The circular dichroism of rhodopsin and lumirhodopsin

Microsecond time-resolved circular dichroism of rhodopsin photointermediates

Time-resolved circular dichroism measurements, over a spectral range from 300 to 700 nm, were made at delays of 5, 100, and 500 micros after room-temperature photoexcitation of bovine rhodopsin in a lauryl maltoside suspension. The purpose was to provide more structural information about intermediate states in the activation of rhodopsin and other G protein-coupled receptors. In particular, information was sought about photointermediates that are isochromic or nearly isochromic in their unpolarized absorbance. The circular dichroism spectrum of lumirhodopsin, obtained after correcting the 5 micros difference CD data for the bleached rhodopsin, was in reasonable agreement with the lumirhodopsin CD spectrum obtained previously by thermal trapping at -76 degrees C. Similarly, the metarhodopsin II spectrum obtained with a 500 micros delay was also in agreement with the results of previous work on the temperature-trapped form of metarhodopsin II. However, the CD of the mixture formed with a 100 micros delay after photoexcitation, whose only visible absorbing component is lumirhodopsin, could not be accounted for near 480 nm in terms of the initially formed, 5 micros lumirhodopsin CD spectrum. Thus, the CD spectrum of lumirhodopsin changes on the time scale from 5 to 100 micros, showing reduced rotational strength in its visible band, possibly associated with either a process responsible for a small spectral shift that occurs in the lumirhodopsin absorbance spectrum at earlier times or the Schiff base deprotonation-reprotonation which occurs during equilibration of lumirhodopsin with the Meta I(380) photointermediate. Either explanation suggests a chromophore conformation change closely associated with deprotonation which could be the earliest direct trigger of activation.

Lumi I --> Lumi II: the last detergent independent process in rhodopsin photoexcitationt

Time-resolved absorbance difference spectra were collected at delays from 1 to 128 micros after photolysis of membrane and detergent suspensions of rhodopsin at 20 degrees C. Fitting both sets of data with two exponential decays plus a constant showed a similar fast process (lifetime 11 micros in membrane, 12 micros in 5% dodecyl maltoside) with a small but similar spectral change. This demonstrates that the Lumi I - Lumi II process, previously characterized in detergent suspensions, has similar properties in membrane without significant effect of detergent. The slower exponential process detected in the data is quite different in membrane compared to detergent solubilized samples, showing that the pronounced effect of detergent on the later rhodopsin photointermediates begins fairly abruptly near 20 micros. Besides affecting the late processes, the data collected here shows that detergent induces a small blue shift in the 1 micros difference spectrum (the Lumi I minus rhodopsin difference spectrum). The blue shift is similar to one induced by chloride ion in the E181Q rhodopsin mutant and may indicate that the ionization state of Glu181 in rhodopsin is affected by detergent.

Room temperature trapping of rhodopsin photointermediates

By suspending bovine rhodopsin in trehalose-water glass films, it is possible to trap photostates in the light-activation process. Because of the unusually high vitrification temperature of trehalose-water mixtures, this trapping can be accomplished at room temperature. This allows for a facile investigation of the spectroscopic properties of rhodopsin's photointermediates. Depending on experimental conditions, it is possible to trap photolysis products that have visible absorbance spectra closely resembling the two different photointermediates, metarhodopsin I and metarhodopsin II. When rhodopsin is maintained in the native rod outer segment membrane, the photolysis product has the spectral properties of metarhodopsin I. Upon detergent solubilization, the photolysis product closely resembles metarhodopsin II. Ultraviolet circular dichroism spectra show that the metarhodopsin I product had no change in secondary structure compared with unbleached rhodopsin. The metarhodopsin II product did show a significant decrease in alpha-helical content. Resonance energy transfer was measured from extrinsic probes located on each of the cytoplasmic cysteine residues to the retinal in the trapped photoproducts. It is seen that these distances are the same for rhodopsin and metarhodopsin I while metarhodopsin II shows considerably shorter distances. Metarhodopsin II is intimately associated with the signal transduction process, and the present results suggest that large structural changes have occurred in the transition to this state. These results demonstrate the utility of room temperature trapping of photostates in trehalose-water glasses.

Effects of depalmitoylation on physicochemical properties of rhodopsin

In an effort to determine the functionality of palmitoylation in rhodopsin, a number of physicochemical properties of depalmitoylated rhodopsin were monitored. Approximately 70% of the rhodopsin was depalmitoylated in rod outer segments by a mild hydroxylamine treatment that resulted in minimal bleaching of rhodopsin. Subsequent purification by affinity chromatography could be used to remove hydroxylamine-bleached rhodopsin. Parallel physical studies were performed on both purified, detergent-solubilized rhodopsin and rhodopsin in rod outer segments. No effect was seen on the rate of metarhodopsin II formation for depalmitoylated rhodopsin. A small effect was seen in the biphasic behavior of the rate of retinal regeneration. The circular dichroism spectrum of depalmitoylated, purified rhodopsin was virtually identical to that of the native protein. These results suggest that depalmitoylation does not greatly affect the conformational structure of rhodopsin. Circular dichroism at 222 nm was used to monitor the thermal denaturation of depalmitoylated and native rhodopsin. A small but significant decrease in the in rod outer segments. In both cases, the van't Hoff parameters showed an increase in positive enthalpy for denaturation relative to the native state. This is largely counterbalanced by an increase in positive entropy relative to the native states. The circular dichroism of the "denatured" state showed a high alpha-helix content. Depalmitoylated rhodopsin had a lower helix content than native protein in this high-temperature state. The changes in the thermodynamics upon depalmitoylation were attributed to structural changes in the denatured state.

Studies on structure and function of rhodopsin by use of cyclopentatrienylidene 11-cis-locked-rhodopsin

The photochemical reaction of cyclopentatrienylidene 11-cis-locked-rhodopsin derived from cyclopentatrienylidene 11-cis-locked-retinal and cattle opsin was spectrophotometrically studied. The difference absorption spectrum between the cyclopentatrienylidene 11-cis-locked-rhodopsin and its retinal oxime had its maximum at 495 nm (P-495). Irradiation of P-495 at -196 degrees C with either blue light or orange light caused no spectral change, supporting the cis-trans isomerization hypothesis for formation of bathorhodopsin. Upon irradiation of P-495 at 0 degree C with orange light, however, its absorption spectrum shifted to a shorter wavelength owing to formation of a hypsochromic product. The difference absorption spectrum between this product (P-466) and its retinal oxime showed its maximum at 466 nm. Analysis of retinal isomers by high-performance liquid chromatography showed that this spectral shift was not accompanied by photoisomerization of the chromophore. P-466 could almost completely be photoconverted to the original pigment (P-495) by irradiation at 0 degree C with blue light with little formation of the other isomeric form of its chromophore. The alpha-band of the circular dichroism spectrum of P-495 was very small in comparison with that of rhodopsin, while that of P-466 was comparable to it. These facts suggest that P-495 has a planar conformation in the side chain of the chromophore and that P-466 has a twisted one, probably at the C8-C9 single bond. Cyclic-GMP phosphodiesterase in frog rod outer segment was activated by neither P-495 nor P-466. This result suggests that the isomerization of the retinylidene chromophore of rhodopsin is indispensable in the phototransduction process.

Picosecond absorption studies on rhodopsin and isorhodopsin in detergent and native membrane

Picosecond transient absorption spectra of rhodopsin and isorhodopsin were measured at room temperature with a double-beam laser spectrophotometer after excitation at 355 nm. Photolysis studies were performed on rhodopsin solubilized in two different detergents (digitonin and 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate). The resulting rhodopsin/bathorhodopsin absorption difference spectra were measured at times from 35 ps to 250 ns following photoexcitation. Rhodopsin and isorhodopsin in native disk membrane were studied after suspension in 75% glycerol. Isorhodopsin was prepared by photoisomerizing rhodopsin in disk membrane at 77 K. Transient spectra obtained from the visual pigments in native membrane were of a quality approaching that obtained from detergent-solubilized rhodopsin. The batho intermediate derived from isorhodopsin was spectrally the same as that generated by rhodopsin photolysis and was produced with a quantum yield higher than had been predicted on the basis of other studies.

Bathorhodopsin intermediates from 11-cis-rhodopsin and 9-cis-rhodopsin

Bathorhodopsin-rhodopsin difference spectra of native 11-cis-rhodopsin and regenerated 9-cis-rhodopsin were measured at room temperature with a double-beam laser spectrophotometer after excitation at 532 nm. A detailed analysis of data obtained at 85 psec after excitation suggests that the bathorhodopsins generated from 11-cis- and 9-cis-rhodopsin differ in their extinction coefficients and that their absorption maxima are shifted in wavelength by about 10 nm from one another. The ratio of quantum yields for photochemical production of the 11-cis-bathorhodopsin and the 9-cis-bathorhodopsin approximates 1. Implications that the early photochemical processes in vision are more complex than previously considered are explored.

Circular dichroism of cattle rhodopsin and bathorhodopsin at liquid nitrogen temperatures

The photoevent in vision has been considered to be the conversion of rhodopsin to bathorhodopsin, which is caused by photoisomerization of the chromphoric retinal. Recently some objections were raised to this hypothesis. The reliability of the hypothesis was verified by measurement of circular dichroism of bathorhodopsin. The measurement of circular dichroism of rhodopsin extract (containing 66% or 75% of glycerol) at liquid nitrogen temperatures (-195 degrees C) by a conventional spectropolarimeter induced an extraordinary large signal, owing to linear dichroism originated from conversion of rhodopsin to bathorhodopsin by the measuring light. The similar linear dichrolism can be induced by irradiation of rhodopsin extract at -195 degrees C with polarized light or natural light. At photosteady state the linear dichroism disappeared. Circular dichroism spectrum of cattle rhodopsin displayed two positive peaks ([theta]max = 80 800 degrees at 335 nm, and [theta]max = 42 600 degrees at 500 nm) at -195 degrees C, whereas, bathorhodopsin displayed a positive peak ([theta]max = 43 100 degrees at 334 nm) and a negative peak ([theta]max = 163 000 degrees at 540 nm). The change of the positive sign to negative one at alpha-band of circular dichroism spectrum supports the hypothesis that the conversion of rhodopsin is due to rotation of the chromophoric retinal about C-11--12 double bond ('photoisomerization model').

Optical activity of octopus metarhodopsins

The optical activity of octopus rhodopsin, acid metarhodopsin and alkaline metarhodopsin was studied by a sensitive and rapid CD apparatus. For sometime it has been thought that cephalopod metarhodopsins do not have any optical activity associated with their main absorption band. However, the present work shows that acid metarhodopsin in digitonin has a positive CD band at 498 nm and a negative CD band at 436 nm and alkaline metarhodopsin has a negative CD band at 381 nm. Detergent affected the wavelength of the CD peak of the visual pigments though the pattern of the spectrum was similar. From these results it is concluded that the conformation of all-trans retinal in octopus metarhodopsin is influenced by the asymmetric conformation of the protein near the retinal and therefore inducing optical activity.

Molecular mechanism for the initial process of visual excitation. III. Theoretical studies of optical spectra and conformations of chromophores in visual pigments, their analogues and intermdiates based on the torsion model

The torsion model with which we proposed to interpret the specific properties of the photoisomerization reaction of rhodopsin has been developed to apply to isorhodopsin I, isorhodopsin II and some intermediates. Based on this model, optical absorption wavelengths and oscillator strengths, as well as rotational strengths of visual pigments, analogues and intermediates at low temperatures are analyzed by varying twisted conformations of the chromophores. As a result, it was found that most of the optical data could be very well accounted for quantitatively by the torsion model. The twisting characters in the chromophore of rhodopsin are very similar to those of isorhodopsin. The obtained conformations of the chromophores are very similar in rhodopsin and its analogues, and in isorhodopsin and its analogues. Those of the chromophores of bathorhodopsin, lumirhodopsin and metarhodopsin I are similar to one another except that the conjugated chain of metarhodopsin I bends considerably when compared with the other intermediates.

Circular dichroism of squid rhodopsin and its intermediates

Circular dichroism (CD) and absorption spectra of squid (Todarodes pacificus) rhodopsin, isorhodopsin and the intermediates was measured at low temperatures. Squid rhodopsin has positive CD bands at wavelengths corresponding the alpha- and beta-absorption bands at liquid nitrogen temperature (CD maxima: 485 nm at alpha-band and 348 nm at beta-band) as well as at room temperature (CD maxima: 474 nm at alpha-band and 347 nm at beta-band). The rotational strength of the alpha-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 alpha-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 de 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.

Reversible changes in circular dichroism spectra of cattle rhodopsin and isorhodopsin

When the disk membrane of rod outer segment is treated with detergents, the alpha-band CD of rhodopsin decreases and the gamma-band CD increases. This tendency of CD change is most prominent in the purified rhodopsin in cholic acid obtained by the ammonium sulfate fractionation of disk membranes, and the gamma-band CD is three times larger than the alpha-band CD. The beta-band CD of rhodopsin is only slightly influenced by detergents. The gamma-band of isorhodopsin shows two CD bands, one negative and one positive. Both in rhodopsin and isorhodopsin the gamma-band CD is lost by light irradiation. It is supposed that both chromophore retinal and aromatic amino acid residues of opsin are responsible for the gamma-band CD. When ammonium sulfate is added to the sonicated disk membranes suspended in cholic acid solution, the alpha-band CD of rhodopsin decreases to about a third and the gamma-band CD increases remarkably. The CD spectrum goes back to the original one on eliminating ammonium sulfate from the solution with dialysis. However, the purified rhodopsin recovers native CD spectrum on addition of lipids extracted from disk membranes. The retinal-opsin interaction that induces optical activity depends upon the property of a local environment formed by lipid and detergent.

The quantum efficiency for the photochemical conversion of the purple membrane protein

The quantum efficiency for the formation of M(412), an intermediate product in the photoconversion of the purple membrane protein of Halobacterium halobium, was determined to be 0.30 +/- 0.03 at -40 degrees C. This photochemical reaction was photoreversible to the original pigment and the ratio of the quantum efficiencies gamma PM(568 leads to M(412)/gamma M(412) leads to PM(568) was 0.39 +/- 0.02. No change was seen in either value when exciton interaction between chromophores was eliminated. The sum of gamma PM(568) leads to M(412) plus gamma M(412) leads to PM(568) was 1.07 +/- 0.10, approximately 1, suggesting that the pigment and its primary photoproduct share a common excited state.

Alkyl glucosides as effective solubilizing agents for bovine rhodopsin. A comparison with several commonly used detergents

The suitability of octyl and decyl-beta-D-glucoside as solubilizing agents for the bovine retinal rod outer segment disc membrane was investigated and compared to that of hexadecyltrimethylammonium bromide, N,N-dimethyldodecylamine oxide, Emulphogene BC-720 and digitonin. The properties measured included the thermal stability of rhodopsin, regenerability of bleached rhodopsin by addition of 11-cis-retinal, and the rate of denaturation of bleached rhodopsin as measured by changes in the ultraviolet CD spectrum. Denaturing tendencies of the detergents were also evaluated by observing their effects on the absorption and CD spectra of sperm whale metmyoglobin. Our results demonstrate that octyl glucoside is superior to the other detergents, with the possible exception of digitonin, by the above criteria. Unlike digitonin, however, octyl glucoside affords rapid solubilization of the disc membrane and is itself highly soluble. Decyl glucoside has properties equivalent or superior to octyl glucoside, but salts and buffers interfere with its ability to solubilize the disc membrane. The well defined chemical composition, ease of removal by dialysis, and non-denaturing properties of the alkyl glucosides make them attractive detergents for membrane research.

Circular dichroism of cephalopod rhodopsin and its intermediates in the bleaching and photoregeneration process

In the bleaching process of cephalopod rhodopsin, a new intermediate was found in the conversion process from lumirhodopsin to metarhodopsin. This intermediate of octopus has an absorption peak at about 475 nm and has been named as M475. The circular dichroism value of M475 is too small to be evaluated. On the other hand, lumirhodopsin shows a negative CD at 470 nm, a positive CD at 350 nm and a large positive CD band with three peaks at 280, 287 and 295 nm. Such a large CD band in the ultraviolet region is not observed in rhodopsin, M475 and metarhodopsin. This CD seems to be mainly due to tryptophan and tyrosine residues restricted in free rotation in the protein moiety of lumirhodopsin. The intermediate in the photoregeneration process of cephalopod rhodopsin, P380, has a positive CD band at the main peak, 380 nm, and also a large positive CD band in the ultraviolet region like lumirhodopsin.