Skin recruitment of monomyeloid precursors involves human herpesvirus-6 reactivation in drug allergy.

BACKGROUND: In drug-induced hypersensitivity syndrome (DIHS), latent human herpesvirus (HHV)-6 is frequently reactivated in association with flaring of symptoms such as fever and hepatitis. We recently demonstrated an emergence of monomyeloid precursors expressing HHV-6 antigen in the circulation during this clinical course. METHODS: To clarify the mechanism of HHV-6 reactivation, we immunologically investigated peripheral blood mononuclear cells (PBMCs), skin-infiltrating cells, and lymphocytes expanded from skin lesions of patients with DIHS. RESULTS: The circulating monomyeloid precursors in the patients with DIHS were mostly CD11b(+) CD13(+) CD14(-) CD16(high) and showed substantial expression of skin-associated molecules, such as CCR4. CD13(+) CD14(-) cells were also found in the DIHS skin lesions, suggesting skin recruitment of this cell population. We detected high levels of high-mobility group box (HMGB)-1 in blood and skin lesions in the active phase of patients with DIHS and showed that recombinant HMGB-1 had functional chemoattractant activity for monocytes/monomyeloid precursors in vitro. HHV-6 infection of the skin-resident CD4(+) T cells was confirmed by the presence of its genome and antigen. This infection was likely to be mediated by monomyeloid precursors recruited to the skin, because normal CD4(+) T cells gained HHV-6 antigen after in vitro coculture with highly virus-loaded monomyeloid precursors from the patients. CONCLUSIONS: Our results suggest that monomyeloid precursors harboring HHV-6 are navigated by HMGB-1 released from damaged skin and probably cause HHV-6 transmission to skin-infiltrating CD4(+) T cells, which is an indispensable event for HHV-6 replication. These findings implicate the skin as a cryptic and primary site for initiating HHV-6 reactivation.

Studies on cephalopod rhodopsin: photoisomerization of the chromophore.

Photoisomerization of the chromophore of squid rhodopsin is dependent upon the irradiation temperature. Above 0 degrees C, only 11-cis in equilibrium all-trans reaction proceeds and the all-trans leads to 9-cis reaction is limited to extremely low efficiency. At liquid nitrogen temperature, 11 cis in equilibrium all-trans in equilibrium 9-cis reaction takes place. At intermediary low temperatures (-80 degrees C to -15 degrees C) another isomer of retinal may be produced by the irradiation, which forms a pigment having an absorbance maximum at 465 nm (P-465). The formation of P-465 decreases remarkably in the narrow temperature range from -30 degrees C to 0 degrees C where mesorhodopsin converts to metarhodopsin. Medsorhodopsin is quite different from metarhodopsin in the photoisomerization of the chromophore because P-465 is produced from the former but not from the latter. No P-465 is produced both at liquid nitrogen temperature and above 0 degrees C. P-465 is more labile than any of the other photoproducts so far known, that is isorhodopsin, alkaline and acid metarhodopsins. P-465 is converted to metarhodopsin by irradiation.

Molecular weight and structural studies on cephalopod rhodopsin.

The protein moiety of squid (Watasenia scintillans) rhodopsin has been shown to have a molecular weight of 46 800 by means of amino acid analysis. This value was comparable to the value (51 000) obtained from SDS-polyacrylamide gel electrophoresis. After the squid eyes were incubated at 10 degrees C for 8 days, the rhodopsin showed a molecular weight of 39 000 on electrophoresis. The smaller molecular weight was ascertained by amino acid analysis of the rhodopsin; and may result from autolysis by the lysosomal enzyme. The rhodopsin in rhabdomeric membranes and in detergent solution was treated with chymotrypsin, papain or subtilisin. These enzymes first produced the 39 000 dalton rhodopsin and then cleaved this into the 25 000 and 14 000 dalton peptides without bleaching. The rhodopsin was attacked by proteases and readily lost an approx. 12 000 dalton peptide portion. This portion included the COOH-terminal and was rich in glutamic acid, proline, glycine, alanine and tyrosine residues.

Effect of phospholipid and detergent on the Schiff base of cephalopod rhodopsin and metarhodopsin.

In the visual pigment, the chromophore retinal is bound through a Schiff base linkage with the protein moiety, opsin. The secondary interaction of retinal with opsin was studied in cephalopod rhodopsin and its photoproduct, metarhodopsin. The pK of the protonation of the Schiff base in metarhodopsin was affected by the phospholipids and detergents surrounding the protein, and varied between 9.2 and 6.9. Among nonionic detergents, the fatty acid ester of sucrose behaved like phospholipids but other detergents changed the protein conformation so that the pK of the Schiff base in metarhodopsin became nearly equal to the pK of N-retinylidene butylamine. This tendency was manifested in rhodopsin as the formation of a 380 nm pigment.

Studies on cephalopod rhodopsin. Fatty acid esters of sucrose as effective detergents.

Squid rhodopsin was extracted with solutions of fatty acid esters of sucrose (monolaurate and monostearate) and purified by DEAE-cellulose and concanavalin A-Sepharose affinity chromatography. The purified rhodopsin (A280/A480 = 2.5) contained 2.3 mol of glucosamine and 1.2 mol of phospholipid per mol of rhodopsin. The photoproduct metarhodopsin was also stable in these detergent solutions as in digitonin solution. Concanavalin A had no affinity for retinochrome.

Amino acid sequence of the retinal binding site of squid visual pigment.

The retinylpeptides of visual pigments of two species of squid were identified in invertebrate visual pigments. Their primary structures were identical: H-Phe-Ala-Lys-Ala-Ser-Ala-Ile-His-Asn-pro-Hse(Met)-OH. The sequence was homologous to those of the corresponding region of other visual pigments, but the eighth amino acid, His, was found in squid visual pigments. In this experiment the retinylpeptides of eleven amino acid residues were isolated by monitoring the absorbance spectrum of the reduced retinal Schiff base without using radio-active [3H]retinal. This method is valid for the isolation and identification of retinylpeptides of other invertebrate visual pigments in which the chromophore is not exchangeable.

Conformation changes of cuttlefish (Euprymna morsei) rhodopsin following photoconversion.

Cuttlefish (Euprymna morsei) rhodopsin solubilized in lauryl ester of sucrose and its photoproduct, acid metarhodopsin, were examined by small-angle X-ray scattering and chromatofocusing to investigate the conformation changes of visual pigment following photoconversion. From spectroscopic studies, it was found that more than 93% of Euprymna rhodopsin could be converted to meta form under the condition of red light irradiation at neutral pH. Since almost pure acid metarhodopsin solution was prepared without changing the specimen concentration, the small-angle X-ray scattering intensities of both pigment-detergent complexes were directly compared. The radius of gyration increased on going from rhodopsin to acid metarhodopsin by approximately 1.5%. There were also discernible changes in the secondary peak intensities. The distribution function, derived by the Fourier transformation of intensity data, showed a significant change around 55 A. The maximum linear dimension of the rhodopsin-detergent complex was about 95 A and hardly changed after illumination. Intensity at zero angle did not change after illumination, suggesting that the aggregation did not occur. The change of the intensity profile could be due to the conformational change of the pigment-detergent monomers. The pI value of rhodopsin determined by chromatofocusing was 5.32 and that of acid metarhodopsin was 5.06, indicating that a few carboxyl groups are newly dissociated. The shift of the protein mass and the charge redistribution were observed following photoconversion.

Fractionation of rhodopsin and other components in the rod outer segment membrane by ammonium sulfate salting-out.

Purified bovine rod outer segment membrane was solubilized in a mixture of 1.5% cholic acid/20% saturated ammonium sulfate and 0.05 M phosphate buffer (pH 7.5). The solubilized rod outer segment membrane was fractionated with ammonium sulfate and 70--90% of rhodopsin (A278/A498= 1.6--1.9) was recovered in the fraction of 50 to 60% saturation with ammonium sulfate, giving a highly concentrated solution of purified rhodopsin (A1CM 498 = 83). By the method of ammonium sulfate salting-out, the solubilized rod outer segment membrane was divided into several fractions without a loss of components. The components in each fraction were examined by sodium dodecyl sulfate polyacrylamide gel electrophoresis. Rhodopsin and opsin amounted to 93% of the total protein in the membrane. Other proteins with molecular weights of 46 000, 52 000, 56 000, 70 000, 95 000, 105 000, 130 000 and 270 000 were also detected. Most of phospholipids in the rod outer segment membrane remained in the supernatant above 60% saturation with ammonium sulfate.

Formation of the two-dimensional hexagonal lattice of bacteriorhodopsin in reconstituted brown membrane.

The aggregation state of reconstituted bacteriorhodopsin molecules in the brown membrane has been investigated by X-ray diffraction and CD spectra. It has been confirmed that reconstituted bacteriorhodopsin molecules form the hexagonal lattice spontaneously whereas bacterioopsin molecules do not.

Studies on cephalopod rhodopsin conformational changes in chromophore and protein during the photoregeneration process.

The ultraviolet absorbance of squid and octopus rhodopsin changes reversibly at 234 nm and near 280 nm in the interconversion of rhodopsin and metarhodopsin. The absorbance change near 280 nm is ascribed to both protein and chromophore parts. Rhodopsin is photoregenerated from metarhodopsin via an intermediate, P380, on irradiation with yellow light (lamda >520 nm). The ultraviolet absorbance decreases in the change from rhodopsin to metarhodopsin and recovers in two steps; mostly in the process from metarhodopsin to P380 and to a lesser extent in the process from P380 to rhodopsin. P380 has a circular dichroism (CD) band at 380 nm and its magnitude is the same order as that of rhodopsin. Thus it is considered that the molecular structure of P380 is close to that of rhodopsin and that the chromophore is fixed to opsin as in rhodopsin. In the change from metarhodopsin to P380, the chromophore is isomerized from the all-trans to the 11-cis form, and the conformation of opsin changes to fit 11-cis retinal. In the change from P380 to rhodopsin, a small change in the conformation of the protein part and the protonation of the Schiff base, the primary retinal-opsin link, occur.

Volatile anesthetics cause conformational changes of bacteriorhodopsin in purple membrane.

We examined the effects of volatile anesthetics on the structure of the bacteriorhodopsin in the purple membrane by measurements of the absorption spectrum and the visible circular dichroism (CD) spectrum and assay of the retinal composition. As the concentrations of halothane, enflurane and methoxyflurane were increased, the absorption at 560 nm decreased but that at 480 nm increased with an isosbestic point around 510 nm. These anesthetic-induced spectroscopic changes were reversible. The CD spectrum showed the biphasic pattern with a positive and a negative band. As the concentration of halothane was increased from 4 mM to 8mM, the negative band reversibly diminished more drastically than the positive band, and at 8 mM of halothane the positive band shifted to around 480 nm. These results show that halothane disturbed the exciton coupling among bacteriorhodopsin molecules. The retinal isomer composition was analyzed using high performance liquid chromatography. The ratio of 13-cis- to all-trans-retinal was 47:53, 34:66 and 19:81 at control, 7.4 mM and 14.9 mM enflurane, respectively. After elimination of enflurane, the ratio returned to the control value. These findings indicate that volatile anesthetic directly affect a bacteriorhodopsin in the purple membrane and induce conformational changes in it.

The quantitative analysis of three action modes of volatile anesthetics on purple membrane.

We quantitatively assessed the spectroscopic changes of purple membrane in relation to the concentrations of a volatile anesthetic. As reported previously, volatile anesthetics show three modes of action on purple membrane. By using an anesthetic for which the concentration in solution could be determined spectroscopically and by applying modified analytical methods regarding the M-intermediate lifetime, we were able to clarify the quantitative relation between anesthetic concentration and each mode of action, a relation which in the past has only been described qualitatively. We also determined through the measurement of transient pH changes with pyranine that the proton pump efficiency per photochemical cycle in an action mode induced with low concentrations of anesthetic does not change from that of the native state. Moreover, we dynamically obtained the individual M-bacteriorhodopsin difference spectrum of each state at room temperature using our flash photolysis system equipped with a wavelength-tunable dye laser. These results demonstrated again that we should clearly distinguish different action modes of anesthetics according to their concentrations.

4-Hydroxyretinal, a new visual pigment chromophore found in the bioluminescent squid, Watasenia scintillans.

The bioluminescent squid, Watasenia scintillans has three visual pigments. The major pigment, based on retinal (lambda max 484 nm), is distributed over the whole retina. Another pigment based on 3-dehydroretinal (lambda max approximately 500 nm) and the third pigment (lambda max approximately 470 nm) are localized in the specific area of the ventral retina just receiving the downwelling light. Visual pigment was extracted and purified from the dissected retina. The chromophores were then extracted and analyzed with HPLC, NMR, infrared and mass spectroscopy, being compared with the synthetic 4-hydroxyretinal. A new retinal derivative, 11-cis-4-hydroxyretinal, is identified as the chromophore of the third visual pigment of the squid.

Wavelength modulation by molecular environment in visual pigments.

The absorption and regenerability characteristics are compared for rhodopsin contained in rod outer segment membranes and purified in a series of alkyl sucrose esters. It is found that membrane-bound rhodopsin has maximum absorbance from 504 to 500 nm between 1.5 and 40 degrees C. After purification, rhodopsin absorbance can be blue-shifted by up to 6 nm, depending on the detergent species used. Only the longest chain sucrose esters give purified rhodopsin with maximum absorbance comparable to that of the native pigment. In the same manner, detergent-purified rhodopsin will be easily regenerated as long as its native spectral characteristics are maintained. Sucrose esters thus prove to be mild enough to maintain rhodopsin functionality with respect to these two properties and could probably be used successfully to maintain other membrane proteins' integrity.

Adaptation of a deep-sea cephalopod to the photic environment. Evidence for three visual pigments.

Watasenia scintillans, a bioluminescent deep-sea squid, has a specially developed eye with a large open pupil and three visual pigments. Photoreceptor cells (outer segment: 476 micron; inner segment: 99 micron) were long in the small area of the ventral retina receiving downwelling light, whereas they were short (outer segment: 207 micron; inner segment: 44 micron) in the other regions of the retina. The short photoreceptor cells contained the visual pigment with retinal (lambda max approximately 484 nm), probably for the purpose of adapting to their environmental light. The outer segment of the long photoreceptor cells consisted of two strata, a pinkish proximal area and a yellow distal area. The visual pigment with 3-dehydroretinal (lambda max approximately 500 nm) was located in the pinkish proximal area, giving high sensitivity at longer wavelengths. A newly found pigment (lambda max approximately 471 nm) was in the yellow distal area. The small area of the ventral retina containing two visual pigments is thought to have a high and broad spectral sensitivity, which is useful for distinguishing the bioluminescence of squids of the same species in their environmental downwelling light. These findings were obtained by partial bleaching of the extracted pigment from various areas of the retina and by high-performance liquid chromatographic analysis of the chromophore, complemented by microscopic observations.

The specific binding site of the volatile anesthetic diiodomethane to purple membrane by X-ray diffraction.

To determine the binding site of volatile anesthetics on purple membrane, diiodomethane (CH2I2) was used as a label in X-ray diffraction experiments. At less than 3 mM diiodomethane, purple membrane retains its two-dimensional crystallinity of bacteriorhodopsin, absorption spectra show only a little blue shift and the decay time of the M-intermediate becomes fast in flash photolysis experiments. These effects are similar to those of other anesthetics previously studied. The position where the anesthetic binds was identified by difference Fourier methods, and refined by model calculations. This study suggests that volatile anesthetics bind specifically to the protein-lipid interfacial region near the surface of membrane.

X-ray diffraction study of the live squid retina.

In previous studies of invertebrate rhabdomes by X-ray diffraction, glutaraldehyde fixation of the retina was used because this tissue is very labile and, without fixation, disintegrates within an hour of dissection. However, with conventional X-ray apparatus more than ten hours exposure time was needed to record a diffraction pattern. In this study, X-ray diffraction patterns from unfixed squid retina could be successfully obtained by use of synchrotron radiation and a storage phosphor screen as detector. The diffraction spots were indexed on a two-dimensional hexagonal lattice of 60 nm. X-ray data was analysed by comparing Patterson functions calculated from the diffraction intensities with those based on model building. The hexagonal shape of microvillar cross section was suggested by the systematic weakness of (0, k) reflections beyond k = 4 and the appearance of the six symmetry-related diffuse maxima around (4 nm)-1. The best-fitting model showed a large gap between adjacent microvilli (approximately 12 nm), which has been expected (for ionic current flow through the inter-microvillus space to generate the membrane potential) but not observed with the chemically fixed retina, possibly due to an artifact of fixation. Also, the existence of massive inter-microvillus material, scarcely observed by conventional electron microscopy, has been confirmed.

Isolation and nucleotide sequences of the genes encoding killer toxins from Hansenula mrakii and H. saturnus.

The HMK gene, encoding a killer toxin (HMK) of Hansenula mrakii strain IFO 0895, and the HSK gene, encoding a killer toxin (HSK) of H. saturnus strain IFO 0117, were cloned and sequenced. The HMK and HSK genes encode precursors to killer toxins of 125 amino acids (aa) and 124 aa, respectively. Both precursors have an N-terminal signal sequence of 37 aa which may be removed by a signal peptidase, and a propeptide which may be cleaved off by a KEX2-like protease. There is extensive homology between the aa sequences of HMK and HSK with the exception of the addition of one aa residue in HMK. The HMK and HSK genes were placed, separately, downstream from the yeast GAL10 promoter and introduced into a mutant of Saccharomyces cerevisiae that was resistant to the HMK. The transformants were capable of killing sensitive yeasts in medium that contained galactose with killing spectra similar to those of the donor strains of the toxins. These observations suggest that both killer toxins were synthesized and secreted from S. cerevisiae cells and killed sensitive yeasts, perhaps by the same mechanism as that associated with the donor strains and, moreover, that the difference in primary structure between the two toxins is responsible for the difference in their killing spectra.