Total synthesis of a gene.

The method developed for the total synthesis of a given DNA containing biologically specific sequences consists of the following. The DNA in the double-stranded form is carefully divided into short single-stranded segments with suitable overlaps in the complementary strands. All the segments are chemically synthesized starting with protected nucleosides and mononucleotides. The 5'-OH ends of the appropriate oligonucleotides are then phosphorylated with the use of [y-32P]ATP and polynucleotide kinase. A few to several neighboring oligonucleotides are then allowed to form bihelical complexes in aqueous solution, and the latter are joined end to end by polynucleotide ligase to form covalently linked duplexes. Subsequent heat-to-tail joining of the short duplexes leads to the total DNA. The methods are described for the construction of a biologically functional suppressor transfer RNA gene. The total work involved (i) the synthesis of a 126-nucleotide-long bihelical DNA corresponding to a known precursor to the tyrosine suppressor transfer RNA, (ii) the sequencing of the promoter region and the distal region adjoining the C-C-A end, which contained a signal for the processing of the RNA transcript, (iii) total synthesis of the 207 base-pair-long DNA, which included the control elements, as well as the Eco R1 restriction endonuclease specific sequences at the two ends, and (iv) full characterization by transcription in vitro and amber suppressor activity in vivo of the synthetic gene.

Transmembrane protein structure: spin labeling of bacteriorhodopsin mutants.

Transmembrane proteins serve important biological functions, yet precise information on their secondary and tertiary structure is very limited. The boundaries and structures of membrane-embedded domains in integral membrane proteins can be determined by a method based on a combination of site-specific mutagenesis and nitroxide spin labeling. The application to one polypeptide segment in bacteriorhodopsin, a transmembrane chromoprotein that functions as a light-driven proton pump is described. Single cysteine residues were introduced at 18 consecutive positions (residues 125 to 142). Each mutant was reacted with a specific spin label and reconstituted into vesicles that were shown to be functional. The relative collision frequency of each spin label with freely diffusing oxygen and membrane-impermeant chromium oxalate was estimated with power saturation EPR (electron paramagnetic resonance) spectroscopy. The results indicate that residues 129 to 131 form a short water-exposed loop, while residues 132 to 142 are membrane-embedded. The oxygen accessibility for positions 131 to 138 varies with a periodicity of 3.6 residues, thereby providing a striking demonstration of an alpha helix. The orientation of this helical segment with respect to the remainder of the protein was determined.

Requirement of rigid-body motion of transmembrane helices for light activation of rhodopsin.

Conformational changes are thought to underlie the activation of heterotrimeric GTP-binding protein (G protein)-coupled receptors. Such changes in rhodopsin were explored by construction of double cysteine mutants, each containing one cysteine at the cytoplasmic end of helix C and one cysteine at various positions in the cytoplasmic end of helix F. Magnetic dipolar interactions between spin labels attached to these residues revealed their proximity, and changes in their interaction upon rhodopsin light activation suggested a rigid body movement of helices relative to one another. Disulfide cross-linking of the helices prevented activation of transducin, which suggests the importance of this movement for activation of rhodopsin.

Rhodopsin mutants that bind but fail to activate transducin.

Rhodopsin is a member of a family of receptors that contain seven transmembrane helices and are coupled to G proteins. The nature of the interactions between rhodopsin mutants and the G protein, transduction (Gt), was investigated by flash photolysis in order to monitor directly Gt binding and dissociation. Three mutant opsins with alterations in their cytoplasmic loops bound 11-cis-retinal to yield pigments with native rhodopsin absorption spectra, but they failed to stimulate the guanosine triphosphatase activity of Gt. The opsin mutations included reversal of a charged pair conserved in all G protein-coupled receptors at the cytoplasmic border of the third transmembrane helix (mutant CD1), replacement of 13 amino acids in the second cytoplasmic loop (mutant CD2), and deletion of 13 amino acids from the third cytoplasmic loop (mutant EF1). Whereas mutant CD1 failed to bind Gt, mutants CD2 and EF1 showed normal Gt binding but failed to release Gt in the presence of guanosine triphosphate. Therefore, it appears that at least the second and third cytoplasmic loops of rhodopsin are required for activation of bound Gt.

Time-resolved detection of structural changes during the photocycle of spin-labeled bacteriorhodopsin.

Bacteriorhodopsin was selectively spin labeled at residues 72, 101, or 105 after replacement of the native amino acids by cysteine. Only the electron paramagnetic resonance spectrum of the label at 101 was time-dependent during the photocycle. The spectral change rose with the decay of the M intermediate and fell with recovery of the ground state. The transient signal is interpreted as the result of movement in the C-D or E-F interhelical loop, or in both, coincident with protonation changes at the key aspartate 96 residue. These results link the optically characterized intermediates with localized conformational changes in bacteriorhodopsin during the photocycle.

A rapid and efficient procedure for the purification of mitochondrial beta-hydroxybutyrate dehydrogenase.

A new, rapid and efficient procedure for the purification of the mitochondrial enzyme beta-hydroxybutyrate dehydrogenase (EC 1.1.1.30) to homogeneity is described. It involves the following steps. The mitochondria are solubilized with potassium cholate and the 100 000 X g supernate is fractionated with ammonium sulfate. This is followed by precipitation of the enzyme at pH 5.2 and then selective solubilization at pH 8.8. This key step removes eighty percent of the contaminating proteins and allows subsequent DEAE-Sepharose and glass bead column chromatography to be performed in the absence of detergents. The overall yield is consistently around 35% and the purified protein is homogeneous on polyacrylamide gel electrophoresis. The purified enzyme is absolutely dependent upon phosphatidylcholine for activity.

The preparation of lipid-depleted bacteriorhodopsin.

Bacteriorhodopsin, the protein of the purple membrane of Halobacterium halobium, was freed to the extent of 90-95% from the natural membrane lipids without loss of function. The residual lipid corresponded to less than 1 mol/mol of bacteriorhodopsin. Delipidation was achieved by treatment of the purple membrane with a mixture of the detergent dimethyldodecylamine oxide and sodium chloride. The detergent was removed by dialysis or by sucrose density gradient centrifugation. Analysis of the lipids removed and those still bound to bacteriorhodopsin was facilitated by the use of purple membrane preparations labelled with 35S, 32P, or 14C. The composition of the residual lipids associated with bacteriorhodopsin was similar to that of the total lipid in the purple membrane.

Interaction of cholesterol with photoactivable phospholipids in sonicated vesicles.

Photoactivable phospholipids containing either alpha-diazo-beta-trifluoropropionyloxy or m-diazirinophenoxyl groups in the omega-positions of sn-2 fatty acyl chains were synthesized and incorporated into sonicated vesicles containing 33 mol% of cholesterol. Photolysis of the vesicles at 350 nm produced covalent cross-links between the synthetic phospholipids and cholesterol. The cross-linked products obtained using [14C]cholesterol were characterized by their chromatographic behavior, cleavage on phospholipase A2 treatment, base-catalyzed transesterification and mass spectral measurements. The cross-linking was shown not to involve the 3-beta-hydroxyl group of cholesterol, and it was concluded that the reactive carbene intermediates formed from the photolabels inserted into the hydrocarbon skeleton of cholesterol in the bilayer. The extent of cross-linking obtained was comparable to that observed previously using phospholipids alone, indicating that no lateral phase separation occurred. The present approach is promising for further precise studies of the molecular interactions between cholesterol and phospholipids in biological membranes.

Synthesis of phospholipids containing photoactivatable carbene precursors in the headgroups and their crosslinking with membrane proteins.

Many integral membrane enzymes require for their activity interactions with the polar headgroups of phospholipids, in addition to the hydrophobic interactions within the lipid bilayer. The interactions with the polar headgroups may have preferential or absolute specificity. To study such interactions, phospholipids have been synthesized which carry photoactivable moieties in their headgroups. Three types of phospholipids, PL-I, PL-II and PL-III, were synthesized. The synthetic phospholipids, PL-I and PL-II were able to reconstitute enzymatic activity of the membrane proteins which were studied. Covalent crosslinking between these phospholipids and the membrane proteins was demonstrated after photolysis of the reconstituted phospholipid-protein complexes.

Structure and function in bacteriorhodopsin: the role of the interhelical loops in the folding and stability of bacteriorhodopsin.

Bacteriorhodopsin functions as a light-driven proton pump in Halobacterium salinarium. The functional protein consists of an apoprotein, bacterioopsin, with seven transmembrane alpha helices together with a covalently bound all-trans retinal chromophore. In order to study the role of the interhelical loop conformations in the structure and function of bacteriorhodopsin, we have constructed bacterioopsin genes where each loop is replaced, one at a time, by a peptide linker consisting of Gly-Gly-Ser- repeat sequences, which are believed to have flexible conformations. These mutant proteins have been expressed in Escherichia coli, purified and reconstituted with all-trans retinal in l-alpha-1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC)/3-(3-cholamidopropyl)dimethylammonio-1-propane sulfonate (CHAPS)/SDS and l-alpha-1,2-dihexanoylphosphatidylcholine (DHPC)/DMPC/SDS micelles. Wild-type-like chromophore formation was observed in all the mutants containing single loop replacements. In the BC and FG mutants, an additional chromophore band with an absorption band at about 480 nm was observed, which was in equilibrium with the 550 nm, wild-type band. The position of the equilibrium depended on temperature, SDS and relative DMPC concentration. The proton pumping activity of all of the mutants was comparable to that of wild-type bR except for the BC and FG mutants, which had lower activity. All of the loop mutants were more sensitive to denaturation by SDS than the wild-type protein, except the mutant where the DE loop was replaced. These results suggest that a specific conformation of all the loops of bR, except the DE loop, contributes to bR stability and is required for the correct folding and function of the protein. An increase in the relative proportion of DHPC in DHPC/DMPC micelles, which reduces the micelle rigidity and alters the micelle shape, resulted in lower folding yields of all loop mutants except the BC and DE mutants. This effect of micelle rigidity on the bR folding yield correlated with a loss in stability of a partially folded, seven-transmembrane apoprotein intermediate state in SDS/DMPC/CHAPS micelles. The folding yield and stability of the apoprotein intermediate state both decreased for the loop mutants in the order WT approximately BC approximately DE>FG>AB>EF> or =CD, where the EF and CD loop mutants were the least stable.

Structure and function in bacteriorhodopsin: the effect of the interhelical loops on the protein folding kinetics.

The loops connecting the seven transmembrane helices of bacteriorhodopsin have each been replaced in turn by structureless linkers of Gly-Gly-Ser repeat sequences, and the effect on the protein folding kinetics has been determined. An SDS-denatured state of each loop mutant bacterio-opsin was folded in l-alpha-1,2-dihexanoylphosphatidylcholine/l-alpha-1,2-dimyristoylphosphatidylcholine micelles, containing retinal, to give functional bacteriorhodopsin. Stopped-flow mixing was used to initiate the folding reaction, giving a time resolution of milliseconds, and changes in protein fluorescence were used to monitor folding. All loop mutant proteins folded according to the same reaction scheme as wild-type protein. The folding kinetics of the AB, BC and DE loop mutants were the same as wild-type protein, despite the blue-shifted chromophore band of the BC loop mutant bR state. A partially folded apoprotein intermediate state of the AB loop mutant did however appear to decay in the absence of retinal. The most significant effects on the folding kinetics were seen for mutant protein with structureless linkers in place of the CD, EF and FG loops. The rate-limiting apoprotein folding step of the CD loop mutant was about ten times slower than wild-type, whilst that of the EF loop mutant was almost four times slower than wild-type. Wild-type behaviour was observed for the other folding and retinal binding events of the CD and EF loop mutant proteins. These effects of the CD and EF loop mutations on apoprotein folding correlate with the fact that these two loop mutants also have the least stable, partially folded apoprotein intermediate of all the loop mutants, and are the most affected by a decrease in lipid lateral pressure. In contrast, the FG loop mutant exhibited wild-type apoprotein folding, but altered covalent binding of retinal and final folding to bacteriorhodopsin. This correlates with the fact that the FG loop mutant bacteriorhodopsin is the most susceptible to denaturation by SDS of all the loop mutants, but its partially folded apoprotein intermediate is more stable than that of the CD and EF mutants. Thus the CD and EF loops may contribute to the transition state for the rate-limiting apoprotein folding step and the FG loop to that for final folding and covalent binding of retinal.

Signal sequence of human preproparathyroid hormone is inactive in yeast.

The biosynthesis of human preproparathyroid hormone (hpreproPTH) and the processing to mature parathyroid hormone (hPTH) was investigated in yeast. Cells were transformed with a plasmid that carried a fusion gene made of the yeast pyruvate kinase promoter, complementary DNA (cDNA) encoding a slightly modified form of hpreproPTH and the transcription termination signal from yeast triosephosphate-isomerase. In transformed yeast cells we identified a protein that was recognized by a PTH antiserum and, on gel electrophoresis, comigrated with hpreproPTH marker. The amino-terminal sequence of the protein was consistent with that of hpreproPTH, indicating that the hormone precursor is not processed. It was localized inside the cell, when analyzed in pulse-chase experiments by trypsin accessibility in intact and lysed spheroplasts. In contrast, when mRNA from these yeast cells and from human parathyroid tissue was translated into preproPTH in a reticulocyte lysate supplemented with canine pancreatic microsomes, the preproPTHs from both mRNAs were transported and cleaved with identical efficiencies. We conclude that hpreproPTH is synthesized in yeast but not recognized and processed like a precursor of a secreted protein by the yeast secretory apparatus.

Time-resolved surface charge change on the cytoplasmic side of bacteriorhodopsin.

The pH-sensitive dye 5-iodoacetamidofluorescein was covalently bound to a single cysteine residue introduced by site-directed mutagenesis in position 101 on the cytoplasmic surface or in position 130 on the extracellular surface of the proton pump bacteriorhodopsin. Using time-resolved absorption spectroscopy at 495 nm a transient increase was observed in the apparent pK of the dye attached at residue 101. At pH 7.3 the rise and decay times of this pK-change (approximately 2 ms and approximately 60 ms) correlate well with decay times observed for the M and O intermediates and with the proton uptake time. Interpreting the pK-increase of +0.18 pH-unit in terms of a transiently more negative surface charge density, we calculate a change of -0.80 elementary charge per bacteriorhodopsin at the cytoplasmic surface. It is likely that this charge change is due to the transient deprotonation of aspartate-96. With the label in position 130 on the extracellular surface no transient pK-shift was detected.

Conserved amino acids in F-helix of bacteriorhodopsin form part of a retinal binding pocket.

A 3-dimensional model for the retinal binding pocket in the light-driven proton pump, bacteriorhodopsin, is proposed on the basis of spectroscopic studies of bacteriorhodopsin mutants. In this model Trp-182, Pro-186 and Trp-189 surround the polyene chain while Tyr-185 is positioned close to the retinylidene Schiff base. This model is supported by sequence homologies in the F-helices of bacteriorhodopsin and the related retinal proteins, halorhodopsin and rhodopsins.

Sensitivity of the retinal circular dichroism of bacteriorhodopsin to the mutagenetic single substitution of amino acids: tyrosine.

Bacteriorhodopsin (bR) in the native purple membrane, in wild type expressed in E. coli and reconstituted in lipid vesicles, and its constituted mutants with substitutions of Tyr-185 by Phe all are found to have different visible retinal CD spectra. The results strongly suggest that the environment of the retinal in bR determines the sign and heterogeneity of its visible retinal CD spectrum. This supports the recent proposal that the observed biphasic CD spectrum of bR is due to the superposition of the CD spectra having opposite signs of more than one type of bR rather than due to exciton coupling.

Phospholipids containing photoactivable groups in studies of biological membranes.

Photoactivable carbene precursors, aryl diazirines and trifluorodiazopropionates, were incorporated synthetically into the omega-positions of fatty acids, which were used to synthesize phospholipids. Extensive intermolecular C--H insertion reactions were demonstrated by photolysis of liposomes prepared from the above phospholipids. Structural analysis of the cross-linked products showed that the predominant sites of cross-linking were in the expected positions within the bilayer. Studies on the topography of a number of membrane proteins using the above phospholipids were initiated. Cross-linking of the photoactivable phospholipids to membrane-embedded proteins, glycophorin A, cytochrome b5, and gramicidin A, was demonstrated.

Site directed spin labeling studies of structure and dynamics in bacteriorhodopsin.

Site-directed spin labeling of membrane proteins has been used to determine: (1) the topography of the polypeptide chain with respect to the membrane/solution interface, and (2) the identity and orientation of secondary structure in selected regions. These features are deduced from the collision rates of nitroxide side chains with paramagnetic reagents in solution, and the principles of the method are reviewed with reference to bacteriorhodopsin. The dynamics of the nitroxide side chains relative to the backbone reveal tertiary interactions of the labeled site, and provide a promising means of time-resolving conformational changes. This aspect is illustrated by recent studies of structural changes in bacteriorhodopsin during the photocycle. In these experiments, nitroxide side chains were introduced at residues 72, 101 and 105 after replacement of the original residues by cysteine. Upon flash photolysis, the electron paramagnetic resonance spectrum of a nitroxide at 101, but not those at 72 or 105, is time-dependent. The spectral change develops during the decay of the M-intermediate, and reverses upon return to the ground state. The results suggest a movement of the C-D or E-F interhelical loops during the protonation changes of aspartate 96.

Time-resolved Fourier transform infrared spectroscopy of the bacteriorhodopsin mutant Tyr-185-->Phe: Asp-96 reprotonates during O formation; Asp-85 and Asp-212 deprotonate during O decay.

The protonation state of key aspartic acid residues in the O intermediate of bacteriorhodopsin (bR) has been investigated by time-resolved Fourier transform infrared (FTIR) difference spectroscopy and site-directed mutagenesis. In an earlier study (Bousché et al., J. Biol Chem. 266, 11063-11067, 1991) we found that Asp-96 undergoes a deprotonation during the M-->N transition, confirming its role as a proton donor in the reprotonation pathway leading from the cytoplasm to the Schiff base. In addition, both Asp-85 and Asp-212, which protonate upon formation of the M intermediate, remain protonated in the N intermediate. In this study, we have utilized the mutant Tyr-185-->Phe (Y185F), which at high pH and salt concentrations exhibits a photocycle similar to wild type bR but has a much slower decay of the O intermediate. Y185F was expressed in native Halobacterium halobium and isolated as intact purple membrane fragments. Time-resolved FTIR difference spectra and visible difference spectra of this mutant were measured from hydrated multilayer films. A normal N intermediate in the photocycle of Y185F was identified on the basis of characteristic chromophore and protein vibrational bands. As N decays, bands characteristic of the all-trans O chromophore appear in the time-resolved FTIR difference spectra in the same time range as the appearance of a red-shifted photocycle intermediate absorbing near 640 nm. Based on our previous assignment of the carboxyl stretch bands to the four membrane embedded Asp groups: Asp-85, Asp-96, Asp-115 and Asp-212, we conclude that during O formation: (i) Asp-96 undergoes reprotonation. (ii) Asp-85 may undergo a small change in environment but remains protonated. (iii) Asp-212 remains partially protonated. In addition, reisomerization of the chromophore during the N-->O transition is accompanied by a major reversal of protein conformational changes which occurred during the earlier steps in the photocycle. These results are discussed in terms of a proposed mechanism for proton transport.

Effects of mutagenetic substitution of prolines on the rate of deprotonation and reprotonation of the Schiff base during the photocycle of bacteriorhodopsin.

Membrane-buried proline residues are found in many transport proteins. To study their roles in the structure and function of bacteriorhodopsin (bR), effects of the individual substitutions of Pro-50, Pro-91 and Pro-186 on the deprotonation and reprotonation kinetics of the Schiff base (SB) were determined by flash photolysis. The obtained rate constants and the amplitudes of the slow and fast components were compared with those of ebR (wild-type bR, the native protein that is expressed in Escherichia coli). The deprotonation rates of PSB were found to be 10 times faster than that of ebR for P50A, P91A and P91G mutants, and 4 times faster for the P50G mutant. These mutations also increased the initial reprotonation rate of the SB, although the overall change in the reprotonation rate is not as significant as that in the deprotonation rate. Our results indicate that Pro-50 and Pro-91, as well as Pro-186, are important for the proton-pumping function of bR.