Circular dichroism of squid rhodopsin and its intermediates

Circular dichroism (CD) and absorption spectra of squid (Todarodes pacificus) rhodopsin, isorhodopsin and the intermediates were measured at low temperatures. Squid rhodopsin has positive CD bands at wavelengths corresponding the - and β-absorption bands at liquid nitrogen temperature (CD maxima: 485 nm at -band and 348 nm at β-band) as well as at room temperature (CD maxima: 474 nm at -band and 347 nm at β-band). The rotational strength of the -band has a molecular ellipticity about twice that of cattle rhodopsin. The CD spectrum of bathorhodopsin displays a negative peak at 532 nm, the rotational strength of which has an absolute value slightly larger than that of rhodopsin. The reversal in sign at -band of the CD spectrum may indicate that the isomerization of retinal chromophore from twisted 11-cis form to twisted 11-trans form has occurred in the process of conversion from rhodopsin to bathorhodopsin. Lumirhodopsin has a small negative CD band at 490 nm, the maximum of which lies at 25 nm shorter wavelengths than the absorption maximum (515 nm), and a large positive CD band near 290 nm, which is not observed in rhodopsin and the other intermediates. This band may be derived from a conformational change of the opsin. In the process of changing from lumirhodopsin to LM-rhodopsin, the CD bands at visible and near ultraviolet regions disappear. Both alkaline and acid metarhodopsins have no CD bands at visible and near ultraviolet regions.     

A.U and G.C base pairs in synthetic RNAS have characteristic vacuum UV CD bands.

The vacuum UV CD spectra of GpC, CpG, GpG, poly[r(A)], poly[r(C)], poly[r(U)], poly[r(A-U)], poly[r(G).r(C)], poly[r(A).r(U)], and poly[r(A-U).r(A-U)] were measured down to at least 174 nm. These spectra, together with the published spectra of poly[r(G-C).r(G-C)], CMP, and GMP, were sufficient to estimate the CD changes upon base pairing for four double-stranded RNAs. The vacuum UV CD bands of poly[r(A)], poly[r(C)], and the dinucleotides GpC and CpG were temperature dependent, suggesting that they were due to intrastrand base stacking. The dinucleotide sequence isomers GpC and CpG had very different vacuum UV CD bands, indicating that the sequence can play a role in the vacuum UV CD of single-stranded RNA. The vacuum UV CD bands of the double-stranded (G.C)-containing RNAs, poly[r(G).r(C)] and poly[r(G-C).r(G-C)], were larger than the measured or estimated vacuum UV CD bands of their constituent single-stranded RNAs and were similar in having an exceptionally large positive band at about 185 nm and negative bands near 176 and 209 nm. These similarities were enhanced in difference-CD spectra, obtained by subtracting the CD spectra of the single strands from the CD spectra of the corresponding double strands. The (A.U)-containing double-stranded RNAs poly[r(A).r(U)] and poly[r(A-U).r(A-U)] were similar only in that their vacuum UV CD spectra had a large positive band at 177 nm. The spectrum of poly[r(A).r(U)] had a shoulder at 188 nm and a negative band at 206 nm, whereas the spectrum of poly[r(A-U).r(A-U)] had a positive band at 201 nm. On the other hand, difference spectra of both of the (A.U)-containing polymers had positive bands at about 177 and 201 nm. Thus, the difference-CD spectra revealed CD bands characteristic of A.U and G.C base pairing. (ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Circular dichroism and conformational properties of modeccin,a toxic protein

According to its circular dichroism (CD) spectrum, modeccin, a toxic lectin from the roots of the South African plantModecca digitata, is structurally similar to the ricins and abrins. In nearly neutral and weakly alkaline solutions (pH 7.6–9.0) the CD spectra of modeccin displayed a positive CD band at 190–195 nm and a negative band at 210–220 nm, indicating the presence of some α-helix and β-sheet structures. In the near-ultraviolet zone, we observed positive CD bands at 232 and 245 nm and weak negative bands at 285 and 293 nm. In more strongly alkaline solutions of pH 9.5–10.2 the CD bands in the farultraviolet zone were not affected, but the CD band at 232 nm diminished and the CD band at 245 nm was enhanced. These transitions were reversible. At pH 11.2–11.5 the CD band at 232 nm disappeared completely, and the CD bands in the far-ultraviolet diminished. The CD bands at 285 and 293 nm were affected very little by the alkali, and these bands were assigned to buried tryptophan side chains. Sodium dodecyl sulfate and 2,2,2-trifluoroethanol disorganized the tertiary structure of modeccin and reconstructed the secondary structure into a new form with a higher helix content than in the native protein.     

高粱叶片磷酸烯醇式丙酮酸羧化酶溶液构象状态的紫外差示吸收光谱研究

PEP诱导产生的差光谱在237nm是一强负峰,在252nm附近呈宽负峰。Mg~(2+)产生的差光谱在275nm附近为正的阔峰,在237nm处为一负峰。PEP、Mg~(2+)共同与酶作用的差光谱在263nm附近呈宽的负峰。正效应剂G6P、Gly及GG分别存在条件下PEP羧化酶的差光谱亦各具明显差异,在270nm以下光区内尤其显著。在284nm和291nm为两个负峰,Gly诱导的峰强度大于G6P的,而GG复合效应剂对此两峰的影响表现很大的协同作用。Mal作用于酶的差光谱在246nm处有一负峰。     

Biotinylation in the hyperthermophile Aquifex aeolicus.

Biotin protein ligase (BPL) catalyses the biotinylation of the biotin carboxyl carrier protein (BCCP) subunit of acetyl CoA carboxylase and this post-translational modification of a single lysine residue is exceptionally specific. The exact details of the protein-protein interactions involved are unclear as a BPL:BCCP complex has not yet been isolated. Moreover, detailed information is lacking on the composition, biosynthesis and role of fatty acids in hyperthermophilic organisms. We have cloned, overexpressed and purified recombinant BPL and the biotinyl domain of BCCP (BCCP Delta 67) from the extreme hyperthermophile Aquifex aeolicus. In vitro assays have demonstrated that BPL catalyses biotinylation of lysine 117 on BCCP Delta 67 at temperatures of up to 70 degrees C. Limited proteolysis of BPL with trypsin and chymotrypsin revealed a single protease-sensitive site located 44 residues from the N-terminus. This site is adjacent to the predicted substrate-binding site and proteolysis of BPL is significantly reduced in the presence of MgATP and biotin. Chemical crosslinking with 1-ethyl-3-(dimethylamino-propyl)-carbodiimide (EDC) allowed the isolation of a BPL:apo-BCCP Delta 67 complex. Furthermore, this complex was also formed between BPL and a BCCP Delta 67 mutant lacking the lysine residue (BCCP Delta 67 K117L) however, complex formation was considerably reduced using holo-BCCP Delta 67. These observations provide evidence that addition of the biotin prosthetic group reduces the ability of BCCP Delta 67 to heterodimerize with BPL, and emphasizes that a network of interactions between residues on both proteins mediates protein recognition.     

Use of circular dichroism to study the interaction of carboxypeptidase A with substrates and inhibitors

The phenylalanyl circular dichroism (CD) bands of peptides were used to assay peptidase activity of carboxypeptidase A (EC.3.4.12.2.). Hippuryl-L-phenylalanine has a sharp, negative CD band at 254 nm whilst L-phenylalanine (the optically active product) has positive CD. Thus the hydrolysis of this substrate as well as the inhibition effect of dipeptides, may be measured from the CD change at 254 nm. The addition of the dipeptide GLy-Tyr to carboxypeptidase A makes the CD spectrum more positive in the region from 270-295 nm. This alteration can result from the tyrosyl and tryptophanyl CD bands of the protein as well as from the tyrosyl CD band of the inhibitor.     

The C-terminal domain of biotin protein ligase from E. coli is required for catalytic activity

Biotin protein ligase of Escherichia coli, the BirA protein, catalyses the covalent attachment of the biotin prosthetic group to a specific lysine of the biotin carboxyl carrier protein (BCCP) subunit of acetyl-CoA carboxylase. BirA also functions to repress the biotin biosynthetic operon and synthesizes its own corepressor, biotinyl-5'-AMP, the catalytic intermediate in the biotinylation reaction. We have previously identified two charge substitution mutants in BCCP, E119K, and E147K that are poorly biotinylated by BirA. Here we used site-directed mutagenesis to investigate residues in BirA that may interact with E119 or E147 in BCCP. None of the complementary charge substitution mutations at selected residues in BirA restored activity to wild-type levels when assayed with our BCCP mutant substrates. However, a BirA variant, in which K277 of the C-terminal domain was substituted with Glu, had significantly higher activity with E119K BCCP than did wild-type BirA. No function has been identified previously for the BirA C-terminal domain, which is distinct from the central domain thought to contain the ATP binding site and is known to contain the biotin binding site. Kinetic analysis of several purified mutant enzymes indicated that a single amino acid substitution within the C-terminal domain (R317E) and located some distance from the presumptive ATP binding site resulted in a 25-fold decrease in the affinity for ATP. Our data indicate that the C-terminal domain of BirA is essential for the catalytic activity of the enzyme and contributes to the interaction with ATP and the protein substrate, the BCCP biotin domain.     

Induced circular dichroism of eosin-5-maleimide bound to band 3 of human erythrocytes.

The inhibition of anion exchange in human erythrocyte membrane by eosin-5-maleimide (EMI) was examined at various pH values. At the pH region between pH 6.0 and 8.0, EMI inhibited the sulfate efflux by about 90%. Further, the interaction of EMI molecules with erythrocyte ghosts was studied by induced circular dichroism (CD). At acidic pH, the EMI-ghost system showed a positive band at about 552 nm and negative bands at about 523 and 505 nm. When the ghosts had been preincubated with N-ethylmaleimide, which is a modifying reagent for cysteine residues, the intensity of the CD bands was decreased. On the other hand, when the ghosts had been preincubated with 4,4'-diisothiocyanostilbene-2,2'-disulfonate or eosin-5-isothiocyanate, which inhibit the anion exchange by binding to membrane from outside of the cell, EMI CD was not influenced. These results and the experiment of trypsin digestion, suggested that the induced CD originated from the complexation of EMI molecules with SH groups on band 3 protein. A conventional Gaussian analysis of the CD spectrum at pH 6.0 revealed that the CD spectrum was composed of three components; one of them may be from EMI monomers bound to a cryptic SH group on the 17K fragment and two of them were coupling-type CD bands originating from EMI dimer and/or trimer. The EMI dimer and trimer, which should be located predominantly on the cytoplasmic SH groups on the 43K fragment, were considered as 'stacking' and/or 'head to tail' arrangements. At pH 7.4, the CD spectrum originating from EMI monomers, which showed a negative band at about 560 nm and a positive band at about 535 nm, could be observed.     

A unique biotin carboxyl carrier protein in archaeon Sulfolobus tokodaii

Biotin carboxyl carrier protein (BCCP) is one subunit or domain of biotin-dependent enzymes. BCCP becomes an active substrate for carboxylation and carboxyl transfer, after biotinylation of its canonical lysine residue by biotin protein ligase (BPL). BCCP carries a characteristic local sequence surrounding the canonical lysine residue, typically -M-K-M-. Archaeon Sulfolobus tokodaii is unique in that its BCCP has serine replaced for the methionine C-terminal to the lysine. This BCCP is biotinylated by its own BPL, but not by Escherichia coli BPL. Likewise, E. coli BCCP is not biotinylated by S. tokodaii BPL, indicating that the substrate specificity is different between the two organisms.     

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.     

Circular dichroism and saccharide-induced conformational transitions of lectins from Ricinus communis.

Conformational studies on lectins from castor beans (Ricinus communis), RCA_I and RCA_II, were performed by using circular dichroism (CD). The CD spectra were similar showing several negative bands at 270–320 nm, a positive region at 230–250 nm, several negative bands at 205–225 nm, and a positive peak at about 195 nm. However, significant differences were observed in the band strength between RCA_I and RCA_II. Lactose, melibiose, and d-fucose induced marked Conformational alterations in RCA_I, whereas weaker effects were produced by d-galactose and l-rhamnose. Saccharide-induced conformational alterations were weaker in RCA_II than in RCA_I, with only lactose and melibiose inducing significant alterations. d-Glucose and 2-acetamido-2-deoxy-d-glucose, which do not inhibit hemagglutination by RCA_I or RCA_II, did not influence lectin conformation. Acetylation of tyrosyl groups with N-acetylimidazole produced changes in the CD bands in the near uv indicating involvement of tyrosine residues. The saccharide effect was most pronounced at 285 nm, a band that was assigned to a tyrosine chromophore. Analysis of the CD bands in the far-uv zone indicated the presence of approximately 50% pleated sheet (β) structure, and 13–15% α-helix in both RCA_I and RCA_II. According to the CD results, the polypeptide chain backbone in the lectins was not affected by the saccharides, whereas significant disorganization occurred in 7 m guanidine-HCl.     

Single‐particle analysis of urea amidolyase reveals its molecular mechanism

Urea amidolyase (UA), a bifunctional enzyme that is widely distributed in bacteria, fungi, algae, and plants, plays a pivotal role in the recycling of nitrogen in the biosphere. Its substrate urea is ultimately converted to ammonium, via successive catalysis at the C‐terminal urea carboxylase (UC) domain and followed by the N‐terminal allophanate hydrolyse (AH) domain. Although our previous studies have shown that Kluyveromyces lactis UA (KlUA) functions efficiently as a homodimer, the architecture of the full‐length enzyme remains unresolved. Thus how the biotin carboxyl carrier protein (BCCP) domain is transferred within the UC domain remains unclear. Here we report the structures of full‐length KlUA in its homodimer form in three different functional states by negatively‐stained single‐particle electron microscopy. We report here that the ADP‐bound structure with or without urea shows two possible locations of BCCP with preferred asymmetry, and that when BCCP is attached to the carboxyl transferase domain of one monomer, it is attached to the biotin carboxylase domain in the second domain. Based on this observation, we propose a BCCP‐swinging model for biotin‐dependent carboxylation mechanism of this enzyme.     

Chiral discrimination of 5,6-epoxy-3-dehydroretinal by aporetinochrome and cattle opsin

The combination of a racemic all-trans 5,6-epoxy-3-dehydroretinal (EDR) with aporetinochrome formed a mixture of two diastereomeric pigments. One of the diastereomeric pigments which contained the all-trans EDR with a negative circular dichroic (CD) band, hereafter called EDR(-)-chrome, has its visible absorption maximum around 438 nm, while the other pigment, called EDR(+)-chrome, has its maximum at 464 nm. These were substantiated by measuring the optical activities of the two EDR isomers which were extracted from a mixture of racemic all-trans EDR and a smaller amount of aporetinochrome following exposure to orange light (greater than 530 nm) that irradiates EDR(+)-chrome selectively. The extracted all-trans EDR had a negative CD band around 240 nm and the extracted 11-cis EDR had a positive band in that region with two negative bands on either side of the main band. In the case of both pigments, the effect of alkalinization on the increase of absorbance in the near-ultraviolet and the decrease of absorbance in the visible region was proportionate, qualitatively, to that on the positive CD intensities in both regions. These results suggest that the chromophore EDR in each pigment binds to the same binding site via a Schiff base. The EDR(+)-chrome exhibited properties similar to those of retinochrome, but EDR(-)-chrome showed some different properties, i.e. its formation rate was slower than that of the former one and its absorption band in the near-ultraviolet appeared even at neutral pH. Moreover, by exposing EDR(-)-chrome to yellow light (greater than 480 nm), only a part of its prosthetic all-trans EDR was isomerized and resulted in the formation of 11-cis and 13-cis isomers. This variation in photoisomerizing activity was supposed to be due to the difference in conformation of the side chain between EDR(+) and EDR(-) in aporetinochrome. Combination of 11-cis EDR with cattle opsin was also shown to result in the formation of two diastereomeric pigments. The absorption maxima of the diastereomers containing 11-cis EDR(+) and EDR(-) were at about 446 and 474 nm, respectively.     

Bacteriochlorophyll a-types in chromatophore and subchromatophore preparations from Rhodopseudomonas sphaeroides.

Comparison of absorption and circular dichroism (CD) spectra in the near infrared region was made with chromatophore and subchromatophore preparations obtained from Rhodopseudomonas sphaeroides. The 850 nm absorption band had a positive correlation with the 850 nm and 870 nm CD bands. The 800 nm and 870 nm absorption bands seemed not to correlate with any CD bands. Lipid contents in chromatophores and subchromatophores were measured. Lipids in membranes seemed to contribute to the appearance of the 870 nm absorption band, but not to that of the 800 nm and 850 nm absorption bands. The time courses of absorbance changes were compared at 800, 850, and 870 nm in detergent-treated chromatophores. Relative changes of absorbances differed from one another. The present results suggest that the three absorption bands are due to three different bacteriochlorophyll a-types and the 850 nm absorption band originates from exciton-coupling of bacteriochlorophyll a.     

Circular dichroism microscopy of compact forms of DNA and chromatin in vivo and in vitro: cholesteric liquid-crystalline phases of DNA and single dinoflagellate nuclei

Two highly condensed structures of DNA have been analyzed in the circular dichroism (CD) microscope: the cholesteric liquid-crystalline phase of DNA and the nucleus of a dinoflagellate (Prorocentrum micans). In both cases, the DNA shows a helical cholesteric organization, but the helical pitch equals about 2500 nm in the first case and 250 nm in the second one. Since the absorption band of DNA is located at 260 nm, the reflection and absorption bands are well separated in the cholesteric phase of DNA and are overlapping in the dinoflagellate nucleus. However, both structures give a very strong negative CD signal at 265 nm. We show that this very strong signal cannot correspond to a Borrmann effect, i.e., to a superposition of the absorption and reflection bands, but is a differential absorption of left versus right circularly polarized light. This anomalous differential absorption is probably due to a significant scattering of light, inside of the structure, which produces a resonance phenomenon in the absorption band of the chromophore. Therefore, for any helical structure containing a chromophore, the apparent CD can be expressed as CD = [(epsilon L - epsilon R)cl] + (psi L - psi R) + (SL - SR) The first term is true absorption and is located in the absorption band of the chromophore, and the last term is true scattering and is observed at the wavelength corresponding to the helical pitch of the structure. The second term (psi L - psi R) corresponds to the anomalous differential absorption observed in dense superhelical structures of DNA. It superimposes to the first term in the absorption band of the chromophore. psi L - psi R is a measure of the perfection of the helical structure and of the density of chromophores in the material. Intercalative dyes [ethidium bromide and meso-tetrakis(4-N-methylpyridyl)porphine (H2TMpyP-4) and its nickel(II) derivative (NiIITMpyP-4)] were inserted in the dinoflagellate chromatin. The CD signal recorded in their absorption band mimics the signal observed in the absorption band of DNA. In both structures, the negative sign of the CD at 265 nm indicates that the twist occurring between DNA. In both structures, the negative sign of the CD at 265 nm indicates that the twist occurring between DNA molecules is left-handed, and we show that this situation is the most frequently encountered in vivo and vitro.     

The gene encoding the biotin carboxylase subunit of Escherichia coli acetyl-CoA carboxylase.

We report the molecular cloning and DNA sequence of the gene encoding the biotin carboxylase subunit of Escherichia coli acetyl-CoA carboxylase. The biotin carboxylase gene encodes a protein of 449 residues that is strikingly similar to amino-terminal segments of two biotin-dependent carboxylase proteins, yeast pyruvate carboxylase and the alpha-subunit of rat propionyl-CoA carboxylase. The deduced biotin carboxylase sequence contains a consensus ATP binding site and a cysteine-containing sequence preserved in all sequenced bicarbonate-dependent biotin carboxylases that may play a key catalytic role. The gene encoding the biotin carboxyl carrier protein (BCCP) subunit of acetyl-CoA carboxylase is located upstream of the biotin carboxylase gene and the two genes are cotranscribed. As previously reported by others, the BCCP sequence encoded a protein of 16,688 molecular mass. However, this value is much smaller than that (22,500 daltons) obtained by analysis of the protein. Amino-terminal amino acid sequencing of the purified BCCP protein confirmed the deduced amino acid sequence indicating that BCCP is a protein of atypical physical properties. Northern and primer extension analyses demonstrate that BCCP and biotin carboxylase are transcribed as a single mRNA species that contains an unusually long untranslated leader preceding the BCCP gene. We have also determined the mutational alteration in a previously isolated acetyl-CoA carboxylase (fabE) mutant and show the lesion maps within the BCCP gene and results in a BCCP species defective in acceptance of biotin. Translational fusions of the carboxyl-terminal 110 or 84 (but not 76) amino acids of BCCP to beta-galactosidase resulted in biotinated beta-galactosidase molecules and production of one such fusion was shown to result in derepression of the biotin biosynthetic operon.     

Circular dichroism studies on alpha- and beta-ketosides of 5-acetamido-3,5-dideoxy-D-glycero-D-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 methy, ethyl, and allyl alpha-D-ketosides are characterized by a broad, positive band centered at lambda similar to 195 nm with a slight skew towards the higher wavelengths and weak bands between lambda 225 and 255 nm, whereas the methyl beta-D-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-D-glycero-beta-D-galacto-nonulopyranose, its methyl beta-D-ketoside, and 5-acetamido-3,5-dideoxy-D-glycero-D-galacto-nonulopyranosonamide containing only the acetamido chromophore showed one single positive Cotton effect centered at lambda similar to 192 nm. The c.d. spectrum of 5-acetamido-3,5-dideoxy-D-glycero-D-galacto-nonulopyranosonic acid confirms the beta-D configuration of the free acid in aqueous solution, whereas the shape of the c.d. curve of O-(N-acetyl-alpha-D-neuraminopyranosyl)-(2yields3)-O-beta-D-galactopyranosyl-(1 yields 4)-D-glucopyranose resembles that of the methyl, ethyl, and allyl alpha-D-ketosides 2-4.     

Circular dichroism of human pituitary luteinizing hormone and its glycopeptides. Curve resolution and band assignments to the peptide chromophore, aromatic residues, disulfides, and N-acetylated amino sugars.

The circular dichroic (CS) spectrum of the glycoprotein hormone, human pituitary luteinizing hormone (hLH), has been determined between 195-320 nm and resolved into gaussian constituents. Below 230 nm the CD spectrum is characterized by a negative extremum at 207 nm with a shoulder at 217 nm. Resolution into gaussian constituents of the 200-230 nm CD spectrum resulted in two resolved negative bands, one at 206 nm and the other at 215 nm. The latter band is assigned to beta-structure which is estimated to be about 25%. The 206 nm resolved band is assigned to the N-acetylated carbohydrate groups (e.g. N-acetyl glucosamine, galactosamine, and neuraminic acid). This is based partly on the evidence that the CD spectrum of the hLH glycopeptide fraction (prepared by a pronase digestion of s-carboxymethylated hLH) exhibited a negative extremum at 207.5 nm, which is close to the resolved 206 nm band in hLH. Above 230 nm the CD spectrum is characterized by a negative extremum at about 275 nm. Most of the ellipticity in this region is attributed to the disulfides in hLH. Both strong acid (0.1 N hcl) and concentrated guanidine hydrochloride (4 M) affect the ellipticity in the vicinity of 275 nm, but only the latter (as well as concentrated urea) has a major effect on the CD spectrum below 230 nm indicating extensive conformational changes. There is, however, some loss of beta-structure in 0.1 N hcl. Thus, it appears that the conformation of the hLH subunits in these subunit-dissociating agents is rather different. There was no dramatic change in the magnitude of the 207 nm extremum of native hLH between 10-50C.     

Individual tyrosine side-chain contributions to circular dichroism of ribonuclease

Experimental and theoretical studies using site-directed mutants of ribonuclease A (RNase A) offer more extensive information on the tyrosine side-chain contributions to the circular dichroism (CD) of the enzyme. Bovine pancreatic RNase A has three exposed tyrosine residues (Tyr73, Tyr76, and Tyr115) and three buried tyrosine residues (Tyr25, Tyr92 and Tyr97). The difference CD spectra between the wild type and the mutants at pH 7.0 (Deltaepsilon(277,wt) - Deltaepsilon(277,mut)) show bands with more negative DeltaDeltaepsilon(277) values for Y73F and Y115F than those for Y25F and Y92F and bands with positive DeltaDeltaepsilon(277) values for Y76F and Y97F. The theoretical calculations are in good semiquantitative agreement for all the mutants. The pH difference spectrum (pH 11.3-7.0) for the wild type shows a negative band at 295 nm and an enhanced positive band at 245 nm. The three mutants at buried tyrosine sites and one mutant at an exposed tyrosine site (Y76F) exhibit pH-difference spectra that are similar to that of the wild type. In contrast, two mutants at exposed tyrosine sites (Y73F and Y115F) exhibit diminished 295-nm negative bands and, instead of positive bands at 245 nm, negative bands are observed. Our results indicate that Tyr73 and Tyr115, two of the exposed tyrosine residues, are the largest contributors to the 277- and 245-nm CD bands of RNaseA, but the buried tyrosine residues and the one remaining exposed residue also contribute to these bands. Disulfide contributions to the 277- and 240-nm bands and the peptide contribution to the 240-nm band are confirmed theoretically.