The chiroptical properties of proteins. II. Near-ultraviolet circular dichroism of lysozyme

A study of the near-uv CD spectrum of lysozyme was carried out in the presence and absence of the inhibitor tri-N-acetylglucosamine, and theoretical chiroptical calculations based on the tetragonal crystal structure of the enzyme and the enzyme-inhibitor complex were performed. The results of these calculations indicate that the near-uv CD spectrum of lysozyme can be adequately explained in terms of negative rotatory strengths arising from the tryptophan ¹L_a (293–300 nm) and the disulfide n-σ* bands (250 rm), and positive rotatory strength contributions from the tryptophan ¹L_b bands (291 nm) and the tyrosine ¹L_b bands (275 nm). Contributions to the rotatory strength of each band were approximated in terms of specific interactions between chromophores. It was found that the rotatory strength of most of the near-uv transitions arises primarily from coupling interactions involving other side-chain chromophores and amide groups which are in close proximity. Changes which are observed in the lysozyme CD spectrum on binding of tri-N-acetylglucosamine may be explained in terms of changes in the rotatory strength which result from interactions of the ¹L_a transitions of the active-site tryptophans with the acetamide groups of the inhibitor. The reasonable agreement which is found between the experimental and calculated rotatory strengths implies that the crystal conformation of lysozyme must resemble the solution conformation.     

Photoselection and circular dichroism in the purple membrane.

The transient dichroic ratio D = delta A parallel/delta A perpendicular has been measured in the visible absorption region of bacteriorhodopsin in purple membrane by a flash photolysis method. D is found to be wavelength independent throughout the visible absorption band, and reaches a maximum value of 2.75 +/- 0.15 on reduction of the excitation intensity. This value is close to that expected for a single nondegenerate transition dipole moment and is incompatible with the strong exciton coupling model used to explain circular dichroism (CD) spectrum of purple membrane. A time-dependent analysis of the exciton interaction and consideration of the coupling strength suggests an explanation of these observations. It is concluded that excitation interaction between retinals in purple membrane is of the weak or very weak type defined by Förster.     

CD of the Li-salt of DNA in ethanol/water mixtures: evidence for the B- to C-form transition in solution

The conformational change of Li-DNA in water/ethanol mixtures is followed by the change in the CD spectrum in solutions containing various percentages of ethanol in the range from 0 to 95%. Two main transitions can be distinguished. The first occurs in the range from 0 to 70% and is represented by a large reduction of the intensity of the positive CD band around 275 nm, which is apparently related to a small change in the number of base pairs per turn. Secondly, at higher percentages of ethanol (> 80%) a conformational change is detected, which is expressed as a reduction of the 245-nm negative CD intensity. According to x-ray diffraction experiments of fibers of Li-DNA, the C-form is attained in 95% ethanol, while at 70% ethanol a B-like structure is observed. The CD experiments reported here also show that for DNA in solution the dependence on percentage of ethanol is composed of two main transition regions. The C-form would then be adopted at high (～ 95%) ethanol percentage. The 0–70% transition, although strongly expressed in optical CD experiments, has to be related to relatively small structural changes within the B-family of DNA structures, which probably induce an enhanced contribution of n → π* transitions to the CD spectrum.     

R-phycoerythrins having two conformations for the same aggregate

The visible circular dichroism (CD) spectrum of an R-phycoerythrin (Porphyra tenera) is composed of several positive bands. The protein in aqueous buffer very slowly exhibits changes in the CD spectrum of its chromophores, a band at 489 nm undergoes an increase in intensity and a red shift. When the band reached a 493 nm maximum, the spectrum became very stable. The aggregation state of the protein did not change during this spectral conversion. The chromophore CD spectrum was also obtained in the presence of a low concentration of urea or sodium thiocyanate, and the identical change in the CD was noted, but the change was much faster. The visible absorption and CD in the far UV spectra were unaffected by urea. Unchanged visible absorption and protein secondary structure (61% alpha helix) contradicted by comparatively salient alterations in the visible CD spectra suggested very subtle structural changes are influencing some of the chromophores. For a second R-phycoerythrin (Gastroclonium coulteri), the CD of the chromophores had a negative band on the blue edge of the spectrum. This is the first negative CD band observed for any R-phycoerythrin. Treatment of this protein with low concentrations of urea produced a change in the visible CD with the negative band being completely converted to a positive band. Fluorescence studies showed that the treatment by urea did not affect energy migration. Deconvolution of the CD spectra were used to monitor the chromophores. The results demonstrated that the same aggregate of each R-phycoerythrin could exist in two conformations, and this is a novel finding for any red algal or cyanobacterial biliprotein. The two forms of each protein would differ in tertiary structure, but retain the same secondary structures.     

Synthesis of Diastereomeric Bicyclo[3.3.1]nonane Dibenzoyl Esters and Study of Their Chiroptical Properties

A synthesis of diastereomeric bicyclic dibenzoyl esters derived from enantiomerically pure (1S,5S)‐bicyclo[3.3.1]nonane‐2,6‐dione was accomplished. Molecules containing two benzoyl chromophores with different configuration in the bicyclic framework were obtained. Chiroptical properties of the synthesized enantiomerically pure molecules were studied. Diastereomeric esters exhibited exciton couplets in the circular dichroism (CD) spectra because of transannular interaction between non‐conjugated benzoate chromophores. The conformational effects and solvent impact on the exciton coupling were examined by CD spectroscopy. Theoretical computation of the CD spectra of diastereomers correctly reproduced the sign of the exciton couplets in the studied molecules, however, no major solvent dielectric constant influence and conformational effects per se on the exciton coupling was observed. Chirality 24:810–816, 2012. © 2012 Wiley Periodicals, Inc.     

DNA-templated formation and luminescence of diphenylacetylene dimeric and trimeric complexes

We report on spectral features for two and three diphenylacetylene chromophores aligned in close proximity in aqueous solution by self assembly of attached oligonucleotide arms. Two duplex systems were examined in detail. One was formed by hybridization (Watson-Crick base pairing) of two oligonucleotide 10-mers, each containing the diphenylacetylene insert. The other was generated by self-folding of a 36-mer oligonucleotide containing two diphenylacetylene inserts. The triplex system was obtained by hybridization (Hoogsteen base pairing) of a 16-mer oligonucleotide diphenylacetylene conjugate to the folded 36-mer hairpin. Formation of duplex and triplex entities from these conjugates was demonstrated experimentally by thermal dissociation and spectroscopic studies. The UV and CD spectra for the duplex systems exhibit bands in the 300-350 nm region attributable to exciton coupling between the two chromophores, and the emission spectra show a strong band centered at 410 nm assigned to excimer fluorescence. Addition of the third strand to the hairpin duplex has little effect on the CD spectrum in the 300-350 nm region, but leads to a negative band at short wavelengths characteristic of a triplex and to a strongly enhanced band at 410 nm in the fluorescence spectrum. The third strand alone shows a broad fluorescence band at approximately 345-365 nm, but this band is virtually absent in the triplex system. A model for the triplex system is proposed in which two of the three aligned diphenylacetylenes function as a ground state dimer that on excitation gives rise to the exciton coupling observed in the UV and CD spectra and to the excimer emission observed in the fluorescence spectrum. Excitation of the third chromophore results in enhanced excimer fluorescence, as a consequence of energy transfer from the locally excited singlet of one chromophore to the ground state dimer formed by the other two chromophores.     

The Absence of Non-Local Conformational Changes in OR3 Operator DNA on Complexing with the Cro Repressor

Abstract

The Interaction of the cro protein of λ phage with a synthetic OR3 operator having 17 base pairs in length and with its 9 bp fragment has been studied using the circular dichroism (CD) method. In both cases, a considerable change in the CD of the samples was found in the region 260-300 nm upon the addition of the cro protein. The stoichiometry obtained by the CD titration was identical for OR3 and its 9 bp fragment: one duplex per dimeric cro.

NaCl addition makes the complexes dissociate so that the 9 bp fragment becomes free at [NaCl]>0.2 M while the whole OR3 becomes free at [NaCl]>0.5 M.

The CD spectra of both the free duplexes show a typical B-form conservative pattern with a positive CD band (270 nm) and a negative one (250 nm). The specific complexing of both the duplexes results in a substantial CD depression in the positive band. The most pronounced effect occurs at 280 nm. This spectral change is quite distinct from those in the B to A transition and in the non-cooperative winding of the DNA within the B-family of forms.

The interaction of the cro protein with the non-operator DNAs, calf thymus DNA and a synthetic 10 bp duplex, reveals no visible CD changes at all.

An inference is drawn that the CD change in the specific complexes is mainly due to the induced CD in tyr-26 upon its interaction with a specific base pair in the operator or its fragment, the operator DNA conformation being conserved in a B-like form as a whole. However, some local distortions such as kinks cannot be ruled out on the basis of the CD data.     

The Interaction of New Pyridylporphyrins with Bovine Serum Albumin

The interaction of meso-tetra(4-N-hydroxyethylpyridyl)porphyrin, meso-tetra(3-N-hydroxyethylpyridyl)porphyrin, and their zinc complexes with bovine serum albumin (BSA) was studied by electronic spectroscopy, CD, and equilibrium dialysis at pH 7.2. The titration of the porphyrins with BSA was accompanied by a decrease in light absorption and a bathochromic shift of the Soret band, as well as by the appearance of an isobestic point. The porphyrin interaction with BSA also led to the induction of positive CD spectra in the visible region, which is explained by the porphyrin sorption on the protein globule. The equilibrium dialysis helped in determining the stoichiometry of binding and the binding constants of the porphyrins under study with BSA using Scatchard plots. This interaction is nonspecific and reversible.     

Conformation and activity ofPhaseolus coccineus var. rubronanus lectin

The conformation of native and denaturedPhaseolus coccineus var. rubronanus lectin was studied by circular dichroism (CD) and correlated to the hemagglutinating activity. The far-UV CD spectrum at 25°C showed a broad, negative band around 223 nm and a positive one at 196 nm. CD data analysis of the lectin indicated a -sheet-rich protein. At high temperatures, the spectrum was blue-shifted with increasing magnitude; these changes correlated well with the loss of the activity. The conformation of lectin betweenpH 2 and 10 remained essentially unchanged. AtpH 13 the CD spectrum resembled that of unordered form with a negative band near 200 nm and the activity was completely lost. The denatured lectin in 6 M guanidine hydrochloride would be renatured upon diluting the denaturant to 0.75 M; the changes in CD spectrum again correlated well with the loss of the activity. The effect of sodium dodecyl sulfate on the lectin was drastic; it sharply increased thea-helix at the expense of the -sheet and reduced the activity; the changes reached a plateau above 20 mM surfactant.     

Circular dichroism of halorhodopsin: comparison with bacteriorhodopsin and sensory rhodopsin I

Circular dichroic (CD) spectra of three related protein pigments from Halobacterium halobium, halorhodopsin (HR), bacteriorhodopsin (BR), and sensory rhodopsin I (SR-I), are compared. In native membranes the two light-driven ion pumps, HR and BR, exhibit bilobe circular dichroism spectra characteristic of exciton splitting in the region of retinal absorption, while the phototaxis receptor, SR-I, exhibits a single positive band centered at the SR-I absorbance maximum. This indicates specific aggregation of protein monomers of HR, as previously noted [Sugiyama, Y., & Mukohata, Y. (1984) J. Biochem. (Tokyo) 96, 413-420], similar to the well-characterized retinal/retinal exciton interaction in the purple membrane. The absence of this interaction in SR-I indicates SR-I is present in the native membrane as monomers or that interactions between the retinal chromophores are weak due to chromophore orientation or separation. Solubilization of HR and BR with nondenaturing detergents eliminates the exciton coupling, and the resulting CD spectra share similar features in all spectral regions from 250 to 700 nm. Schiff-base deprotonation of both BR and HR yields positive CD bands near 410 nm and shows similar fine structure in both pigments. Removal of detergent restores the HR native spectrum. HR differs from BR in that circular dichroic bands corresponding to both amino acid and retinal environments are much more sensitive to external salt concentration and pH. A theoretical analysis of the exciton spectra of HR and BR that provides a range of interchromophore distances and orientations is performed.(ABSTRACT TRUNCATED AT 250 WORDS)     

Tyrosine optical activity as a probe of the conformation and interactions of fibronectin

A very intense negative band is observed at ～ 183 nm in the CD spectrum of fibronectin from bovine plasma. This transition has not previously been reported, probably because it occurs in a spectral region that has not been readily accessible in earlier studies. At longer wavelength, the observed CD is very similar to spectra reported for human and chick material, having positive bands at ～230 and ～200 nm, and a negative band at ～215nm. The low molar ellipticity of the negative band ([θ] ≈ ?2.5 × 10³ deg cm² dmol^?1) suggests little α-helix or β-sheet structure. The new transition, and the two positive bands at higher wavelength, do not correspond to known transitions of the peptide backbone, but all three are present in the CD of N-acetyltyrosineamide. It is therefore suggested that the observed CD behavior of fibronectin arises predominantly from the optical activity of tyrosine side chains. The contribution of this side-chain optical activity to the CD of other proteins is discussed. On raising pH to ionize tyrosine residues, the positive CD band at ～230 nm is lost in both N-acetyltyrosineamide and in fibronectin. The spectral change is fully reversible in the model compound, but only partially reversible in fibronectin. From this evidence, and the magnitude of the 183-nm band, it is suggested that some or all of the tyrosine residues in fibronectin may be present within ordered domains. The possible role of S? S bonds in maintaining tertiary structure is discussed. The interaction of fibronectin with heparin is accompanied by a large increase in the 183-nm band and by slight enhancement of the negative band at 215 nm, consistent with some limited formation of β-sheet. Present results indicate that CD may be of considerable value in characterization of the molecular organization and biologically relevant interactions of fibronectins and of related glycoproteins of the extracellular matrix.     

DNA sequence-specific ligands: XIII. New dimeric Hoechst 33258 molecules,inhibitors of HIV-1 integrase in vitro

Dimeric Hoechst 33258 molecules [dimeric bisbenzimidazoles (DBBIs)] that, upon binding, occupy one turn of the B form of DNA in the narrow groove were constructed by computer simulation. Three fluorescent DBBIs were synthesized; they consist of two bisbenzimidazole units tail-to-tail linked to phenolic hydroxy groups via penta-or heptamethylene or tri(ethylene glycol) spacers and have terminal positively charged N,N-dimethylaminopropyl carboxamide groups in the molecule. The absorption spectra of the DBBIs in the presence of different DNA concentrations showed a hypochromic effect and a small shift of the absorption band to longer wavelengths, which indicated the formation of a complex with DNA. The presence of an isobestic point in the spectrum indicates the formation of one type of DBBI-DNA complexes. The interaction of DBBIs with DNA was studied by CD using a cholesteric liquid-crystalline dispersion (CLD) of DNA. The appearance of a positive band in the absorption region of ligand chromophores in the CD spectrum of the DNA CLD indicates the formation of a DBBI-DNA complex in which ligand chromophores are arranged at an angle close to 54° relative to the helix axis of DNA, which suggests the localization of the DBBI in the narrow groove of DNA. All the DBBIs were found to be in vitro inhibitors of HIV-1 DNA integrase in the 3′-processing reaction, and, of the three DBBIs, two dimers inhibit HIV-1 integrase even in submicromolar concentrations.     

Acetyl coenzyme A carbosylase. Circular dichroism studies of Escherichia coli biotin carboxyl carrier protein.

The biotin carboxyl carrier protein (BCCP) component of Escherichia coli acetyl coenzyme A carboxylase and three peptides derived from BCCP by proteolytic digestion have been examined by circular dichroism spectroscopy. BCCP, which has a peptide molecular weight of 22,500, has a spectrum typical of globular proteins with negative extrema at 222 nm and 208 nm. The two smallest peptides, BCCP(SC) and BCCP(9,100), with molecular weights of 8,900 and 9,100, respectively, exhibit unusual positive CD bands centered at 237 nm and 220 nm. BCCP(10,400), with a molecular weight of 10,400, has a CD spectrum intermediate between BCCP and that of the smallest peptides. Since d-biotin exhibits a positive CD band at 233 nm, it was suspected that the biotin prosthetic group might be the chromophore responsible for the 237 nm CD band seen in BCCP(SC) and BCCP(9,100). Enzymatic carboxylation of BCCP(SC) to form CO2-BCCP(SC) caused the CD spectrum to change with a shift of the 237 nm band to 232 nm. The positive CD band at 220 nm was unaffected by carboxylation of the biotin prosthetic group. These date suggest that the 237 nm signal may be due either to the biotin which acts as a chromophore directly or to a chromophore that is perturbed by the carboxylation of biotin. A spectropolarimetric titration was carried out to investigate the possible contribution of the single tyrosine residue of BCCP(SC) to the CD spectrum of this peptide. At pH values over 9 the CD spetrum changed with the disappearance of the 237 nm band, suggesting that tyrosine might contribute to this CD band. Denaturation of BCCP(SC) or BCCP(9,100) with 8 M urea of 6 M guanidine HCl abolished the positive CD bands and resulted in spectra typical of a random coil, whereas treatment of BCCP(SC) with 1% sodium dodecyl sulfate abolished the positive bands and left a spectrum exhibiting a shoulder at 222 nm and a negative band at 205 nm, suggestive of a high degree of ordered structure. It is concluded that the CD band at 237 nm in BCCP(SC) and BCCP(9,100) is prabably due to a noncovalent interaction of biotin with an amino acid residue(s) of the protein. It is suggested that the biotin prosthetic group is partially buried in the surface of the protein, rather than swinging free at the end of the lysine side chain through which it is covalently linked to the protein, to permit this interaction to occur.     

Spectroscopic studies on the structural organization of the lectin discoidin I: homologies with fibronectin

The structure of the lectin discoidin I has been studied by circular dichroism and fluorescence spectroscopy. A positive ellipticity band at 224 nm is detected in the CD spectrum of discoidin I. The fluorescence spectra show a defined shoulder at 325 nm that through acrylamide quenching has been associated with a displaced tryptophan residue partly buried in the discoidin I molecule. This tryptophan could also be responsible for the 224 nm positive band of the CD spectrum. These spectroscopic characteristics of discoidin I indicate the existence of structural homologies with fibronectin, where the optical activity of aromatic chromophores has been associated with the positive ellipticity band at 227 nm. The CD adjust parameters and theoretical secondary structure predictions show that discoidin I is a molecule with a low content of α-helix and β-strand and high content of β-turn structures, similar to other lectins.     

Interpretation of the absorption and circular dichroic spectra of oriented purple membrane films.

The absorption and circular dichroic (CD) spectra of purple membrane films in which the plane of the membranes is oriented perpendicular to the incident beam are compared with the solution spectra. This enables one to relate structural features of the purple membrane to a coordinate system as defined by a normal to the membrane plane and two mutually perpendicular in-plane axes. The film and solution absorption spectra were similar except for a relative depression in the 200 - 225-nm region of the film spectrum. However, the CD spectra showed significant differences in the visible region, where the biphasic band in the solution spectrum was replaced by a single positive band at 555 nm in the film spectrum and in the far ultraviolet region, where the 208-nm band was deleted from the film spectra of the native and regenerated membranes. Moreover, a small shoulder occurred at 208 nm in the film spectrum of the bleached membrane. The near ultraviolet spectra also showed differences, whereas the 317-nm band remained essentially the same for both spectra. Based on excitonic interpretations of the visible and far ultraviolet spectra the following conclusions were reached: (a) a relatively strong in-plane monomeric interaction occurs between te retinyl chromophore and apoprotein; (b) the helical axes of the native and regenerated membrane proteins are oriented primarily normal to the membrane plane; and (c) the helical axes of the bleached membrane proteins are tilted more in-plane than the axes of the native or regenerated membrane. Additional conclusions were that an interaction occurs between an in-plane magnetic dipole moment of the retinyl chromophore and probably an in-plane electric dipole moment of a nearby aromatic amino acid(s), and that although the membrane is anisotropic with respect to coupling between electric and magnetic moments of the aromatic amino acids, the transition dipole moments of the aromatic amino acids are not preferentially oriented in either direction.     

Localization of hydrogenase in the purple sulphur bacterium Thiocapsa roseopersicina

The localization of hydrogenase in the phototrophic bacterium Thiocapsa roseopersicina was investigated by subcellular fractionations, and transmission electron microscopic immunocytochemistry. By using sonicated cells and measuring in vitro hydrogenase activities in soluble and membrane fractions, respectively, a weak hydrophobic interaction between the hydrogenase enzyme and the T. roseopersicina membranes was observed. Polyclonal antisera directed against the purified hydrogenase were raised in rabbits and exhibited one band in native-PAGE/Western immunoblot analysis. Native-PAGE/activity stain confirmed the identity of this band as being hydrogenase. Immunocytolocalization experiments using ultrathin sections showed an internal localization of the hydrogenase enzyme. A higher specific labeling was associated with chromatophores, indicating a possible coupling of hydrogenase with the photosynthetic membranes in the T. roseopersicina cells.     

Interaction of thiourea with band 3 in human red cell membranes

Summary Although urea transport across the human red cell membrane has been studied extensively, there is disagreement as to whether urea and water permeate the red cell by the same channel. We have suggested that the red cell anion transport protein, band 3, is responsible for both water and urea transport. Thiourea inhibits urea transport and also modulates the normal inhibition of water transport produced by the sulfhydryl reagent,pCMBS. In view of these interactions, we have looked for independent evidence of interaction between thiourea and band 3. Since the fluorescent stilbene anion transport inhibitor, DBDS, increases its fluorescence by two orders of magnitude when bound to band 3 we have used this fluorescence enhancement to study thiourea/band 3 interactions. Our experiments have shown that there is a thiourea binding site on band 3 and we have determined the kinetic and equilibrium constants describing this interaction. Furthermore,pCMBS has been found to modulate the thiourea/band 3 interaction and we have determined the kinetic and equilibrium constants of the interaction in the presence ofpCMBS. These experiments indicate that there is an operational complex which transmits conformational signals among the thiourea,pCMBS and DBDS sites. This finding is consistent with the view that a single protein or protein complex is responsible for all the red cell transport functions in which urea is involved.     

Orientations of the retinyl and the heme chromophores in the brown membrane of Halobacterium halobium

The orientations of the retinyl and heme chromophores of bacteriorhodopsin and cytochrome b-561 of the brown membrane of Halobacterium halobium have been determined by linear dichroic spectroscopy of oriented brown membrane films. Both chromophores exhibit cylindrical symmetry with respect to the membrane normal. However, the retinyl transition dipole moment is polarized at an angle of 20 to 24 ° with respect to the plane of the membrane while the plane of the heme is oriented nearly perpendicular to the membrane plane. Therefore, the orientation of retinal bound to bacterio-opsin in the brown membrane is approximately the same as in the purple membrane. This is supportive of our previous conclusions that the fine structures of the bacteriorhodopsins of these membranes are very similar in spite of differences in the composition and structure of the two membranes. The orientation of the heme plane of the membrane-bound cytochrome b-561 is very similar to orientations of several membrane-bound heme proteins that are involved in electron transfer processes and may be suggestive of its function in the brown membrane. Analysis of the linear dichroic spectrum over the entire bacteriorhodopsin band using an exciton formalism is in accord with the energy separation of the in-plane and out-of-plane excitonic transitions being less than 5 nm. Since a similar energy separation was reported for the purple membrane, the relative positions of the retinals must be approximately the same in both membranes. A similar analysis of the Soret region, based on the existence of two degenerate mutually perpendicular porphyrin transitions, indicates that the energy separation should be from 5 to 20 nm. However, the smaller value is unlikely for it would imply very large circular dichroic bands not yet encountered in any heme proteins.     

Origin of the 701-nm fluorescence emission of the Lhca2 subunit of higher plant photosystem I

Photosystem I of higher plants is characterized by red-shifted spectral forms deriving from chlorophyll chromophores. Each of the four Lhca1 to -4 subunits exhibits a specific fluorescence emission spectrum, peaking at 688, 701, 725, and 733 nm, respectively. Recent analysis revealed the role of chlorophyll-chlorophyll interactions of the red forms in Lhca3 and Lhca4, whereas the basis for the fluorescence emission at 701 nm in Lhca2 is not yet clear. We report a detailed characterization of the Lhca2 subunit using molecular biology, biochemistry, and spectroscopy and show that the 701-nm emission form originates from a broad absorption band at 690 nm. Spectroscopy on recombinant mutant proteins assesses that this band represents the low energy form of an excitonic interaction involving two chlorophyll a molecules bound to sites A5 and B5, the same protein domains previously identified for Lhca3 and Lhca4. The resulting emission is, however, substantially shifted to higher energies. These results are discussed on the basis of the structural information that recently became available from x-ray crystallography (Ben Shem, A., Frolow, F., and Nelson, N. (2003) Nature 426, 630-635). We suggest that, within the Lhca subfamily, spectroscopic properties of chromophores are modulated by the strength of the excitonic coupling between the chromophores A5 and B5, thus yielding fluorescence emission spanning a large wavelength interval. It is concluded that the interchromophore distance rather than the transition energy of the individual chromophores or the orientation of transition vectors represents the critical factor in determining the excitonic coupling in Lhca pigment-protein complexes.     

Circular dichroism studies on α- and β-ketosides of 5-acetamido-3,5-dideoxy- -glycero- -galacto-nonulopyranosonic acid (N-acetylneuraminic acid) and of some of its derivatives

The circular dichroism spectra of a number of N-acetylneuraminic acid derivatives in aqueous solution were studied. For all compounds, the Cotton effects were found to be in the spectral range of the acetamido and carboxyl chromophores. The c.d. curves of the methyl, ethyl, and allyl α- -ketosides are characterized by a broad, positive band centered at λ ≈ 195 nm with a slight skew towards the higher wavelengths and weak bands between λ 225 and 255 nm, whereas the methyl β- -ketoside and the corresponding methyl ester show only an intense positive band with a broad shoulder in the same spectral range. 5-Acetamido-3,5-dideoxy- -glycero-β- -galacto-nonulopyranose, its methyl β- -ketoside, and 5-acetamido-3,5-dideoxy- -glycero- -galacto-nonulopyranosonamide containing only the acetamido chromophore showed one single positive Cotton effect centered at λ ≈ 192 nm. The c.d. spectrum of 5-acetamido-3,5-dideoxy- -glycero- -galacto-nonulopyranosonic acid confirms the β- configuration of the free acid in aqueous solution, whereas the shape of the c.d. curve of O-(N-acetyl-α- -neuraminopyranosyl)-(2→3)-O-β- -galactopyranosyl-(1→4)- -glucopyranose resembles that of the methyl, ethyl, and allyl α- -ketosides 2-4.