, pronase, and proteinase K generated 110,000-dalton species, while trypsin and Staphylococcus aureus V8 protease generated 115,000-dalton forms. Cleavage by chymotrypsin under mild conditions (10 micrograms/ml, 10 min, 20 degrees C) resulted in a complete conversion to a catalytically active 110,000-dalton form of the enzyme which was extremely resistant to further degradation. Attempts to demonstrate these protease digestions in nonpermeabilized Golgi membranes were unsuccessful, a result suggesting that the protease-sensitive regions are not accessible on the external surface of the membrane. In Golgi membranes permeabilized by treatment with 0.5% saponin, mannosidase II could readily be cleaved to the 110,000-dalton form by digestion with chymotrypsin under conditions similar to those which result in a proteolytic inactivation of galactosyltransferase, a lumenal Golgi membrane marker. Although mannosidase II catalytic activity was not diminished by this chymotrypsin digestion, as much as 90% of the enzyme activity was converted to a nonsedimentable form. To examine the effect of the proteolytic cleavage on the partition behavior of the enzyme, control and chymotrypsin-treated Triton X-114 extracts of Golgi membranes were examined by phase separation at 35 degrees C. The undigested enzyme partitioned into the detergent phase consistent with its location as an integral Golgi membrane protein, while the 110,000-dalton chymotrypsin-digested enzyme partitioned almost exclusively into the aqueous phase in a manner characteristic of a soluble protein. These results suggest that mannosidase II catalytic activity resides in a proteolytically resistant, hydrophilic 110,000-dalton domain. Attachment of this catalytic domain to the lumenal face of Golgi membranes is achieved by a proteolytically sensitive linkage to a 14,000-dalton hydrophobic membrane anchoring domain.     

Access of proteinase K to partially translocated nascent polypeptides in intact and detergent-solubilized membranes

We have used proteinase K as a probe to detect cytoplasmically and luminally exposed segments of nascent polypeptides undergoing transport across mammalian microsomal membranes. A series of translocation intermediates consisting of discrete-sized nascent chains was prepared by including microsomal membranes in cell-free translations of mRNAs lacking termination codons. The truncated mRNAs were derived from preprolactin and the G protein of vesicular stomatitis virus and encoded nascent chains ranging between 64 and 200 amino acid residues long. Partially translocated nascent chains of 100 amino acid residues or less were insensitive to protease digestion from the external surface of the membrane while longer nascent chains were susceptible to digestion by externally added protease. We conclude that the increased protease sensitivity of larger nascent chains is due to the exposure of a segment of the nascent polypeptide on the cytoplasmic face of the membrane. In contrast, low molecular weight nascent chains were remarkably resistant to protease digestion even after detergent solubilization of the membrane. The protease resistant behaviour of detergent solubilized nascent chains could be abolished by release of the polypeptide from the ribosome or by the addition of protein denaturants. We propose that the protease resistance of partially translocated nascent chains can be ascribed to components of the translocation apparatus that remain bound to the nascent chain after detergent solubilization of the membrane.     

Proteolysis and flash photolysis of bacteriorhodopsin in purple membrane fragments

Pronase treatment of aqueous suspensions of purple membrane fragments from H. halobium leads to the cleavage of bacteriorhodopsin. The protein fragments remaining in the membrane after treatment with relatively small concentrations of enzyme (2% w/w) in normal daylight range in molecular weight from 20,000-21,000 daltons, indicating that cleavage occurs mainly near the extremities of the protein chain. At higher enzyme concentrations the relative amounts of protein fragments having smaller molecular weight increase. Generally, the relative loss of retinal chromophore is larger than that of protein and thus the retinal binding site seems to be located near one of the chain ends that is cleaved off by enzyme.Irradiation with white light during the time of proteolysis (at both low and high enzyme concentrations) results in extensive cleavage, so that under certain conditions no high molecular weight components can be detected in SDS-polyacrylamide gels. It, therefore, appears that parts of the bacteriorhodopsin chain become more exposed to enzyme digestion when the purple membrane is illuminated.Enzyme treated aqueous purple membrane fragment suspensions still show photocycle activity. The main consequence of proteolysis is a pronounced appearance of biphasicity in the decay of M₄₁₂ and the regeneration of bR₅₇₀. Simultaneously the yield of O₆₆₀ is reduced. As with untreated purple membrane, the correlation between the rates of decay of M₄₁₂ and regeneration of bR₅₇₀ is greatest when the yield of O₆₆₀ is lowest.     

Glycocardiolipin modulates the surface interaction of the proton pumped by bacteriorhodopsin in purple membrane preparations

Glycocardiolipin is an archaeal analogue of mitochondrial cardiolipin, having an extraordinary affinity for bacteriorhodopsin, the photoactivated proton pump in the purple membrane of Halobacterium salinarum. Here purple membranes have been isolated by osmotic shock from either cells or envelopes of Hbt. salinarum. We show that purple membranes isolated from envelopes have a lower content of glycocardiolipin than standard purple membranes isolated from cells. The properties of bacteriorhodopsin in the two different purple membrane preparations are compared; although some differences in the absorption spectrum and the kinetic of the dark adaptation process are present, the reduction of native membrane glycocardiolipin content does not significantly affect the photocycle (M-intermediate rise and decay) as well as proton pumping of bacteriorhodopsin. However, interaction of the pumped proton with the membrane surface and its equilibration with the aqueous bulk phase are altered.     

Glycocardiolipin modulates the surface interaction of the proton pumped by bacteriorhodopsin in purple membrane preparations

Glycocardiolipin is an archaeal analogue of mitochondrial cardiolipin, having an extraordinary affinity for bacteriorhodopsin, the photoactivated proton pump in the purple membrane of Halobacterium salinarum. Here purple membranes have been isolated by osmotic shock from either cells or envelopes of Hbt. salinarum. We show that purple membranes isolated from envelopes have a lower content of glycocardiolipin than standard purple membranes isolated from cells. The properties of bacteriorhodopsin in the two different purple membrane preparations are compared; although some differences in the absorption spectrum and the kinetic of the dark adaptation process are present, the reduction of native membrane glycocardiolipin content does not significantly affect the photocycle (M-intermediate rise and decay) as well as proton pumping of bacteriorhodopsin. However, interaction of the pumped proton with the membrane surface and its equilibration with the aqueous bulk phase are altered.     

Effect of the removal of the COOH-terminal region of bacteriorhodopsin on its light-induced H+ changes.

Removal of the COOH-terminal region of bacteriorhodopsin by digestion with trypsin or papain reduces the yield of light-induced H+ release by 50-70%. The rate of H+ release is not affected significantly, but the half time of H+ uptake increases almost twofold. However, there is no effect on the photocycle of bacteriorhodopsin as judged by the yield and decay kinetics of the M412 photointermediate. The H+:M ratio in enzyme-digested membranes is approximately 0.4-0.8, whereas untreated membranes have a H+:M ratio of approximately 2. Purple membrane sheets stored in distilled water at 4 degrees C for prolonged periods also have a low H+:M ratio, probably due to protease activity associated with bacterial contamination. Electrophoresis on sodium dodecylsulfate-polyacrylamide gels showed that both the enzyme-treated and the stored purple membrane samples have a higher electrophoretic mobility compared to the fresh preparation. The reduction in molecular weight can be accounted for by the loss of several residues from the COOH-terminal portion of the bacteriorhodopsin. We propose that the COOH-terminal region is partially responsible for the high yield of H+ release by the purple membrane.     

Comparison of the subunit organization of early and late replicating chromatin

A comparison was made of the subunit organization of chromatin from regions of the genome with different metaphase chromosome banding characteristics by analyzing the accessibility of early and late replicating DNA in synchronized Chinese hamster ovary cells to digestion with staphylococcal nuclease. Three measures of nuclease susceptibility were employed: (1) the release of acid-soluble material; (2) a digestion index, P, which corresponds to the proportion of internucleosome segments which experienced at least one cleavage event; and (3) the size distribution of DNA fragments isolated from digested chromatin. Little or no difference was observed in the initial rates with which nuclease converted early and late replicating chromatin to acid-soluble material, although the initial digestion rates varied with time of cell collection in the cycle (metaphase > G1 mid-S > late-S or G2). Measurements of the digestion indices of material isolated from interphase cells suggested that initial cleavage events were more rapid in early replicating chromatin than in late replicating chromatin. In contrast, electrophoretic analysis revealed that oligomer DNA fragments from early labelled metaphase chromatin were slightly larger than corresponding fragments from late labelled metaphase chromatin. The size distribution of DNA in submonomer fragments obtained from extensively digested chromatin appeared to be identical regardless of the timing of replication or cell collection. Those small differences in chromatin digestibility that were observed may reflect subtle variations in the accessibility of internucleosome regions or perhaps in the higher-order arrangement of nucleosomes. However, no gross variation in accessibility to staphylococcal nuclease digestion was observed in chromatin localized to metaphase chromosome regions with vastly different cytological staining properties.     

Lecithin:cholesterol acyltransferase. Functional regions and a structural model of the enzyme

The amino acid sequence of human lecithin:cholesterol acyltransferase has been determined by degradation and alignment of peptides obtained from tryptic and staphylococcal digestions and the cleavage with cyanogen bromide and consisted of 416 amino acid residues. All of the tryptic peptides of lecithin:cholesterol acyltransferase were isolated and sequenced. Peptides resulting from digestion by staphylococcal protease, cyanogen bromide cleavage, or the combination of the two methods were employed to find overlapping segments. The N terminus of human lecithin:cholesterol acyltransferase was determined to be phenylalanine by sequencing the whole protein up to 40 residues while the C terminus was identified as glutamic acid through carboxypeptidase Y cleavage. Cys50 and Cys74 and Cys313 and Cys356 were identified as the two disulfide bridges while the free sulfhydryl groups were located at positions 31 and 184. The N-glycosylated sites of the protein were assigned to asparagines at positions 20, 84, 272, and 384. The active site of lecithin:cholesterol acyltransferase was identified as serine on position 181 according to its homology with other serine-type esterases which have a common structure of glycine-variable amino acid-active serine-variable amino acid-glycine (Gly-X-Ser-X-Gly) with the variable amino acids disrupting the homology. No long internal repeats or homologies with apolipoproteins were found. The secondary structure is consistent with the results of predictive algorithms. A simple model of the enzyme is proposed on the basis of available chemical data and predictive methods.     

Retinal location in purple membrane of Halobacterium halobium: a neutron diffraction study of membranes labelled in vivo with deuterated retinal

Purple membranes were prepared by growing Halobacterium halobium in a medium containing nicotine (which inhibits biosynthesis of retinal) and the oxidation products of fully deuterated beta-carotene. This allowed the in vivo incorporation of deuterated retinal into the membranes. The labelled membranes were crystalline and isomorphous with native membrane as determined by X-ray diffraction, and their optical absorption spectra were very similar. Neutron diffraction data for the two dimensional in-plane lattice from labelled and native membranes were analysed by difference Fourier and direct methods to 8.6 A resolution. The difference Fourier shows the retinal to be located in the centre of the bacteriorhodopsin molecule. The best fit to the data was obtained with the projection of retinal as a 10 A long rod forming an angle of -40 degrees +/- 10 degrees with the x axis centred at x = -0.19 +/- 0.02, y = -0.35 +/- 0.02 in fractional unit cell coordinates. The main peak in the difference Fourier map is at x = -0.17, y = -0.33.     

Electron diffraction analysis of structural changes in the photocycle of bacteriorhodopsin.

Structural changes are central to the mechanism of light-driven proton transport by bacteriorhodopsin, a seven-helix membrane protein. The main intermediate formed upon light absorption is M, which occurs between the proton release and uptake steps of the photocycle. To investigate the structure of the M intermediate, we have carried out electron diffraction studies with two-dimensional crystals of wild-type bacteriorhodopsin and the Asp96-->Gly mutant. The M intermediate was trapped by rapidly freezing the crystals in liquid ethane following illumination with a xenon flash lamp at 5 and 25 degrees C. Here, we present 3.5 A resolution Fourier projection maps of the differences between the M intermediate and the ground state of bacteriorhodopsin. The most prominent structural changes are observed in the vicinity of helices F and G and are localized to the cytoplasmic half of the membrane.