The effect of elevated hydrostatic pressure on the spectral absorption of deep-sea fish visual pigments

doi:10.1242/jeb.01984

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):

Home Help Feedback Subscriptions Archive Search Table of Contents

First published online January 3, 2006
Journal of Experimental Biology 209, 314-319 (2006)
Published by The Company of Biologists 2006
doi: 10.1242/jeb.01984

This Article

Summary

Figures Only

Full Text (PDF)

Alert me when this article is cited

Alert me if a correction is posted

Services

Email this article to a friend

Similar articles in this journal

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via Google Scholar

Google Scholar

Articles by Partridge, J. C.

Articles by Douglas, R. H.

Search for Related Content

PubMed

PubMed Citation

Articles by Partridge, J. C.

Articles by Douglas, R. H.

The effect of elevated hydrostatic pressure on the spectral absorption of deep-sea fish visual pigments

J. C. Partridge¹^,*, E. M. White¹ and R. H. Douglas²

¹ School of Biological Sciences, University of Bristol, Woodland Road, Bristol BS8 1UG, UK
² Applied Vision Research Centre, The Henry Wellcome Laboratories for Vision Sciences, Department of Optometry and Visual Science, City University, Northampton Square, London EC1V OHB, UK

^* Author for correspondence (e-mail: j.c.partridge{at}bristol.ac.uk)

Accepted 14 November 2005

Summary

TOP
Summary
Introduction
Materials and methods
Results
Discussion
References

The effect of hydrostatic pressure (0.1-54 MPa, equivalent topressures experienced by fish from the ocean's surface to depthsof ca. 5400 m) on visual pigment absorption spectra was investigatedfor rod visual pigments extracted from the retinae of 12 speciesof deep-sea fish of diverse phylogeny and habitat. The wavelengthof peak absorption ( ${lambda}$ _max) was shifted to longer wavelengths byan average of 1.35 nm at 40 MPa (a pressure approximately equivalentto average ocean depth) relative to measurements made at oneatmosphere (ca. 0.1 MPa), but with little evidence of a changein absorbance at the ${lambda}$ _max. We conclude that previous ${lambda}$ _max measurementsof deep-sea fish visual pigments, made at a pressure close to0.1 MPa, provide a good indication of ${lambda}$ _max values at higher pressureswhen considering the ecology of vision in the deep-sea. Althoughnot affecting the spectral sensitivity of the animal to anyimportant degree, the observed shift in ${lambda}$ _max may be of interestin the context of understanding opsin-chromophore interactionand spectral tuning of visual pigments.

Key words: visual pigment, retina, deep-sea fish, pressure

Introduction

TOP
Summary
Introduction
Materials and methods
Results
Discussion
References

The spectral tuning of animal visual pigments is generally consideredto be highly adaptive and correlated with the visual environment (Lythgoe,1979; Partridge and Cummings, 1999). Although this relationshipis not always simple, it is especially apparent in many fish(Lythgoe, 1988; Douglas, 2001) particularly those inhabitingthe deep-sea (Douglas et al., 1998, 2003). Most illuminationin the deep ocean, whether from sunlight or bioluminescence,is concentrated in a narrow portion of the spectrum around 460-480nm, and the vast majority of deep-sea fish have rod visual pigmentsabsorbing maximally in this spectral region (for a review, seeDouglas et al., 1998). Seemingly, this provides one of the clearestexamples of visual pigment adaptation to a specific environment.This classic observation, first predicted by Clarke (1936),was later confirmed by Denton and Warren (1956) and Wald etal. (1957) and has been overwhelmingly supported by numerouslater studies (for a review, see Douglas et al., 1998). Nevertheless,it is possible that all such investigations have been subjectto a fundamental artefact because the elevated hydrostatic pressureencountered at depth in the sea has been hitherto ignored.

All visual pigments comprise a G-protein coupled protein (opsin)bound to a vitamin A-derived chromophore. The spectral absorptionof the visual pigment is determined by the proximity to thechromophore of a small number of key amino acids (Yokoyama,2002). The positioning of these amino acids is, in turn, determinedby the complex tertiary protein structure. Many proteins invery deep-living organisms show adaptations that allow themto operate optimally at elevated pressure (Somero et al., 1983; Somero,1992). Pressure in the ocean increases with depth (ca. 0.1 MPa,or ca. 1 bar, for every 10 m below the surface) and, as theaverage depth of the oceans is close to 4000 m, the pressureexperienced by deep-sea animals at this depth is ca. 40 MPa.Such pressures are known to affect protein tertiary conformationby the compression of internal cavities and by local and globaldistortion of structural components including alpha helices (Mozhaevet al., 1996). It is likely, therefore, that the pressures experiencedat depth will affect opsin structure and may, thereby, affectvisual pigment absorption characteristics, particularly thewavelength of maximum absorbance ( ${lambda}$ _max). Indeed, an absorbanceincrease and bathochromatic shift in ${lambda}$ _max is to be predictedfor rhodopsin under pressure by inference from the bathochromaticshift observed on cooling (Tsuda and Ebrey, 1980; Yoshizawa,1972) and from spectral measurements of bacteriorhodopsin madeat elevated pressures (Klink et al., 2002). All spectral measurementsof deep-sea fish visual pigment made to date, and on which theobserved correlations with environmental variables are based, however,have been recorded at atmospheric pressure. We have therefore measuredthe visual pigment absorption spectra of extracts of rod pigments from12 species of mesopelagic and demersal deep-sea fish when subjectedto pressures of up to 54 MPa.

Materials and methods

TOP
Summary
Introduction
Materials and methods
Results
Discussion
References

Two specially constructed high pressure hydrostatic chamberswere placed into the sample and reference beams of a ShimadzuUV2101PC double beam spectrophotometer (Kyoto, Japan). Eachchamber consisted of a 90 mm long, 100 mm diameter stainlesssteel tube to which 10 mm thick, 100 mm diameter end caps holding23 mm diameter fused silica windows were bolted. Once completely filledwith distilled water, the pressure within these chambers couldbe increased using a Gilson HPLC pump (model 302, Middleton,WI, USA) connected to them via Swagelok^TM tubing (Bristol FluidSystem Technologies Ltd, Bristol, UK). A central cavity withineach chamber held a standard quartz cuvette, which could beinserted via a 12 mm diameter threaded opening fitted with ahigh-pressure Swagelok plug. The low volume (10 mm path length)cuvettes in the sample and reference beams were filled to theirbrims with visual pigment extract (see below) and saline, respectively,and sealed with Parafilm^TM before being introduced into thepressure chambers. After filling the pressure chambers withdistilled water they were purged to displace any air by brieflyrunning the HPLC pump. Subsequently, pressure was applied inincrements under the control of a Gilson (model 802) manometric moduleto an estimated accuracy of ±0.3 MPa, pressures being cross-calibratedand monitored with a Swagelok analogue pressure gauge (FSD 600bar).

The absorption spectra of visual pigments from 12 species ofdeep-sea fish, from a variety of families and a range of habitatsand depths (Table 1) were measured at various pressures. Demersalspecies were caught using a benthic trawl in the North EasternAtlantic (RRS Discovery cruise 255 and RRS Challenger cruise134), while pelagic animals were sampled with a midwater netin the Pacific north of Hawaii, or off the coast of Guatemala (cruises142 and 173 of the RV Sonne, respectively) and the Southern Ocean(RRS James Clark Ross cruise 100). All animals were collected, handled,and tissue prepared as previously described (Partridge et al.,1989; Douglas et al., 1995). Briefly, immediately after captureanimals were transferred to iced seawater within light-tightcontainers. In a darkroom, and working under dim red light, retinaewere removed from hemisected eyes and either their visual pigments wereextracted immediately and then frozen, or the retinae were frozenin 20 mmol l^-1 Pipes-buffered saline (450 mOsm kg^-1, pH 7.3) forlater extraction.

View this table:
[in this window]
[in a new window]

Table 1. Effect of hydrostatic pressure on the wavelength of maximum absorbance ( ${lambda}$ _max) of difference spectra of visual pigment extracts from 12 species of deep-sea fish, from a range of depths and habitats

Visual pigments were extracted from both fresh and frozen materialin an identical manner using the detergent n-dodecyl ß-D-maltoside,as detailed elsewhere (Partridge et al., 1992; Douglas et al.,1995). Initial extractions used Pipes-buffered saline, but laterexperiments used 50 mmol l^-1 Tris-buffered saline (300 mOsmkg^-1, pH 7.0) as this buffer is known to have a negligibly smallpressure coefficient (Tsuda, 1982; Neuman et al., 1973). In visualpigment spectroscopy it is usual to add hydroxylamine (NH₂OH)to visual pigment extracts to shift photoproduct absorbance toshort wavelengths, well away from the visual pigment's absorbancepeak, thus enabling more accurate determination of visual pigment ${lambda}$ _max(Knowles and Dartnall, 1977). However, this was not done inthis instance as the exact ${lambda}$ _max values for all species examinedhere have been previously established and the primary aim ofthis study was to ascertain whether pressure shifted the ${lambda}$ _maxrather than to place the visual pigment ${lambda}$ _max accurately. It wasalso felt to be advantageous to minimise the complexity of thereaction conditions of the visual pigment during bleaching incase these exhibited pressure-dependence.

The spectral absorption (300-700 nm) of the extracted visualpigment was determined at atmospheric pressure (ca. 0.1 MPa)and following increases in pressure to 9.0, 20.0, 31.0 and 45.8or 54.0 MPa, a procedure taking approximately 5 min, beforethe extract was measured once more at atmospheric pressure.The pressure chamber was then opened and the visual pigmentsolution irradiated from above with an incandescent light sourcefor 30-60 min. After resealing the chamber, the absorption spectrumof the bleached visual pigment solution was remeasured in thesame sequence of ascending pressures. Difference spectra weresubsequently constructed by subtracting the bleached from theunbleached absorbance spectrum at each pressure. The ${lambda}$ _max valuesand absorbance at that ${lambda}$ _max of these difference spectra weredetermined by fitting the visual pigments templates of Govardovskiiet al. (2000) using methods described by Hart et al. (2000).

View larger version (17K):
[in this window]
[in a new window]

Fig. 1. (A) Absorbance spectra of visual pigment extracted from the retina of Bathysaurus ferox measured in unbleached and bleached states at pressures of 0.1, 9.0, 20.0, 31.0 and 45.8 MPa. For clarity of presentation all scans have been zeroed at 700 nm. (B) Difference spectra for each pressure constructed using the curves shown in Fig. 1A. Scans have been zeroed at the minimum long-wave absorbance (see Hart et al., 2000

	Results

TOP Summary Introduction Materials and methods Results Discussion References

Fig. 1A shows the absorbance spectra of a visual pigment extractfrom the retina of Bathysaurus ferox at different pressures,both before and after bleaching. Difference spectra at eachof these pressures are shown in Fig. 1B.

The ${lambda}$ _max values of the bleaching difference spectra correspondingto each pressure were plotted as a function of pressure for everyanimal and linear regression lines were fitted to these data(e.g. Fig. 2A). Coefficients derived for higher order polynomialswere not significant, indicating that linear regression modelswere most appropriate over the range of pressures used. In allcases there was a small but significant increase in ${lambda}$ _max withincreasing pressure. In addition to previously measured ${lambda}$ _maxvalues for the visual pigments of the examined species, Table 1presents the average slope and intercept of the regressionline for each species, as well as the calculated shift in ${lambda}$ _maxthat would be induced by pressure elevation from atmosphericpressure to 40 MPa (the approximate pressure at the averagedepth of the ocean). For different species this calculated ${lambda}$ _maxshift ranged from 0.84 to 2.36 nm. No significant correlations(Spearman's rank correlation, r_s; N=12) were found between thegradients of these regression lines and capture depth (r_s=0.021,P=0.948), nor between this gradient and visual pigment ${lambda}$ _max at0.1 MPa (r_s=0.042, P=0.897), nor absorbances at the ${lambda}$ _max measuredat 0.1 MPa (r_s=0.042, P=0.897).

View larger version (15K):
[in this window]
[in a new window]

Fig. 2. (A) Relationship between ${lambda}$ _max and pressure for the visual pigment of the animal (Bathysaurus ferox) whose visual pigment difference spectra are shown in Fig. 1B. The data are fitted by the following linear regression: ${lambda}$ _max=0.021943P+484.6437; where P is the pressure in MPa. (B) Relationship between absorbance at the ${lambda}$ _max and pressure for the visual pigment of the animal (Bathysaurus ferox) whose visual pigment difference spectra are shown in Fig. 1B. The data are fitted by the following linear regression: A=5.806x10^-5P+0.149787, where A is the absorbance at the ${lambda}$ _max and P is the pressure in MPa.

In contrast, however, the average gradient for the effect ofpressure on ${lambda}$ _max (0.0338 nm MPa^-1) was found to be significantlydifferent from zero (Student's one sample t-test: t=11.60, P=0.000,N=12). This corresponds to a calculated ${lambda}$ _max shift at 40 MPapressure of 1.35 nm. Interestingly, pressure also affected the ${lambda}$ _max of the absorbance spectra of samples of the food dye carmoisine(E122), a pigment chemically distant from visual pigments buthaving a similar bell-shaped absorption spectrum. When E122absorption spectra were analysed as if they were visual pigmentdifference spectra, a statistically significant linear risein ${lambda}$ _max was observed in response to applied pressure, the averagegradient for the effect of pressure on the ${lambda}$ _max being 0.010328±0.002765nm MPa^-1 (mean ± s.d., N=5), which was significantlydifferent from zero (Student's one sample t-test: t=8.35, P=0.001,N=5). The calculated increase in carmoisine ${lambda}$ _max at 40 MPa was0.41 nm, which is significantly different from the shift (1.35nm) observed for the average of the visual pigments (Student'sone sample t test: t=-19.11, P=0.000, N=5).

In most experiments absorbance at the ${lambda}$ _max rose with increasingpressure (e.g. Fig. 2B), but this effect was variable and, fora third of the samples and species measured, the relationshipbetween peak absorbance and pressure was not significantly differentfrom zero (i.e. P>0.05 for the regression coefficient forthe gradient). Over all species, the average gradient was 5.44x10^-5MPa^-1 and, using the regression intercept as a measure of absorbanceat atmospheric pressure for all species, the average increasein absorbance at 40 MPa is calculated to be 0.9%. This averagegradient is not significantly different from zero (Student'sone sample t-test: t=0.99, P=0.342, N=12), from which we concludethat we have no significant evidence for an effect of pressureon peak absorbance in the species examined here.

Discussion

TOP
Summary
Introduction
Materials and methods
Results
Discussion
References

This investigation of visual pigment absorption spectra at elevated pressurewas conducted in order to answer two main questions. (1) Doprevious data on the ${lambda}$ _max of deep-sea fish visual pigments measured atatmospheric pressure provide adequate estimates of in vivo values? (2)What insights can measurements at high pressures provide intothe evolutionary adaptation of visual pigments operating inthe deep-sea? The spectrophotometric measurements provided twofundamental pieces of data for each species investigated: theeffect of pressure on ${lambda}$ _max, and the effect of pressure on absorbanceat the ${lambda}$ _max. We conclude that visual pigments of these deep-seafish showed an average increase in ${lambda}$ _max of approximately 1.35nm in response to an elevation in hydrostatic pressure of 40MPa when measured in detergent extract. We have no significantevidence that this shift was accompanied by a change in absorbanceat the ${lambda}$ _max, nor evidence that deeper living species show moreor less pressure dependence than shallow living species. Ifthese observations are representative of the behaviour of visual pigmentsin vivo then elevated hydrostatic pressure would not affect theabsorption spectra of the visual pigments to any degree thatis physiologically important. Nevertheless, the observed shiftin ${lambda}$ _max may be indicative of changes in opsin conformation that couldhave other consequences, with the potential to affect visual performance.

The species investigated here are representatives of a widerange of habitats and depth ranges, comprising animals thatlive on or near the ocean floor at depths to 4500 m to thoseinhabiting much shallower pelagic habitats (Table 1). The lackof obvious correlations between visual pigment behaviour underpressure and depth of capture is therefore potentially instructive.We have taken the medians of the shallowest capture depths recordedfor a particular species at Fishbase (http://www.fishbase.org), thesebeing tabulated in Table 1.We realise these depth measures areimperfect as, for example, some of mesopelagic species almostcertainly occur at the water surface at night and using themedian will result in a greater estimate of minimum capturedepth. However, the values tabulated in Table 1 provide a better estimateof a species' depth distribution than reliance on any singlestudy. Using these depth data we calculated correlations betweencapture depth and the rate of increase in ${lambda}$ _max with applied pressure,and between capture depth and the rate of change in absorbanceat the ${lambda}$ _max_. In neither case did Spearman's rank correlationcoefficients indicate a significant relationship (r_s=0.021,N=12, P=0.948; r_s=-0.119, N=12, P=0.713. respectively).

Although small, an effect of pressure on ${lambda}$ _max was observed inall animals investigated and the average gradient (0.0338 nm MPa^-1)is not only highly significantly different from zero (Student'sone sample t-test, t=11.60, N=12, P=0.000) but also the power(the probability of being able to detect this sized difference)of this statistical test is very high (1.000). Bathochromaticshifts in ${lambda}$ _max have been observed when rhodopsin is cooled (Yoshizawa, 1972)and this has been interpreted as due to solvent compression analogousto that occurring at elevated pressure (Tsuda and Ebrey, 1980).In addition, bathochromatic shifts in ${lambda}$ _max have been observed inthe bacteriorhodopsin at high pressures (Klink et al., 2002).Although a light-activated proton pump rather than a visualpigment, and phylogenetically distant from vertebrate rhodopsins,this molecule shares aspects of rhodopsin's structure and alsoutilises retinal as a chromophore. Klink et al. (2002) measured ${lambda}$ _maxshifts of ca. 2 nm in bacteriorhodopsin at 40 MPa, slightlymore than the average ${lambda}$ _max shift (1.35 nm) that we observed atthis pressure.

We are, however, more cautious in our tentative conclusion thatabsorbance at the ${lambda}$ _max is pressure-independent. The average increasein absorbance with pressure was 5.44x10^-5 MPa^-1. Using the regressionintercepts as estimates of absorbance at atmospheric pressurefor each species, this corresponds to an average increase in absorbanceat 40 MPa of 0.9%. An increase in absorbance is to be expected purelyon grounds of solvent compressibility: for instance, assuminga linear bulk modulus for water of 2.2x10⁹ Pa (a value thatis probably an overestimate at the pressures we investigated;see Hayward, 1967) a rate of increase in absorbance of 4.545x10^-4MPa^-1 is to be anticipated, corresponding to an absorbance increaseof 1.8% at 40 MPa. As previously stated, we are unable to detecta significant average effect of pressure on absorbance: i.e.the observed average gradient was not significantly differentfrom zero (Student's one-sample t-test: t=0.99, N=12, P=0.342)but the power of this test is low (0.148). In fact neither couldwe detect a significant difference between our observationsand the gradient estimated by calculation based on the bulkmodulus of water (Student's one-sample t-test: t=-7.29, N=12,P=0), despite the fact that, in this case, our power to differentiatethe observed from the calculated values is high (1.000). Pressurealso increased the absorbance of the food dye carmoisine, toa greater degree, with an average gradient of 1.49x10^-4 MPa^-1(s.d.=1.49x10^-4 MPa^-1, N=5), but this value has high varianceand is not significantly different from zero (Student's onesample t-test: t=2.24, P=0.089, N=5) although like the visual pigmentgradient, the rate of increase was also significantly differentfrom that predicted by calculation (t=-4.58, P=0.010, N=5).Further data will be required to determine whether visual pigmentsindeed behave differently from physical predictions (as our measurementssuggest), and that their absorbance is less affected by pressure thanpredicted by the above calculation. Further data are also requiredto test whether our conclusions based on the species' averagemasks diversity in visual pigment pressure dependence at specieslevel.

Visual pigments can be measured spectrophotometrically in anumber of ways, including as extract, by microspectrophotometry,as retinal whole mounts, and as outer segment suspensions. Whilewith the first of these the pigment is in solution, the othertechniques examine pigments within the outer segment membrane.The design of our pressure vessel constrained our measurementsto the examination of detergent extracts, since retinal wholemounts and outer segment suspensions induce an unacceptablelevel of scatter, for which we could not compensate in the currentset up. However, the precise ${lambda}$ _max of rod pigment measurementsshows little variation with method (Douglas et al., 1995) andextract measurements are therefore a reliable indication ofa visual pigment's absorption within the photoreceptor, at leastat atmospheric pressure. Nevertheless, as shown in Table 1, ${lambda}$ _max measurements obtained in this study differ from previousmeasurements by several nm. These differences can be attributedto the presence of visual pigment mixtures in some species and/or tothe absence of hydroxylamine in the photo-bleaching conditionsused in this study (hydroxylamine being eliminated to simplifythe chemical environment of the visual pigment). As shown inFig. 1, there is considerable overlap between the photoproductand alpha absorption band of the relatively short-wave-sensitiverod visual pigments measured here, and this will inevitablyaffect the precision of ${lambda}$ _max measurements. Further experimentsare required to determine the effect of the addition of hydroxylamineon visual pigments under pressure.

In vivo, visual pigments in photoreceptors are located in outer segmentmembranes. As long as visual pigments in outer segment membranes behaveunder pressure as they do in extract, it is likely that ${lambda}$ _maxvalues determined at atmospheric pressure in previous studiesof deep-sea fish visual pigments, on which all correlationsbetween visual pigment spectral absorption and habitat are based (Partridgeet al., 1989; Douglas et al., 1998), represent the true valuesfor visual pigments present within the animals' photoreceptorsat depth. Nevertheless, this conclusion has the caveat that pressuremay be found to affect ${lambda}$ _max when the visual pigment is in situin rod outer segment membranes rather than in extract: thispossibility requires further study.

Of particular vulnerability to perturbation by pressure arebiomolecular reactions that are associated with relatively largevolume changes, or depend on the fluidity of cell membrane lipidbilayers, or in which conformation changes occur during activity(Somero, 1992; Gross and Jaenicke, 1994). Visual pigments exhibitseveral of these characteristics during activation by light,in resultant interactions with intracellular messengers, intermination of activity, and in their regeneration. It is probablethat such phenomena will be affected by pressure, particularlyas both enzyme reactions (Mozhaev et al., 1994) and protein-proteininteractions (Heremans, 1982) are known to be pressure sensitiveat pressures encountered in the deep-sea. Indeed, effects ofpressure on the transmembrane signalling of other G-proteincoupled receptors have been shown (Siebenaller and Garrett,2002). Further study of these facets of visual pigment behaviourunder pressure will be aided by the wealth of opsin sequencedata (some 30 rod opsin sequences) that are already availablefrom diverse deep-sea fish taxa (Hope et al., 1997; Hunt etal., 2001), and the solved structure of a vertebrate rod rhodopsin (Palczewskiet al., 2000).

Acknowledgments

We would like to acknowledge the help of the Masters, crewsand scientists aboard the RV Sonne, RRS Discovery, RRS Challengerand RRS James Clark Ross and particularly the principal scientistswho enabled us to join their cruises: Prof. Dr rer. nat. ErnstFluh, Dr rer. nat. Willi Weinrebe, Dr Phil Bagley and Dr MartinCollins. We also thank Prof. H.-J. Wagner for considerable logisticalsupport on the Sonne cruises, Prof. I. A. Johnston for the giftof the HPLC pump, Stephanie Wong for assistance with spectrophotometry,Flora D. Cana for diplopic induction, and Mr G. St John Heathfor initial development work in building the pressure chamber.

References

TOP
Summary
Introduction
Materials and methods
Results
Discussion
References

Clarke, G. L. (1936). On the depth at which fish can see. Ecology 17,452 -456.

Denton, E. J. and Warren, F. J. (1956). Visual pigments of deep-sea fish. Nature 178, 1059.[Medline]

Douglas, R. H. (2001). The ecology of teleost fish visual pigments: a good example of sensory adaptation to the environment? In Ecology of Sensing (ed. F. G. Barth and A. Schmid), pp. 215-235. Berlin: Springer-Verlag.

Douglas, R. H. and Partridge, J. C. (1997). On the visual pigments of deep-sea fish. J. Fish Biol. 50, 68-85.[CrossRef]

Douglas, R. H., Partridge, J. C. and Hope, A. J. (1995). Visual and lenticular pigments in the eyes of demersal deep-sea fishes. J. Comp. Physiol. A 177,111 -122.

Douglas, R. H., Partridge, J. C. and Marshall, N. J. (1998). The Eyes of deep-sea fish I: Lens pigmentation, tapeta and visual pigments. Prog. Ret. Eye Res. 17,597 -636.[CrossRef][Medline]

Douglas, R. H., Bowmaker, J. K. and Hunt, D. M. (2003). Spectral sensitivity tuning in the deep-sea. In Sensory Processing in Aquatic Environments (ed. S. P. Collin and N. J. Marshall), pp. 323-342. Berlin: Springer-Verlag.

Govardovskii, V. I., Fyhrquist, N., Reuter, T., Kuzmin, D. G. and Donner, K. (2000). In search of the visual pigment template. Vis. Neurosci. 17,509 -528.[CrossRef][Medline]

Gross, M. and Jaenicke, R. (1994). Proteins under pressure: the influence of high hydrostatic pressure on structure, function and assembly of proteins and protein complexes. Eur. J. Biochem. 221,617 -630.[Medline]

Hart, N. S., Partridge, J. C., Bennett, A. T. D. and Cuthill, I. C. (2000). Visual pigments, cone oil droplets and ocular media in four species of estridid finch. J. Comp. Physiol. A 186,681 -694.[CrossRef][Medline]

Hayward, A. T. J. (1967). Compressibility equations for liquids: a comparative study. Br. J. Appl. Phys. 18,965 -977.[CrossRef]

Heremans, K. (1982). High pressure effects on proteins and other biomolecules. Annu. Rev. Biophys. Bioeng. 11,1 -21.[CrossRef][Medline]

Hope, A. J., Partridge, J. C., Dulai, K. S. and Hunt, D. M. (1997). Mechanisms of wavelength tuning in the rod opsins of deep-sea fishes. Proc. R. Soc. Lond. B 264,155 -163.[Medline]

Hunt, D. M., Dulai, K. S., Partridge, J. C., Cottrill, P. and Bowmaker, J. K. (2001). The molecular basis for spectral tuning of rod visual pigments in deep-sea fish. J. Exp. Biol. 204,3333 -3344.[Abstract/Free Full Text]

Klink, B. U., Winter, R., Engelhard, M. and Chizhov, I. (2002). Pressure dependence of the photocycle kinetics of bacteriorhodopsin. Biophys. J. 83,3490 -3498.[Abstract/Free Full Text]

Knowles, A. and Dartnall, H. J. A. (1977). The Photobiology of Vision. New York: Academic Press.

Lythgoe, J. N. (1979). The Ecology of Vision. Oxford: Clarendon Press.

Lythgoe, J. N. (1988). Light and vision in the aquatic environment. In Sensory Biology of Aquatic Animals (ed. J. Atema, R. R. Fay, A. N. Popper and W. N. Tavolga), pp. 57-82. Berlin: Springer-Verlag.

Mozhaev, V. V., Heremans, K., Frank, J., Masson, P. and Balny, C. (1996). High pressure effects on protein structure and function. Proteins Struct. Funct. Genet. 24, 81-91.[CrossRef][Medline]

Neuman, R. C., Kauzmann, W. and Zipp, A. (1973). Pressure dependence of weak acid ionisation in aqueous buffers. J. Phys. Chem. 77,2687 -2691.[CrossRef]

Palczewski, K., Kumasaka, T., Hori, T., Behnke, C. A., Motoshima, H., Fox, B. A., Le Trong, I., Teller, D. C., Okada, T., Stenkamp, R. E., et al. (2000). Crystal structure of rhodopsin: A G protein-coupled receptor. Science 289,739 -745.[Abstract/Free Full Text]

Partridge, J. C. and Cummings, M. E. (1999). Adaptations of visual pigments to the aquatic environment. In Adaptive Mechanisms in the Ecology of Vision (ed. S. N. Archer, M. B. A. Djamgoz, E. R. Loew, J. C. Partridge and S. Vallerga), pp.251 -284. Dortrecht: Kluwer Academic Publishers.

Partridge, J. C., Archer, S. N. and van Oostrum, J. (1992). Single and multiple visual pigments in deep-sea fishes. J. Mar. Biol. Assn. UK 72,113 -130.

Partridge, J. C., Shand, J., Archer, S. N., Lythgoe, J. N. and van Groningen-Luyben, W. A. (1989). Interspecific variations in the visual pigments of deep-sea fishes. J. Comp. Physiol. A 164,513 -529.[CrossRef][Medline]

Siebenaller, J. F. and Garrett, D. J. (2002). The effects of the deep-sea environment on transmembrane signalling. Comp. Biochem. Physiol. 131B,675 -694.[Medline]

Somero, G. N. (1992). Adaptations to high hydrostatic pressure. Annu. Rev. Physiol. 54,557 -577.[CrossRef][Medline]

Somero, G. N., Siebenaller, J. F. and Hochachka, P. W. (1983). Biochemical and physiological adaptations of deep-sea animals. In The Sea. Vol. 8, Deep-sea Biology (ed. G. T. Rowe), pp. 261-330. New York: Wiley.

Tsuda, M. (1982). Effect of pressure on visual pigment and purple membrane. Methods Enzymol. 88,714 -722.

Tsuda, M. and Ebrey, T. G. (1980). Effect of high pressure on the absorption spectrum and isomeric composition of bacteriorhodopsin. Biophys. J. 30,149 -158.[Abstract/Free Full Text]

Wald, G., Brown, P. K. and Smith, P.S. (1957). Visual pigments and depths of habit of marine fishes. Nature 180,969 -971.[CrossRef]

Yokoyama, S. (2002). Molecular evolution of color vision in vertebrates. Gene 300, 69-78.[CrossRef][Medline]

Yoshizawa, T. (1972). The behaviour of visual pigments at low temperatures. In Handbook of Sensory Physiology Vol. II. 1 Photochemistry of Vision (ed. H. J. A. Dartnall), pp. 146-179. Berlin: Springer-Verlag.

This Article

Summary

Figures Only

Full Text (PDF)

Alert me when this article is cited

Alert me if a correction is posted

Services

Email this article to a friend

Similar articles in this journal

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via Google Scholar

Google Scholar

Articles by Partridge, J. C.

Articles by Douglas, R. H.

Search for Related Content

PubMed

PubMed Citation

Articles by Partridge, J. C.

Articles by Douglas, R. H.