Photochromism of halorhodopsin. cis/trans isomerization of the retinal around the 13-14 double bond

The isomeric composition of retinal in membrane-bound and in purified but detergent-free, dark-adapted halorhodopsin was found to be about 70% 13-cis and 30% all-trans. Any illumination increased the all-trans content relative to the dark-adapted state, but blue illumination shifted the isomeric composition more toward all-trans while red illumination of blue-adapted samples shifted it more toward 13-cis. In the presence of chloride this photoisomerization caused the kind of photochromic behavior reported earlier in Smith, S. O., Marvin, M. J., Bogomolni, R. A., and Mathies, R. A. (1984) J. Biol. Chem. 259, 12326-12329, i.e. blue light caused the absorption maximum to move toward longer wavelengths and red light reversed the shift. Only the all-trans chromophore exhibited the complete photocycle described earlier in detergent-solubilized halorhodopsin, and this was the form that could be associated with light-driven chloride transport activity in cell envelope vesicles. In the absence of chloride the spectroscopic changes caused by illumination were much smaller. Reconstitution of bleached preparations with 13-cis- and all-trans-retinal, in the presence and absence of chloride, confirmed that the difference between the absorption maxima of the two isomeric forms of the chromophore is affected by chloride: 13-cis-halorhodopsin absorbs at about 567-568 nm with and without chloride, and the all-trans pigment absorbs near 568 nm in the absence of chloride, but at 578 nm in its presence. The simplest explanation of this finding is that most of the red-shift which accompanies the 13-cis----all-trans transition originates from electrostatic interaction of the retinal with chloride bound in its vicinity.     

Photoactive retinal pigments in haloalkaliphilic bacteria

Light-induced fast transient absorbance changes were detected by time-resolved spectroscopy in 38 of 51 haloalkaliphilic isolates from alkaline salt lakes in Kenya and the Wadi Natrun in Egypt. They indicate the presence of two retinal pigments, Pf and Ps, which undergo cyclic photoreactions with half-times of 2 ms and 500 ms respectively. Pf absorbs maximally near 580 nm and Ps near 500 nm. The pigments differ in their sensitivity to hydroxylamine and detergent bleaching and the photoreactions of Pf are strongly dependent on chloride concentration. Of the 38 pigment-containing strains, 29 possess both Pf and Ps, 9 possess only Ps. Inhibition of retinal synthesis with nicotine blocks pigment formation and addition of retinal restores it. Hydroxylamine-bleached pigments can be reconstituted with retinal or retinal analogues. Their similarity to the retinal pigments of Halobacterium halobium strongly suggests that they are also rhodopsin-like retinyledene proteins. Pf in all properties tested is almost identical to halorhodopsin, the light-driven chloride pump of H. halobium, and may serve the same function in the haloalkaliphiles. Ps has photocycle kinetics similar to sensory rhodopsin and a far-blue-shifted long-lived photocycle intermediate, but its ground state absorption maximum is near 500 nm instead of 587 nm. We have not found a bacteriorhodopsin-like pigment in the haloalkaliphiles.     

Spectroscopic discrimination of the three rhodopsinlike pigments in Halobacterium halobium membranes.

Membranes of Halobacterium halobium contain two photochemically reactive retinal pigments in addition to the proton pump bacteriorhodopsin. One, halorhodopsin, is also an electrogenic ion pump with a fast (on a scale of milliseconds) photoreaction cycle. The other, s-rhodopsin, is active in the same spectral region, but has a much slower photoreaction cycle (on a scale of seconds). S-rhodopsin is not an electrogenic ion pump and its properties suggest it functions as the receptor pigment for phototaxis. All three pigments have very similar absorption spectra. The recent isolation of mutants deficient in both bacteriorhodopsin and halorhodopsin and in retinal synthesis has allowed us to resolve the absorption spectra of s-rhodopsin and halorhodopsin. At neutral pH s-rhodopsin has an absorption maximum at 587 +/- 2 nm and halorhodopsin at 578 +/- 2 nm. At pH 10.8, lambda max for s-rhodopsin is shifted to 552 nm and extinction decreases slightly (15%) while halorhodopsin loses all extinction above 500 nm. Both effects are fully reversible and allow determination of the amounts of s-rhodopsin and halorhodopsin in membrane preparations containing both pigments. Both pigments were present in earlier studies of H. halobium membranes, and in view of these findings, several observations must be reinterpreted.     

Iso-halorhodopsin: a stable, 9-cis retinal containing photoproduct of halorhodopsin.

Dark-adapted halorhodopsin is a mixture of 13-cis and all-trans retinal chromophoric species. It is known that illumination with blue light increases the all-trans content, and this is reversed partially by brief red illumination. We now find that extended red-light illumination produces a third spectroscopic form. Analysis of composite absorption spectra recorded during various illumination regimes yielded the spectrum for the new species, whose absorption is shifted approximately 100 nm to the blue. The isomeric composition of retinal extracted from the illuminated pigment indicates that this form contains 9-cis retinal. This species, which we name iso-halorhodopsin, is stable in the dark at room temperature for at least a day, but can be quantitatively reconverted into a mixture of all-trans and 13-cis halorhodopsin by blue-light illumination. A kinetic scheme for the isomeric interconversions was drawn up, where iso-halorhodopsin is produced from either all-trans halorhodopsin only, or both 13-cis and all-trans forms. This kind of scheme is supported by the finding that red illumination of halo-opsin reconstituted with 13-trans-locked retinal will generate iso-halorhodopsin. A similar experiment with 13-cis-locked retinal could not be done because reconstitution with this retinal analogue was not possible. The photoreaction that leads to iso-halorhodopsin can be readily demonstrated in detergent-solubilized halorhodopsin or in halorhodopsin in liposomes made from phosphatidylcholine plus phosphatidyl-ethanolamine, but only to much reduced extent in cell envelope vesicles and in halorhodopsin incorporated into liposomes made from halobacterial polar lipids.     

Effects of chloride on the absorption spectrum and photoreactions of halorhodopsin

The absorption maximum of halorhodopsin in a membrane fraction prepared from the cells of Halobacterium halobium under low-salt conditions shifted to longer wavelenghts upon addition of NaCl (Ogurusu, T., Maeda, A., Sasaki, N. and Yoshizawa, T. (1981) J. Biochem. (Tokyo) 90, 1267–1273). This bathochromic shift was due to chloride, not sodium. Bromide and iodide were also effective. The bathochromic shift of the absorption maximum was not accompanied by any change in the isomer composition of retinal in halorhodopsin. The same ionic species were essential for the formation of the hypsochromic photoproduct at −75°C. These effects of NaCl on halorhodopsin are discussed in terms of the presence of the two forms of halorhodopsin, a form binding chloride and a chloride-free form.     

Effects of anion binding on the deprotonation reactions of halorhodopsin

The retinal Schiff base of halorhodopsin deprotonates with a pKa of 7.4 in 0.5 M Na2SO4 in the dark. In the presence of various anions, such as chloride or nitrate, etc., the pKa is raised by up to 1.5 units. Analysis of the dependency of the pKa on anion concentration favors the model in which the anions do not bind to the positively charged Schiff base nitrogen, but to a site near it, and exert their effect on the pKa by direct (perhaps electrostatic) interaction. Adding nitrate, or one of several other anions, causes also a small blueshift in the visible absorption band of the chromophore. These effects on the pKa and the absorption band define an anion binding site in halorhodopsin, termed Site I. Chloride and bromide apparently bind in addition to another site, which is associated with a small red-shift of the absorption band and changes in the photocycle. This other anion binding site is termed Site II. Illumination of halorhodopsin samples results in the deprotonation of the Schiff base with a much lowered pKa, but at very low rates probably determined by the generation of a deprotonating photointermediate. Binding of Site I anions increases the pKa of deprotonation in the light also. The similarity of the responses of the apparent pKa in the dark and in the light to anion concentration suggests that anion binding to Site I influences deprotonation of the Schiff base similarly in the photointermediate and in the parent halorhodopsin molecule.     

Flash spectroscopic studies of the kinetics of the halorhodopsin photocycle

The photoreactions of halorhodopsin are complicated by the fact that the parent pigment and its photoproducts interact with chloride. Thus, in any photoreaction scheme at least four species have to be accounted for: HR565 and HR578 Cl-, as well as HR640 and HR520 Cl-. A photocycle scheme proposed earlier places the two main photointermediates of halorhodopsin, HR520 Cl- and HR640, into a single photocycle, with a chloride-dependent equilibrium between them [Oesterhelt, D., Hegemann, P., & Tittor, J. (1985) EMBO J. 4, 2351-2356]. This scheme, with the additional feature of direct photoproduction of HR640 from HR565, was tested in this work by using numerical solutions of the appropriate differential equations to simulate flash-induced absorption changes at 500 nm (production of HR520 Cl-) and at 660 nm (production of HR640). The time scale of the simulation was ms following the flash. Comparison of the simulated curves with experimental traces yielded a unique set of three rate constants. The proposed photocycle scheme and these rate constants predict well the shapes and amplitudes of flash traces at various chloride concentrations. It appears from the photocycle scheme, and the numerical values of rate constants, that chloride is bound with high affinity to the parent halorhodopsin molecule, but with much lower affinity to its main photointermediate. This may be the consequence of the fact that in the parent halorhodopsin in the retinal configuration is all-trans, but in the two photointermediates it is 13-cis.     

Halide binding by the purified halorhodopsin chromoprotein. I. Effects on the chromophore

The halorhodopsin chromoprotein, a retinal-protein complex with an apparent molecular mass of 20 kilo-daltons, exhibits all of the halide-dependent effects found for the chromophore of functional halorhodopsin in cell envelope vesicles. With increasing halide concentration (a) an alkali-dependent 580/410 nm chromophore equilibrium (attributed to reversible deprotonation of the retinal Schiff's base) is shifted toward the 580-nm chromophore and (b) the flash-induced photocycle proceeds increasingly via P520, rather than via P660. The halide-binding site(s) responsible for these effects must reside, therefore, in the chromoprotein. Chloride and bromide are about equivalent, but iodide is much less effective in these effects and in being transported. Several other anions, i.e. thiocyanate, nitrate, phosphate, and acetate, affect the absorption maximum of the chromophore but do not allow the production of P520 upon flash illumination and are not transported. However, these ions appear to compete with chloride in the flash experiments. These observations suggest that binding of anions to a relatively nonspecific site affects the protonation state of the Schiff's base in the chromophore. Either this site directly or a more specific site, connected to the first one by a sequential pathway, is involved with the photocycle intermediates and with chloride transport by halorhodopsin.     

Light-dependent trans to cis isomerization of the retinal in halorhodopsin

Flash-induced absorption changes in the near UV were determined for bacteriorhodopsin and halorhodopsin on a millisecond time scale. The difference spectrum obtained for bacteriorhodopsin was comparable to model difference spectra of tyrosine (aromatic OH deprotonated vs protonated), as found by others. The flash-induced difference spectrum for halorhodopsin, in contrast, resembled a model spectrum obtained for trans to 13-cis isomerization of retinal in bacteriorhodopsin. A model for chloride translocation by halorhodopsin is presented, in which the retinal isomerization moves positive charges, which in turn modulate the affinity of a site to chloride.     

Characterization of the azide-dependent bacteriorhodopsin-like photocycle of salinarum halorhodopsin

The photocycle of salinarum halorhodopsin was investigated in the presence of azide. The azide binds to the halorhodopsin with 150 mM binding constant in the absence of chloride and with 250 mM binding constant in the presence of 1 M chloride. We demonstrate that the azide-binding site is different from that of chloride, and the influence of chloride on the binding constant is indirect. The analysis of the absorption kinetic signals indicates the existence of two parallel photocycles. One belongs to the 13-cis retinal containing protein and contains a single red shifted intermediate. The other photocycle, of the all-trans retinal containing halorhodopsin, resembles the cycle of bacteriorhodopsin and contains a long-living M intermediate. With time-resolved spectroscopy, the spectra of intermediates were determined. Intermediates L, N, and O were not detected. The multiexponential rise and decay of the M intermediate could be explained by the introduction of the "spectrally silent" intermediates M1, M2, and HR', HR, respectively. The electric signal measurements revealed the existence of a component equivalent with a proton motion toward the extracellular side of the membrane, which appears during the M1 to M2 transition. The differences between the azide-dependent photocycle of salinarum halorhodopsin and pharaonis halorhodopsin are discussed.     

Circular dichroism of squid rhodopsin and its intermediates

Circular dichroism (CD) and absorption spectra of squid (Todarodes pacificus) rhodopsin, isorhodopsin and the intermediates were measured at low temperatures. Squid rhodopsin has positive CD bands at wavelengths corresponding the - and β-absorption bands at liquid nitrogen temperature (CD maxima: 485 nm at -band and 348 nm at β-band) as well as at room temperature (CD maxima: 474 nm at -band and 347 nm at β-band). The rotational strength of the -band has a molecular ellipticity about twice that of cattle rhodopsin. The CD spectrum of bathorhodopsin displays a negative peak at 532 nm, the rotational strength of which has an absolute value slightly larger than that of rhodopsin. The reversal in sign at -band of the CD spectrum may indicate that the isomerization of retinal chromophore from twisted 11-cis form to twisted 11-trans form has occurred in the process of conversion from rhodopsin to bathorhodopsin. Lumirhodopsin has a small negative CD band at 490 nm, the maximum of which lies at 25 nm shorter wavelengths than the absorption maximum (515 nm), and a large positive CD band near 290 nm, which is not observed in rhodopsin and the other intermediates. This band may be derived from a conformational change of the opsin. In the process of changing from lumirhodopsin to LM-rhodopsin, the CD bands at visible and near ultraviolet regions disappear. Both alkaline and acid metarhodopsins have no CD bands at visible and near ultraviolet regions.     

Spectral properties of myeloperoxidase and its ligand complexes

The effects of ligands with various field strengths on the optical absorption spectrum of myeloperoxidase have been investigated. As is the case with other hemoproteins, the Soret peak in the optical absorption spectra at 77 K moves to longer wavelengths when strong-field ligands are present, whereas binding of such ligands as chloride and fluoride, which stabilize the high-spin state, shows the opposite effect. With a ligand of intermediate field strength, such as azide, the optical spectrum is not affected at room temperature, but lowering of the temperature results in the formation of the low-spin form of the enzyme. Similarly, in native myeloperoxidase a spin state equilibrium is found in which the low-spin state is favoured at high ionic strength and displays corresponding changes in the optical spectra. From the ligand- and the temperature-induced changes in the optical spectra of the ferric enzyme it is concluded that the band at 620-630 nm is an alpha band of the low-spin heme iron species, whereas the bands at 500 and 690 nm are probably 'charge-transfer' bands of the heme with the iron in the high-spin state.     

Biochemical characterization of halorhodopsin in native membranes

Procedures are described for selectively radiolabeling the protein moiety (haloopsin) or the chromophoric prosthestic group (retinal) of the light-driven chloride pump halorhodopsin in intact cells of Halobacterium halobium. By sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autofluorography, two retinal-binding polypeptides are observed to band near the known molecular weight of the halorhodopsin chromophoric polypeptide (25,000). Synthesis of one of these polypeptides is controlled by retinal and is sufficient for generation of complete halorhodopsin function. The other is constitutively produced by the cells and differs chemically from the haloopsin protein as indicated by differences in their V8 protease digestion patterns. V8 protease cleavage of haloopsin in its native membrane is compared with that of the protein in denaturing and nondenaturing detergents. Protease cleavage sites available in the denatured haloopsin molecule are hidden in its native membrane-integrated conformation and in nondenaturing detergent micelles. Treatment with a variety of proteases indicates susceptibility of a short terminal region of the haloopsin chain in its native conformation.     

Properties and photochemistry of a halorhodopsin from the haloalkalophile, Natronobacterium pharaonis

Pharaonis halorhodopsin is a light-driven transport system for chloride, similarly to the previously described halorhodopsin, but we find that it transports nitrate as effectively as chloride. We studied the photoreactions of the purified, detergent-solubilized pharaonis pigment with a gated multichannel analyzer. At a physiological salt concentration (4 M NaCl), the absorption spectra and rate constants of rise and decay for intermediates of the photocycle were similar to those for halorhodopsin. In buffer containing nitrate, halorhodopsin exhibits a second, truncated photocycle; this difference in the photoreaction of the pigment occurs when an anion is bound in such a way as to preclude transport. As expected from the lack of anion specificity in the transport, the photocycle of pharaonis halorhodopsin was nearly unaffected by replacement of chloride with nitrate. All presumed buried positively charged residues, which might play a role in anion binding, are conserved in the two pigments. At the extracellular end of the presumed helix C, however, an arginine residue is found in halorhodopsin, but not in pharaonis halorhodopsin, and an arginine-rich segment between the presumed helices A and B in halorhodopsin is replaced by a less positively charged sequence in pharaonis halorhodopsin (Lanyi, J. K., Duschl, A., Hatfield, G. W., May, K., and Oesterhelt, D. (1990) J. Biol. Chem. 265, 1253-1260). One or both of these alterations may explain the difference in the anion selectivity of the two proteins.     

Orientation of chromophores in reaction centers of Rhodopseudomonas sphaeroides. Evidence for two absorption bands of the dimeric primary electron donor.

Chromatophores from Rhodopseudomonas sphaeroides were oriented by allowing aqueous suspensions to dry on glass plates. Orientation of reaction center pigments was investigated by studying the linear dichroism of chromatophores in which the absorption by antenna bacteriochlorophyll had been attenuated through selective oxidation. Alternatively the light-induced absorbance changes, in the ranges 550-650 and 700-950nm, were studied in untreated chromatophores. The long wave transition moment of reaction center bacteriochlorophyll (P-870) was found to be nearly parallel to the plane of the membrane, whereas the long wave transition moments of bacteriopheophytin are polarized out of this plane. For light-induced changes the linear dichroic ratios, defined as deltaav/deltaah, are nearly the same for untreated and for oxidized chromatophores. Typical values are 1.60 at 870 nm, 0.80 at 810nm, 1.20 at 790 nm, 0.70 at 765 nm, 0.30 at 745 nm , and 0.50 at 600 nm. The different values for the absorbance decrease at 810 nm (0.80) and the increase at 790 nm (1.20) are incompatible with the hypothesis that these changes are due to the blue-shift of a single band. We propose that the decreases at 870 and 810 nm reflect bleaching of the two components of a bacteriochlorophyll dimer, the "special pair" that shares in the photochemical donation of a single electron. The increase at 790 nm then represents the appearance of a monomer band in place of the dimer spectrum, as a result of electron donation. This hypothesis is consistent with available data on circular dichroism. It is confirmed by the presence of a shoulder at 810 nm in the absorption spectrum of reaction centers at low temperature; this band disappears upon photooxidation of the reaction centers. For the changes near 760 nm, associated with bacteriopheophytin, the polarization and the shape of the "light-dark" difference spectrum (identical to the first derivative of the absorption spectrum) show that the 760 nm band undergoes a light-induced shift to greater wavelengths.     

Zinc Chloride Methylene Blue. I. Biological Stain History, Physical Characteristics and Approximation of Azure B Content of Commercial Samples

Zinc chloride methylene blue appeared on the market almost contemporaneously with the zinc-free medicinal form. The former has rarely been reported as being used in blood stains. Recent suspension of manufacture of medicinal methylene blue by it. principal American producer has excited interest in the use of the zinc chloride form for the preparation of blood stains. According to Lillie (1944a,b) the azure B content of zinc chloride methylene blue may have varied from 5 to 30% in the samples studied. Taking the Merck Index (1968, 1976) figures for the spectroscopic absorption maximum (λmax) of 667.8 and 668 nm as standard, recent samples of zinc chloride methylene blue are calculated to contain 6-8% azure B. These figures are baaed on 1) the shift of λmax after exhaustive pH 9.5 chloroform extraction, 2) evaluation of the actual ratio of the observed TiCl₂ dye content to the theoretical for pure zinc chloride methylene blue, 3) comparison of spectroscopic and staining effects of graded hot dichromate oxidation products with those of highly purified azure B-methylene blue mixtures of known proportions.

As far as can be found, medicinal methylene blue is almost the exclusive source of cosin polychrome methylene blue blood stains. Lillie (1944c) included a short series comparing 5 zinc chloride methylene blues with a dozen medicinal methylene blue samples; all were oxidized with hot dichromate to produce successful Wright stains. No effort was made to remove the zinc Exhaustive pH 9.5 chloroform extraction of zinc chloride methylene blue (lot MCB 12-H-29) yielded a small amount of red dye which when extracted into 0.1 N HCI gave λmax = 650. The extraction moved the absorption peak of the zinc chloride methylene blue from 667 to 668 nm and the midpoint of the 90% maximum absorption band, 18 nm wide, from 666.5 to 667.5 nm.     

Bacteriochlorophyll a-types in chromatophore and subchromatophore preparations from Rhodopseudomonas sphaeroides.

Comparison of absorption and circular dichroism (CD) spectra in the near infrared region was made with chromatophore and subchromatophore preparations obtained from Rhodopseudomonas sphaeroides. The 850 nm absorption band had a positive correlation with the 850 nm and 870 nm CD bands. The 800 nm and 870 nm absorption bands seemed not to correlate with any CD bands. Lipid contents in chromatophores and subchromatophores were measured. Lipids in membranes seemed to contribute to the appearance of the 870 nm absorption band, but not to that of the 800 nm and 850 nm absorption bands. The time courses of absorbance changes were compared at 800, 850, and 870 nm in detergent-treated chromatophores. Relative changes of absorbances differed from one another. The present results suggest that the three absorption bands are due to three different bacteriochlorophyll a-types and the 850 nm absorption band originates from exciton-coupling of bacteriochlorophyll a.     

One-electron reactions in biochemical systems as studied by pulse radiolysis. VI. Stages in the reduction of ferricytochrome c

When ferricytochrome c at pH about 9 is reduced by hydrated electrons and/or CO₂^?, it gives rise to an unstable form of ferrocytochrome c whose absorption spectrum, particularly in the Soret region, differs from that of normal ferrocytochrome c. This form changes intramolecularly (life-time about 0.1 s at ambient temperature) to yield normal ferrocytochrome c, and by 0.5 s the change in absorption spectrum in the range 225–600 nm produced by e^?_aq and/or CO₂^? is identical to the final change produced by reduction with an equivalent amount of sodium dithionite. This shows that both e^?_aq and CO^?₂ reduce cytochrome c with practically 100% efficiency. In the range 600–800 nm the spectrum of the unstable form is the same as that of normal ferrocytochrome c, both having small absorptions at 695 nm as compared with ferricytochrome c. As the unstable form disappears however a further loss of absorption at 695 nm occurs. This is taken to imply that the unstable form decays to a second unstable form which then rapidly donates an electron to the unchanged neutral form of ferricytochrome c, so reducing absorption in the 695 nm band. Subsequent to this process the absorption in the 695 nm band increases over a period of minutes owing to re-equilibration between the neutral and alkaline formes of ferricytochrome c. Between pH 7 and 10 the effect of pH on the absorption changes is consistent with the hypothesis of a second unstable form of ferrocytochrome c. Additional phenomena arise in more alkaline solutions. The rates of the various unimolecular processes are thought to be determined by the rates of change of conformation of the protein parts of the molecule following the change in oxidation state.     

Isolation and characterization of halorhodopsin from Halobacterium halobium

Chromoprotein of a light-driven chloride pump, halorhodopsin (HR), was isolated from Halobacterium halobium L-33, which contains HR and "slowly cycling rhodopsin-like pigment" (SR) but lacks bacteriorhodopsin (BR). The isolation was run in the presence of more than 2 M NaCl, which was required to preserve this halophilic retinal protein. Cell envelope vesicles were washed with Tween-20 to remove 80% of the proteins. The residual membranes were solubilized with 0.5% C12E9, which had little effect on the photochemical activities of HR and SR. HR was purified by passing it through a hydroxyapatite and then a phenyl-Sepharose column in 2 M NaCl and 0.5% C12E9. The absorption maximum of HR was 578 nm and the ratio of absorbance at 280 nm to 580 nm was 1.52. The apparent molecular weight of HR was 20,000 on polyacrylamide gel electrophoresis in the presence of SDS. The characteristic, bilobed CD spectrum of HR in the visible region suggested that HR exists as an oligomer in both its membrane-bound and isolated forms.     

Light and dark adaptation of halorhodopsin

Dark incubation of envelope vesicles derived from a strain of Halobacterium halobium that lacks bacteriorhodopsin but contains halorhodopsin and a third rhodopsin-like pigment caused a decrease in the flash yield [the amplitude of a transient absorbance change of flash reactive component(s) by flash] of halorhodopsin but not the rhodopsin-like pigment. The flash yield decreased to reach a low steady level after incubation for about 4 days in the dark. The flash yield of halorhodopsin at any stage of dark incubation was increased by actinic illumination of the vesicles. The flash yield at 490 nm (absorbance increase) was found to be approximately proportional to that at 590 nm (absorbance decrease). These results indicate that halorhodopsin in the envelope vesicles has two forms, dark and light adapted, and that the halorhodopsin phototransient absorbing at 490 nm is originated from the light-adapted form. A difference spectrum between these two forms of halorhodopsin shows that the light-adapted halorhodopsin was red-shifted from the dark-adapted form. The light-induced membrane potential was measured by tetraphenylphosphonium uptake. The uptake by the dark-adapted vesicles was slower than that by the light-adapted vesicles, suggesting that only the light-adapted halorhodopsin has ion-transporting activity.