Your search keyword '"Shimono K"' showing total 10 results

1. Production of functional bacteriorhodopsin by an Escherichia coli cell-free protein synthesis system supplemented with steroid detergent and lipid.

Author

Shimono K, Goto M, Kikukawa T, Miyauchi S, Shirouzu M, Kamo N, and Yokoyama S

Subjects

Bacteriorhodopsins chemistry, Bacteriorhodopsins genetics, Cholates chemistry, Cholic Acids chemistry, Digitonin chemistry, Escherichia coli genetics, Escherichia coli metabolism, Phosphatidylcholines chemistry, Bacteriorhodopsins biosynthesis, Liposomes metabolism, Protein Biosynthesis

Abstract

Cell-free expression has become a highly promising tool for the efficient production of membrane proteins. In this study, we used a dialysis-based Escherichia coli cell-free system for the production of a membrane protein actively integrated into liposomes. The membrane protein was the light-driven proton pump bacteriorhodopsin, consisting of seven transmembrane alpha-helices. The cell-free expression system in the dialysis mode was supplemented with a combination of a detergent and a natural lipid, phosphatidylcholine from egg yolk, in only the reaction mixture. By examining a variety of detergents, we found that the combination of a steroid detergent (digitonin, cholate, or CHAPS) and egg phosphatidylcholine yielded a large amount (0.3-0.7 mg/mL reaction mixture) of the fully functional bacteriorhodopsin. We also analyzed the process of functional expression in our system. The synthesized polypeptide was well protected from aggregation by the detergent-lipid mixed micelles and/or lipid disks, and was integrated into liposomes upon detergent removal by dialysis. This approach might be useful for the high yield production of functional membrane proteins.

Published

2009

2. A pharaonis phoborhodopsin mutant with the same retinal binding site residues as in bacteriorhodopsin.

Author

Shimono K, Furutani Y, Kandori H, and Kamo N

Subjects

Amides chemistry, Amino Acid Sequence, Binding Sites genetics, Freezing, Hydrogen Bonding, Molecular Sequence Data, Rod Opsins chemistry, Schiff Bases, Spectroscopy, Fourier Transform Infrared, Archaeal Proteins chemistry, Archaeal Proteins genetics, Bacteriorhodopsins chemistry, Carotenoids chemistry, Carotenoids genetics, Halorhodopsins, Mutagenesis, Site-Directed, Retinaldehyde chemistry, Sensory Rhodopsins

Abstract

pharaonis phoborhodopsin (ppR, also called pharaonis sensory rhodopsin II, psR-II) is a photoreceptor for negative phototaxis in Natronobacterium pharaonis. ppR has a blue-shifted absorption maximum (500 nm) relative those of other archaeal rhodopsins such as the proton-pump bacteriorhodopsin (BR; 570 nm). Among the 25 amino acids that are within 5 A of the retinal chromophore, 10 are different in BR and ppR, and they are presumed to be crucial in determining the color of their chromophores. However, the spectral red shift in a multiple mutant of ppR, in which the retinal binding site was made similar to that of BR (BR/ppR), was smaller than 40% (lambda(max) = 524 nm) than expected. In the paper presented here, we report on low-temperature Fourier transform infrared (FTIR) spectroscopy of BR/ppR, and compare the infrared spectral changes before and after photoisomerization with those for ppR and BR. The C[bond]C stretch and hydrogen out-of-plane (HOOP) vibrations of BR/ppR were similar to those of BR, suggesting that the surrounding protein moiety of BR/ppR becomes like BR. However, BR/ppR exhibited a unique IR band regarding the hydrogen bond of the protonated Schiff base. It has been known that ppR has a stronger hydrogen bond for the Schiff base than BR as judged from the frequency difference between their C[double bond]NH and C[double bond]ND stretches. We now find that replacement of the 10 amino acids of BR with ppR (BR/ppR) does not weaken the hydrogen bond of the Schiff base. Rather, the hydrogen bond in BR/ppR is stronger than that in the native ppR. We conclude that the principal factor of the smaller than expected opsin shift in BR/ppR is the strong association of the Schiff base with the surrounding counterion complex.

Published

2002

3. Selective reaction of hydroxylamine with chromophore during the photocycle of pharaonis phoborhodopsin.

Author

Iwamoto M, Sudo Y, Shimono K, and Kamo N

Subjects

Binding Sites, Photochemistry, Structure-Activity Relationship, Archaeal Proteins, Bacteriorhodopsins chemistry, Carotenoids, Halorhodopsins, Hydroxylamine chemistry, Light, Sensory Rhodopsins

Abstract

Phoborhodopsin (pR; also called sensory rhodopsin II, sRII) is a receptor of negative phototaxis of Halobacterium salinarum, and pharaonis phoborhodopsin (ppR; also pharaonis sensory rhodopsin II, psRII) is a corresponding protein of Natronobacterium pharaonis. These receptors contain retinal as a chromophore which binds to a lysine residue via Schiff base. This Schiff base can be cleaved with hydroxylamine to loose their color (bleaching). In dark, the bleaching rate of ppR was very slow whereas illumination accelerated considerably the bleaching rate. Addition of azide accelerated the decay of the M-intermediate while its formation (decay of the L-intermediate) is not affected. The bleaching rate of ppR under illumination was decreased by addition of azide. Essentially no reactivity with hydroxylamine under illumination was observed in the case of D75N mutant which lacks the M-intermediate in its photocycle. Moreover, we provided illumination by flashes to ppR in the presence of varying concentrations of azide to measure the bleaching rate per one flash. A good correlation was obtained between the rate and the mean residence time, MRT, which was calculated from flash photolysis data of the M-decay. These findings reveal that water-soluble hydroxylamine reacts selectively with the M-intermediate and its implication was discussed.

Published

2001

4. Structural changes of pharaonis phoborhodopsin upon photoisomerization of the retinal chromophore: infrared spectral comparison with bacteriorhodopsin.

Author

Kandori H, Shimono K, Sudo Y, Iwamoto M, Shichida Y, and Kamo N

Subjects

Freezing, Hydrogen Bonding, Isomerism, Photochemistry, Schiff Bases chemistry, Spectroscopy, Fourier Transform Infrared methods, Archaeal Proteins, Bacteriorhodopsins chemistry, Carotenoids, Halorhodopsins, Natronobacterium chemistry, Retinaldehyde chemistry, Sensory Rhodopsins

Abstract

Archaeal rhodopsins possess a retinal molecule as their chromophores, and their light energy and light signal conversions are triggered by all-trans to 13-cis isomerization of the retinal chromophore. Relaxation through structural changes of the protein then leads to functional processes, proton pump in bacteriorhodopsin and transducer activation in sensory rhodopsins. In the present paper, low-temperature Fourier transform infrared spectroscopy is applied to phoborhodopsin from Natronobacterium pharaonis (ppR), a photoreceptor for the negative phototaxis of the bacteria, and infrared spectral changes before and after photoisomerization are compared with those of bacteriorhodopsin (BR) at 77 K. Spectral comparison of the C--C stretching vibrations of the retinal chromophore shows that chromophore conformation of the polyene chain is similar between ppR and BR. This fact implies that the unique chromophore-protein interaction in ppR, such as the blue-shifted absorption spectrum with vibrational fine structure, originates from both ends, the beta-ionone ring and the Schiff base regions. In fact, less planer ring structure and stronger hydrogen bond of the Schiff base were suggested for ppR. Similar frequency changes upon photoisomerization are observed for the C==N stretch of the retinal Schiff base and the stretch of the neighboring threonine side chain (Thr79 in ppR and Thr89 in BR), suggesting that photoisomerization in ppR is driven by the motion of the Schiff base like BR. Nevertheless, the structure of the K state after photoisomerization is different between ppR and BR. In BR, chromophore distortion is localized in the Schiff base region, as shown in its hydrogen out-of-plane vibrations. In contrast, more extended structural changes take place in ppR in view of chromophore distortion and protein structural changes. Such structure of the K intermediate of ppR is probably correlated with its high thermal stability. In fact, almost identical infrared spectra are obtained between 77 and 170 K in ppR. Unique chromophore-protein interaction and photoisomerization processes in ppR are discussed on the basis of the present infrared spectral comparison with BR.

Published

2001

5. Photo-induced proton transport of pharaonis phoborhodopsin (sensory rhodopsin II) is ceased by association with the transducer.

Author

Sudo Y, Iwamoto M, Shimono K, Sumi M, and Kamo N

Subjects

Archaeal Proteins chemistry, Biophysical Phenomena, Biophysics, Natronobacterium chemistry, Photochemistry, Photolysis, Protons, Bacteriorhodopsins chemistry, Carotenoids, Halorhodopsins, Sensory Rhodopsins

Abstract

Phoborhodopsin (pR; also sensory rhodopsin II, sRII) is a retinoid protein in Halobacterium salinarum and works as a receptor of negative phototaxis. Pharaonis phoborhodopsin (ppR; also pharaonis sensory rhodopsin II, psRII) is a corresponding protein of Natronobacterium pharaonis. In bacterial membrane, ppR forms a complex with its transducer pHtrII, and this complex transmits the light signal to the sensory system in the cytoplasm. We expressed pHtrII-free ppR or ppR-pHtrII complex in H. salinarum Pho81/wr(-) cells. Flash-photolysis experiments showed no essential changes between pHtrII-free ppR and the complex. Using SnO2 electrode, which works as a sensitive pH electrode, and envelope membrane vesicles, we showed the photo-induced outward proton transport. This membranous proton transport was also shown using membrane vesicles from Escherichia coli in which ppR was functionally expressed. On the other hand, the proton transport was ceased when ppR formed a complex with pHtrII. Using membrane sheet, it was shown that the complex undergoes first proton uptake and then release during the photocycle, the same as pHtrII-free ppR, although the net proton transport ceases. Taking into consideration that the complex of sRII (pR) and its transducer undergoes extracellular proton circulation (J. Sasaki and J. L., Biophys. J. 77:2145-2152), we inferred that association with pHtrII closes a cytoplasmic channel of ppR, which lead to the extracellular proton circulation.

Published

2001

6. Involvement of two groups in reversal of the bathochromic shift of pharaonis phoborhodopsin by chloride at low pH.

Author

Shimono K, Kitami M, Iwamoto M, and Kamo N

Subjects

Bacteriorhodopsins genetics, Chemical Phenomena, Chemistry, Physical, Chlorides chemistry, Hydrogen-Ion Concentration, Natronobacterium chemistry, Natronobacterium genetics, Point Mutation, Recombinant Proteins chemistry, Recombinant Proteins genetics, Spectrophotometry, Archaeal Proteins, Bacteriorhodopsins chemistry, Carotenoids, Halorhodopsins, Sensory Rhodopsins

Abstract

Pharaonis phoborhodopsin (ppR; or pharaonis sensory rhodopsin II, psRII) is a photophobic receptor of the halobacterium Natronobacterium pharaonis. Its lambdamax is at 496 nm, but upon acidification in the absence of chloride, lambdamax shifted to 522 nm. This bathochromic shift is thought to be caused by the protonation of Asp75, which corresponds to Asp85 of bacteriorhodopsin (bR). The D75N mutant, in which Asp75 was replaced by Asn, had its lambdamax at approximately 520 nm, supporting this mechanism for the bathochromic shift. A titration of the shift yielded a pKa of 3.5 for Asp75. In the presence of chloride, the spectral shifts were different: with a decrease in pH, a bathochromic shift was first observed, followed by a hypsochromic shift on further acidification. This was interpreted as: the disappearance of a negative charge by the protonation of Asp75 was compensated by the binding of chloride, but it is worthy to note that the binding requires the protonation of another proton-associable group other than Asp75. This is supported by the observation that in the presence of chloride, upon acidification, the lambdamax of D75N even showed a blue shift, showing that the protonation of a proton-associable group (pKa = 1.2) leads to the chloride binding that gives rise to a blue shift.

Published

2000

7. Effects of three characteristic amino acid residues of pharaonis phoborhodopsin on the absorption maximum.

Author

Shimono K, Iwamoto M, Sumi M, and Kamo N

Subjects

Amino Acid Sequence, Amino Acids chemistry, Bacteriorhodopsins genetics, Bacteriorhodopsins radiation effects, Models, Molecular, Molecular Sequence Data, Natronobacterium genetics, Natronobacterium radiation effects, Photochemistry, Protein Conformation, Sequence Homology, Amino Acid, Spectrophotometry, Archaeal Proteins, Bacteriorhodopsins chemistry, Carotenoids, Halorhodopsins, Natronobacterium chemistry, Sensory Rhodopsins

Abstract

Phoborhodopsin (pR or sensory rhodopsin II, sRII) or pharaonis phoborhodopsin (ppR or pharaonis sensory rhodopsin II, psRII) has a unique absorption maximum (lambda max) compared with three other archaeal rhodopsins: lambda max of pR or ppR at ca 500 nm and others at 560-590 nm. Alignment of amino acid sequences revealed three sites characteristic of the shorter wavelength-absorbing pigments. The amino acids of these three sites are conserved completely among archaeal rhodopsins having longer lambda max, and are different from those of pR or ppR. We replaced these amino acids of ppR with amino acids corresponding to those of bacteriorhodopsin, Val-108 to Met, Gly-130 to Ser and Thr-204 to Ala. The lambda max of V108M mutant was 502 nm with a slight redshift. G130S and T204A mutants had lambda max of 503 and 508 nm, respectively. Thus, each site contributes only a small effect to the color tuning. We then constructed three double mutants and one triple mutant. The opsin-shifts of these mutants suggest that Val-108 and Thr-204 or Gly-130 are synergistic, and that Gly-130 and Thr-204 work additively. Even in the triple mutant, the lambda max was 515 nm, an opsin-shift only ca 30% of the shift value from 500 to 560 nm. This means that there is another yet unidentified factor responsible for the color tuning.

Published

2000

8. Positioning proton-donating residues to the Schiff-base accelerates the M-decay of pharaonis phoborhodopsin expressed in Escherichia coli.

Author

Iwamoto M, Shimono K, Sumi M, and Kamo N

Subjects

Bacteriorhodopsins genetics, Base Sequence, DNA Primers genetics, Escherichia coli genetics, Gene Expression, Halobacterium salinarum metabolism, Kinetics, Natronobacterium genetics, Natronobacterium metabolism, Photochemistry, Point Mutation, Protons, Schiff Bases chemistry, Schiff Bases metabolism, Archaeal Proteins, Bacteriorhodopsins chemistry, Bacteriorhodopsins metabolism, Carotenoids, Halorhodopsins, Sensory Rhodopsins

Abstract

Phoborhodopsin (also called sensory rhodopsin II, sR-II) is a receptor for the negative phototaxis of Halobacterium salinarum (pR), and pharaonis phoborhodopsin (ppR) is the corresponding receptor of Natronobacterium pharaonis. pR and ppR are retinoid proteins and have a photocycle similar to that of bacteriorhodopsin (bR). A major difference between the photocycle of the ion pump bR and the sensor pR or ppR is found in their turnover rates which are much faster for bR. A reason for this difference might be found in the lack of a proton-donating residue to the Schiff base which is formed between the lysine of the opsin and retinal. To reconstruct a bR-like photochemical behavior, we expressed ppR mutants in Escherichia coli in which proton-donating groups have been reintroduced into the cytoplasmic proton channel. In measurement of the photocycle it could be shown that the F86D mutant of ppR (Phe86 was substituted by Asp) showed a faster decay of M-intermediate than the wild-type, which was even accelerated in the F86D/L40T double mutant.

Published

1999

9. V108M mutant of pharaonis phoborhodopsin: substitution caused no absorption change but affected its M-state.

Author

Shimono K, Iwamoto M, Sumi M, and Kamo N

Subjects

Amino Acid Sequence, Bacteriorhodopsins genetics, Escherichia coli, Methionine chemistry, Molecular Sequence Data, Mutagenesis, Site-Directed, Sequence Homology, Amino Acid, Spectrum Analysis, Valine chemistry, Archaeal Proteins, Bacteriorhodopsins chemistry, Carotenoids, Halorhodopsins, Sensory Rhodopsins

Abstract

Crystallographic data reveal that Met-118 in bacteriorhodopsin (bR) contacts directly with the C9 methyl group of retinal, and Khorana et al. [J. Biol. Chem. 268, 20305-20311 (1993)] suggest that this contact may regulate the absorption maximum (lambdamax). We have replaced the amino acid (Val-108) corresponding to Met-118 of bR by methionine in pharaonis phoborhodopsin (ppR), whose lambdamax is ca. 500 nm, while those of other bacterial rhodopsins such as bR, halorhodopsin, and sensory rhodopsin are red-shifted by 60-90 nm. By flash-photolysis measurement, we could not recognize a large spectral red-shift of the V108M mutant. On the other hand, the decay of ppRM (M-intermediate) of the mutant was approximately three times as fast as that of wild-type, and an M-like intermediate (M') whose lambdamax is blue-shifted by 60 nm from that of M became appreciable. The replacement abolished the shoulder of the ppRM spectrum. From these findings, we infer that the distance between the retinal and the 108-position in ppR is relatively long, and that in the M-state this distance is shortened.

Published

1998

10. Functional expression of pharaonis phoborhodopsin in Escherichia coli.

Author

Shimono K, Iwamoto M, Sumi M, and Kamo N

Subjects

Bacteriorhodopsins chemistry, Cell Membrane, Cloning, Molecular, Genes, Archaeal genetics, Photolysis, Recombinant Fusion Proteins chemistry, Archaeal Proteins, Bacteriorhodopsins genetics, Carotenoids, Escherichia coli genetics, Gene Expression, Halorhodopsins, Natronobacterium genetics, Sensory Rhodopsins

Abstract

Pharaonis phoborhodopsin, the photoreceptor of the negative phototaxis of archaebacterial Natronobacterium pharaonis, was functionally expressed in the heterologous system of Escherichia coli. Flash-photolysis on a millisecond time scale indicated that the photochemical properties of ppR expressed in E. coli were the same as those of the native ppR in N. pharaonis. We concluded that the integral membrane protein ppR is correctly folded in vivo in the eubacterial E. coli membrane.

Published

1997