Dihydrothymine lesion in X-irradiated DNA: characterization at the molecular level and detection in cells

PURPOSE

To study the formation of the dihydrothymine lesion produced in DNA by ionizing radiation in an anaerobic environment.

MATERIALS AND METHODS

The dihydrothymine lesion, along with other lesions, was isolated from an X-irradiated aqueous solution of the dinucleoside monophosphate d(TpA) and analysed by correlated two-dimensional nuclear magnetic resonance spectroscopy. The dihydrothymine lesion was obtained by enzymatic digestion of irradiated DNA in the form of modified dinucleoside monophosphates, d(T(d)A), where T(d) stands for dihydrothymidine. Liquid chromatography-tandem mass spectrometry was used to detect the lesion in the DNA of X-irradiated mouse fibroblast cells.

RESULTS

The modified dinucleoside monophosphate, d(T(d)pA), fragments by two pathways so that altogether the lesion could be detected using two different sets of tandem mass spectrometry (precursor ion mass/daughter ion mass) values.

CONCLUSION

The dihydrothymine lesion is a significant lesion in cells exposed to ionizing radiation in an anaerobic environment.

A theoretical study of the cis-syn pyrimidine dimers in the gas phase and water cluster and a tautomer-bypass mechanism for the origin of UV-induced mutations

A quantum mechanical study of all cis-syn cyclobutane pyrimidine photodimers including the normal and rare tautomeric forms of bases has been performed using the ab initio method at HF/6-31G(d.p), MP2(fc)//HF/6-31G(d,p) and MP2(fc)/6-31G(d,p) levels. A puckering angle of the cyclobutyl ring and twist angle of pyrimidine rings with respect to each other is well described by these calculations. It is predicted that in the gas phase all photodimers containing the rare imino form of cytosine are more stable than those containing its normal form. The Monte Carlo simulations show that the dimer containing the imino form of cytosine is more stabilized by water cluster than that containing its amino forms. The possible biological significance stems from the fact that the cytosine in the dimer directs the incorporation of adenine in the complementary strand during replicative bypass. Data obtained point to the cytosine tautomerism as a possible mechanism for the origin of UV-induced mutation.

Assembly of a polytopic membrane protein structure from the solution structures of overlapping peptide fragments of bacteriorhodopsin

Three-dimensional structures of only a handful of membrane proteins have been solved, in contrast to the thousands of structures of water-soluble proteins. Difficulties in crystallization have inhibited the determination of the three-dimensional structure of membrane proteins by x-ray crystallography and have spotlighted the critical need for alternative approaches to membrane protein structure. A new approach to the three-dimensional structure of membrane proteins has been developed and tested on the integral membrane protein, bacteriorhodopsin, the crystal structure of which had previously been determined. An overlapping series of 13 peptides, spanning the entire sequence of bacteriorhodopsin, was synthesized, and the structures of these peptides were determined by NMR in dimethylsulfoxide solution. These structures were assembled into a three-dimensional construct by superimposing the overlapping sequences at the ends of each peptide. Onto this construct were written all the distance and angle constraints obtained from the individual solution structures along with a limited number of experimental inter-helical distance constraints, and the construct was subjected to simulated annealing. A three-dimensional structure, determined exclusively by the experimental constraints, emerged that was similar to the crystal structure of this protein. This result suggests an alternative approach to the acquisition of structural information for membrane proteins consisting of helical bundles.

Structures of the transmembrane helices of the G-protein coupled receptor, rhodopsin

An hypothesis is tested that individual peptides corresponding to the transmembrane helices of the membrane protein, rhodopsin, would form helices in solution similar to those in the native protein. Peptides containing the sequences of helices 1, 4 and 5 of rhodopsin were synthesized. Two peptides, with overlapping sequences at their termini, were synthesized to cover each of the helices. The peptides from helix 1 and helix 4 were helical throughout most of their length. The N- and C-termini of all the peptides were disordered and proline caused opening of the helical structure in both helix 1 and helix 4. The peptides from helix 5 were helical in the middle segment of each peptide, with larger disordered regions in the N- and C-termini than for helices 1 and 4. These observations show that there is a strong helical propensity in the amino acid sequences corresponding to the transmembrane domain of this G-protein coupled receptor. In the case of the peptides from helix 4, it was possible to superimpose the structures of the overlapping sequences to produce a construct covering the whole of the sequence of helix 4 of rhodopsin. As similar superposition for the peptides from helix 1 also produced a construct, but somewhat less successfully because of the disordering in the region of sequence overlap. This latter problem was more severe for helix 5 and therefore a single peptide was synthesized for the entire sequence of this helix, and its structure determined. It proved to be helical throughout. Comparison of all these structures with the recent crystal structure of rhodopsin revealed that the peptide structures mimicked the structures seen in the whole protein. Thus similar studies of peptides may provide useful information on the secondary structure of other transmembrane proteins built around helical bundles.

The 2-naphthylmethyl (NAP) group in carbohydrate synthesis: first total synthesis of the GlyCAM-1 oligosaccharide structures

Total syntheses of the GlyCAM-1 (glycosylation-dependent cell adhesion molecule-1) oligosaccharide structures: [alpha-NeuAc-(2 --> 3)-beta-Gal-(1 --> 4)-[alpha-Fuc-(1 --> 3)]-beta-(6-O-SO3Na)-GlcNAc-(1 --> 6)]-[alpha-NeuAc-(2 --> 3)-beta-Gal-(1 --> 3)]-alpha-GalNAc-OMe (1) and [alpha-NeuAc-(2 --> 3)-beta-Gal-(1 --> 4)-[alpha-Fuc-(1 --> 3)]-beta-GlcNAc-(1 --> 6)]-[alpha-NeuAc-(2 3)-beta-Gal-(1 --> 3)]-alpha-GalNAc-OMe (2) through a novel sialyl LewisX tetrasaccharide donor are described. Employing sequential glycosylation strategy, the starting trisaccharide was regio- and stereoselectively constructed through coupling of a disaccharide imidate with the monosaccharide acceptor phenyl-6-O-naphthylmethyl-2-deoxy-2-phthalimido-1-thio-beta-D-glucopyranoside with TMSOTf as a catalyst without affecting the SPh group. The novel sialyl Lewisx tetrasaccharide donor 3 was then obtained by alpha-L-fucosylation of trisaccharide acceptor with the 2,3,4-tri-O-benzyl-1-thio-beta-L-fucoside donor. The structure of the novel sialyl Lewisx tetrasaccharide was established by a combination of 2D DQF-COSY and 2D ROESY experiments. Target oligosaccharides 1 and 2 were eventually constructed through heptasaccharide which was obtained by regioselective assembly of advanced sialyl Lewisx tetrasaccharide donor 3 and a sialylated trisaccharide acceptor in a predictable and controlled manner. Finally, target heptasaccharides 1 and 2 were fully characterized by 2D DQF-COSY, 2D ROESY, HSQC, HMBC experiments and FAB mass spectroscopy.

A novel tumor necrosis factor-alpha inhibitory protein, TIP-B1

TIP-B1, a novel TNF inhibitory protein, has been identified, purified and characterized from cytosolic extracts of TNF-treated human fibroblasts, and a partial TIP-B1 cDNA clone has been obtained. The (27 kDa pI approximately 4.5 TIP-B1 protein is unique based on both the sequence of three internal peptides (comprising 51 amino acids), and the nucleotide sequence of the corresponding cDNA clone. TNF-sensitive cells, when exposed to TIP-B1 prior to the addition of TNF, are completely protected from TNF-induced lysis. Thus, this TIP-B1 treatment effectively makes these cells TNF-resistant. Furthermore, TIP-B1 protects cells from apoptotic lysis induced by TNF. TIP-B1 does not interfere with the interactions between TNF and the TNF receptors based on flow cytometric analysis of the cellular binding of biotinylated TNF. These and other data indicate that TIP-B1 is not a soluble TNF receptor, nor an anti-TNF antibody, nor a protease that degrades TNF, yet TIP-B1 functions when added exogenously to cells. Thus, TIP-B1 is not one of the proteins previously reported to be involved in resistance to TNF. The fact that incubation of the newly discovered novel TIP-B1 with TNF-sensitive cells protects them from TNF-induced cell death, including TNF-mediated apoptosis, makes TIP-B1 a candidate for therapeutic modulation of TNF-induced effects.

Chemical synthesis of sulfated oligosaccharides with a beta-D-Gal-(1-->3)

The syntheses of two sulfated pentasaccharides: beta-D-Gal6SO3Na-(1-->3)-[beta-D-Gal-(1-->4)-alpha-L-Fuc-(1-->3)-beta-D-Glc-NAc-(1-->6)]-alpha-D-GalNAc-->OMe (1) and beta-D-Gal6SO3Na-(1-->3)-[beta-D-Gal-(1-->4)-alpha-L-Fuc-(1-->3)-beta-D-Glc-NAc6SO3Na-(1-->6)]-alpha-D-GalNAc-->OMe (2) by using Lewisx trisaccharides 12 and 16 as glycosyl donors are described. Sulfated oligosaccharides 1-2 and intermediate compounds are fully characterized by 2D 1H-1H DQF-COSY and 2D ROESY experiments.

Chemical synthesis of a core 2 branched pentasaccharide containing a carboxylate group

Design and synthesis of a carboxylate-containing pentasaccahride 1 with the Galbeta(1-4) (Fucalpha1-3)GlcNAcbeta(1-6)[3-[1-carboxymethyl]-Galbeta+ ++(1-3)]GalNAcalpha-OMe sequence, which is obtained through regioselective coupling of the 6-OH of a novel acceptor 9 with Lewis(x) donor 10 catalyzed by NIS-TfOH are described.

Total synthesis of sialylated and sulfated oligosaccharide chains from respiratory mucins

The total syntheses of several complex oligosaccharide moieties that occur in the core structure of sulfated mucins are reported. A trisaccharide acceptor was obtained through regio- and stereoselective sialylation of methyl (6-O-pivaloyl-beta-D-galactopyanosyl)(1-->3)-4,6-O-benzylidene-2-a cetamido-2-deoxy-alpha-D-galactopyranoside with a novel sialyl donor. A tetrasaccharide, pentasaccharide, and hexasaccharide were constructed in predictable and controlled manner with high regio- and stereoselectivity after the successful preparation and employment of a disaccharide donor, trisaccharide donor, disaccharide acceptor, and trisaccharide acceptor building blocks. Finally, a mild oxidative cleaving method was adopted for the selective removal of 2-naphthylmethyl (NAP) in the presence of benzyl groups.

A convergent synthesis of trisaccharides with alpha-Neu5Ac-(2 --> 3)-beta-D-gal-(1 --> 4)-beta-D-GlcNAc and alpha-Neu5Ac-(2 --> 3)-beta-D-gal-(1 --> 3)-alpha-D-GalNAc sequences

The syntheses of three trisaccharides: alpha-Neu5Ac-(2 --> 3)-beta-D-Gal-(1 --> 4)-beta-D-GlcNAc --> OMe, alpha-Neu5Ac-(2 --> 3)-beta-D-Gal6SO3Na-(1 --> 4)-beta-D-GlcNAc --> OMe, and alpha-Neu5Ac-(2 --> 3)-beta-D-Gal-(1 --> 3)-alpha-D-GalNAc --> OBn were accomplished by using either methyl (phenyl 5-acetamido-4,7,8,9-tetra-O-acetyl-3,5-dideoxy-2-thio-beta-D-glycero-D-g alacto-2-nonulopyranoside)onate or methyl (phenyl N-acetyl-5-acetamido-4,7,8,9-tetra-O-acetyl-3,5-dideoxy-2-thio-beta-D-gl ycero-D-galacto-2-nonulopyranoside)onate as the sialyl donor. The N,N-diacetylamino sialyl donor appears to be more reactive than its parent acetamido sugar when allowed to react with an disaccharide acceptor under the same glycosylation conditions. The trisaccharides, as well as the intermediate products, were fully characterized by 2D DQF 1H-1H COSY and 2D ROESY spectroscopy.

Three dimensional structure of the seventh transmembrane helical domain of the G-protein receptor, rhodopsin

PURPOSE

The three dimensional structure of a peptide comprising the sequence of the seventh transmembrane segment of the G-protein coupled receptor, rhodopsin, was determined in solution.

METHODS

The sequence of the seventh transmembrane segment of rhodopsin, which contains the NPxxY sequence that is highly conserved among G-protein coupled receptors and lys296 that forms the Schiff base with the retinal, was synthesized by solid phase peptide synthesis. The three dimensional structure was determined in solution by high-resolution nuclear magnetic resonance (NMR).

RESULTS

The structure revealed a helix-break-helix motif for this sequence. Two families of structures were observed which differed in the angle between the two helical segments. The sequence of this transmembrane segment overlapped significantly the sequence of a peptide from the carboxyl terminal of rhodopsin, the structure of which was solved previously. The redundant sequence formed a helix in both peptides. It was therefore possible to superimpose the redundant sequence of both peptides and construct a structure for rhodopsin encompassing residues 291-348.

CONCLUSIONS

This structure reveals locations of the lys296 and the acylation sites of rhodopsin that are consistent with the known biochemistry of this receptor. This segmentation approach to membrane protein structure provides important structural information in the absence of an X-ray crystal structure of rhodopsin. The approach is expected to be useful for other G-protein coupled receptors.

Solution structure of the loops of bacteriorhodopsin closely resembles the crystal structure

Bacteriorhodopsin is one of very few transmembrane proteins for which high resolution structures have been solved. The structure shows a bundle of seven helices connected by six turns. Some turns in proteins are stabilized by short range interactions and can behave as small domains. These observations suggest that peptides containing the sequence of the turns in a membrane protein such as bacteriorhodopsin may form stable turn structures in solution. To test this hypothesis, we determined the solution structure of three peptides each containing the sequence of one of the turns in bacteriorhodopsin. The solution structures of the peptides closely resemble the structures of the corresponding turns in the high resolution structures of the intact protein.

Structures of the intradiskal loops and amino terminus of the G-protein receptor, rhodopsin

The intradiskal surface of the transmembrane protein, rhodopsin, consists of the amino terminal domain and three loops connecting six of the seven transmembrane helices. This surface corresponds to the extracellular surface of other G-protein receptors. Peptides that represent each of the extramembraneous domains on this surface (three loops and the amino terminus) were synthesized. These peptides also included residues which, based on a hydrophobic plot, could be expected to be part of the transmembrane helix. The structure of each of these peptides in solution was then determined using two-dimensional 1H nuclear magnetic resonance. All peptide domains showed ordered structures in solution. The structures of each of the peptides from intradiskal loops of rhodopsin exhibited a turn in the central region of the peptide. The ends of the peptides show an unwinding of the transmembrane helices to form this turn. The amino terminal domain peptide exhibited alpha-helical regions with breaks and bends at proline residues. This region forms a compact domain. Together, the structures for the loop and amino terminus domains indicate that the intradiskal surface of rhodopsin is ordered. These data further suggest a structural motif for short loops in transmembrane proteins. The ordered structures of these loops, in the absence of the transmembrane helices, indicate that the primary sequences of these loops are sufficient to code for the turn.

Thermolysis of vic-dihydroxybacteriochlorins: a new approach for the synthesis of chlorin-chlorin and chlorin-porphyrin dimers

[formula: see text] A novel approach for the preparation of symmetrical (chlorin-chlorin), and unsymmetrical (chlorin-porphyrin) dimers joined with carbon-carbon linkages as models to study the "intramolecular" charge transfer is discussed.

An efficient synthesis of two monosulfated trisaccharides with the Galbeta1,3GlcNacbeta1,3Galbeta-O-allyl backbone

The GlcNAcbeta(1-->3) Gal linked disaccharide 7 was synthesized as key building blocks for the construction of target monosulfated trisaccharides 1 and 2 using oxazoline 3 as glycosyl donor promoted by BF3 x Et2O.

An NMR and conformational investigation of the trans-syn cyclobutane photodimers of dUpdT

Both trans-syn cyclobutane-type photodimers of 2'-deoxyuridylyl (3'-5') thymidine (dUpdT) were formed by deamination of the corresponding trans-syn cyclobutane photodimers of 2'-deoxycytidylyl (3'-5') thymidine (dCpdT) and were examined by 1H-, 13C-, and 31P-nmr spectroscopy. One- and two-dimensional nmr experiments provided a nearly complete assignment of the 1H, 13C, and 31P resonances. Scalar and nuclear Overhauser effect contacts were used to determine the conformation of the deoxyribose rings, exocyclic bonds, cyclobutane rings, and glycosidic linkages. Isomer I (S-type class; CB-; SYN-ANTI) and isomer II (N-type class; CB+; ANTI-SYN) exhibit markedly different conformational features. 31P chemical shifts show that the relative flexibility is dUpdT > isomer II > isomer I. The conformations of these species are very similar to those of other previously examined trans-syn photodimers. Among bipyrimidine photodimers of a given diastereomeric form (i.e., trans-syn I or II), the nmr-derived conformational parameters are nearly invariant, regardless of base substitution pattern. This contrasts with the substituent-dependent variation of cyclobutane ring conformation observed by Kim et al. (Biopolymers, 1993, Vol. 33, pp. 713-721) for an analogous series of cis-syn photodimers. Steric crowding of cyclobutane ring substituents is offered as an explanation for the difference in substituent effects between the families of cis-syn and trans-syn photodimers.

A study of the hydration of deoxydinucleoside monophosphates containing thymine, uracil and its 5-halogen derivatives: Monte Carlo simulation

An extensive Monte Carlo simulation of hydration of various conformations of the dinucleoside monophosphates (DNP), containing thymine, uracil and its 5-halogen derivatives has been performed. An anti-anti conformation is the most energetically stable one for each of the DNPs. In the majority of cases the energy preference is determined by water-water interaction. For other dimers conformational energy is the most important factor, or both the factors are of nearly equal importance. The introduction of the methyl group into the 5-position of uracil ring most noticeably influences the conformational energy and leads to the decrease of its stabilizing contribution to the total interaction energy. The introduction of halogen atoms increases the relative content of anti-syn and syn-anti conformations of DNPs as compared to the parent ones due to the formation of an energetically more favorable water structure around these conformations. A correlation is observed between the Monte Carlo results for the halogenated DNPs and their experimental photoproduct distribution. The data obtained demonstrates a sequence dependence in the photochemistry of the halogenated dinucleoside monophosphates.

Synthesis of oligosaccharides containing beta-D-Gal-(1-->3)-O-(6-O-sulfo-beta-D-GlcNAc) as a terminal unit

The chemical synthesis of beta-D-Gal-(1-->3)-6-O-SO3Na-beta-D-GlcNAc-(1-->6)-alpha-D-Man-O-+ ++C6H4NO2 (1) and beta-D-Gal-(1-->3)-6-O-SO3Na-beta-D-GlcNAc-(1-->2)-alpha-D-Man-OMe (2) is reported using a key glycosyl donor, phenyl O-(2,3,4,6-tetra-O-acetyl-beta-D-galactopyranosyl)-(1-->3)-4,6-di-O- chloroacetyl-2-deoxy-2-phthalimido-1-thio-beta-D-glucopyranoside (3).

Nuclear magnetic resonance spectroscopy of mussel adhesive protein repeating peptide segment

Mussel adhesive protein (MAP) is the adhesive agent used by the common blue sea mussel (Mytilus edulis) to attach the animal to various underwater surfaces. It is generally composed of 75 to 85 repeating decameric units with the reported primary sequence NH2-Ala(1)-Lyst(2)-Pro(3)-Ser(4)-Tyr(5)-Hyp(6)-Hyp(7)-Thr(8)-DOPA( 9)- Lys(10)-COOH. This study examines this peptide's solution-state conformation using proton nuclear magnetic resonance (NMR) spectroscopy. NMR and molecular modeling of the decamer before and after molecular dynamics calculations in water suggests a conformation that retains an overall bent helix.

Protein-nucleic acid recognition: simulation of base and "model" amino acids complexes in DMSO by the Monte Carlo method

A computer simulation of guanine (G), cytosine (C), the G-C base pair, protonated C (CH+), acetic acid in neutral (AcOH) and deprotonated (AcO-) forms, G-AcO-, C-AcOH, and CH(+)-AcO- complexes, solvated in DMSO was carried out by the Monte Carlo method. It is shown that the G-C base pair formation in DMSO is energetically favorable. The G-AcO- complex formation is comparable with the formation of G-C base pair in energetically favorability. In this case the acetate anion can replace C in the G-C base pair. The formation of the C-AcOH complex is much less favorable than the formation of the G-C pair. However proton transfer from AcOH to C leads to the formation of the CH(+)-AcO- complex, which is the most favorable of all complexes studied. Here the acetic acid can replace G in a G-C base pair. The formation of G-AcO- and CH(+)-AcO- specific complexes detected in DMSO with the help of experiment and theory is a competitive process with respect to the formation of G-C base pairs, and can be considered the primary step in the real mechanism of protein-nucleic acid recognition.

Three-dimensional structure of the cytoplasmic face of the G protein receptor rhodopsin

Rhodopsin is a G protein receptor from a many-membered family of membrane receptors. No high-resolution structure exists for any member of this family due to the insolubility of membrane proteins and the difficulty in crystallizing membrane proteins. Two new approaches to the structure of rhodopsin are described that circumvent these limitations: (1) individual solution structures of the four cytoplasmic domains of rhodopsin are fitted with the transmembrane domain; (2) the solution structure of a complex of the four cytoplasmic domains is determined from nuclear magnetic resonance data. The two structures are similar. To test the validity of these structures, specific site-to-site distances measured on intact membrane-bound rhodopsin are compared to the same distances on the structures reported here. Excellent agreement is obtained. Furthermore, the agreement is obtained with distances measured on the activated form of teh receptor and not with distances on the dark-adapted form of rhodopsin. This approach may prove to have general applicability for the determination of the structure for membrane proteins.

The study of the stability of Watson-Crick nucleic acid base pairs in water and dimethyl sulfoxide: computer simulation by the Monte Carlo method

An extensive computer simulation of nucleic acid bases and Watson-Crick base pairs in a water cluster and DMSO cluster is performed by the Monte Carlo method. It is demonstrated that the unfavorable energetics of pair formation in a water cluster is determined by the significant destabilizing contribution of solvent to the energy of complex formation. It is shown that the formation of coplanar base pairs in a DMSO cluster is favorable. The DMSO cluster stabilizes A-U and A-T base pairs and the insignificant destabilization of the G-C base pair by a DMSO cluster is much less than the stabilization which occurs due to the attraction between bases.

The first and second cytoplasmic loops of the G-protein receptor, rhodopsin, independently form beta-turns

The cytoplasmic face of the transmembrane protein, rhodopsin, is made up of one carboxyl terminal and three cytoplasmic loops connecting six of the seven transmembrane helices. Neither the high-resolution, three-dimensional structure of this G-protein receptor nor any other cell surface receptor is known. In this work, the structures of peptides containing the amino acid sequence of the first and second cytoplasmic loops of rhodopsin have been determined. Both loops show ordered structures in solution. In both loops, the ends of the transmembrane helices unwind and form a beta-turn. The conformations of the two loops are remarkably similar, even though their sequences are not. These data suggest a structural motif for short loops in transmembrane proteins. The well-ordered structures of these loops, in the absence of the transmembrane helices, indicate that the primary sequences of these loops stabilize the beta-turn. These data further suggest that the loops may contribute to the folding of such membrane proteins during their synthesis and insertion into membranes.

Structure determination of the fourth cytoplasmic loop and carboxyl terminal domain of bovine rhodopsin

PURPOSE

High resolution structural information is lacking for any member of the class of G-protein receptors. This dearth of structural information extends to virtually all integral membrane proteins. As part of an alternative approach to examining integral membrane protein structure, we are determining the structures of the extramembraneous domains of the G-protein receptor, rhodopsin.

METHODS

The carboxyl terminal domain of bovine rhodopsin was synthesized, containing the last 43 amino acids of the protein sequence (rhoIVe). This sequence included the entire putative fourth cytoplasmic loop as well as a significant portion of helix seven, the transmembrane helix of this receptor to which the carboxyl terminal is attached. The solution structure of rhoIVe was determined by multidimensional 1H nuclear magnetic resonance.

RESULTS

The structure contained a portion of alpha-helix corresponding to the top of transmembrane helix seven of the receptor. This allowed unambiguous docking of the carboxyl terminal domain to a model of the transmembrane domain. Helix seven is longer than suggested by hydropathy analysis. The structure also revealed the fourth cytoplasmic loop. The palmitoylation sites of rhodopsin are located near the deduced membrane surface. However, palmitoylation is not required for formation of this loop.

CONCLUSIONS

The carboxyl terminal of rhodopsin forms a structural domain whose structure can be determined separately from the rest of the protein. This structure reveals the fourth cytoplasmic loop that had been suggested to exist based on the presence of palmitoylation sites in the carboxyl terminal domain. Determination of the structure of all of the cytoplasmic domains of rhodopsin in a manner that allows docking to the structure of the transmembrane domain should permit construction of the entire surface of rhodopsin that interacts with the G-protein, transducin. Additionally, the rhodopsin phosphorylation sites and mutations associated with certain autosomal dominant forms of retinitis pigmentosa can now be located in the three dimensional structure of the carboxyl terminal domain.

Structure of the third cytoplasmic loop of bovine rhodopsin

The three-dimensional high-resolution structure of rhodopsin is unknown, as is the case for almost all integral membrane patients. As part of an alternative approach to determine of membrane protein structure, we are pursuing the structure of cytoplasmic domains of this G-protein receptor. A peptide, rhoIII, with the sequence of the third cytoplasmic loop of bovine rhodopsin was synthesized. This soluble peptide was biologically active, inhibiting the light-stimulated activation of the rod cell phosphodiesterase by rhodopsin in rod outer segment disks. Therefore rhoIII likely contains structural elements characteristic of native rhodopsin. The structure of rhoIII was determined by H nuclear magnetic resonance. A defined structure was obtained for about 70% of rhoIII. A model of a turn-helix-turn motif could then be proposed for the third cytoplasmic loop of rhodopsin, which suggested a molecular switch for activation of the G-protein by the receptor.

Structure of the carboxy-terminal domain of bovine rhodopsin

The biologically active carboxy-terminal peptide of the G-protein receptor, rhodopsin, forms a compact structure, suggesting that it is a structural domain in this integral membrane protein. The disposition of serines explains receptor kinase specificity.

Solution structure of a nucleic acid photoproduct of deoxyfluorouridylyl-(3'-5')-thymidine monophosphate (d-FpT) determined by NMR and restrained molecular dynamics: structural comparison of two sequence isomer photoadducts (d-U5p5T and d-T5p5U)

Acetone-sensitized irradiation using UV-B (sun lamp, lambda max = 313 nm) of deoxyfluorouridylyl-(3'-5')-thymidine monophosphate (d-FpT, F = fluorouracil), produces two major photoproducts, the cis-syn cyclobutane-type photodimer and a defluorinated (5-5) photoadduct, d-U5p5T. Product distribution is dependent on the pH of the irradiation solution, as was the case of irradiated d-TpF. At high pH (8-10) the (5-5) photoadduct is the major photoproduct. Irradiation of d-FpT shows a much faster photodegradation rate than the sequence isomer d-TpF. Multinuclear NMR experiments establish the formation of (5-5) covalent bonding between the C5 (d-U5p-, where the fluorine had been) and the C5 (-p5T) and the C6 (-p5T) acquires an OH group. NOE interproton distances and dihedral angles derived from J coupling analysis are constrained to refine model structures of d-U5p5T in restrained molecular dynamics calculations. The resultant structures obtained show 5S-6S as the most chiralities of the C5 and C6 atoms of the thymine, which is the opposite chirality to the corresponding atoms in the sequence isomer d-T5p5U. The orientation of the C5 substituents (-p5T fragment), the CH3 and the uracil are pseudo-axial and pseudo-equatorial respectively. Glycosidic angles are in the anti regions for both the d-U5p- and -p5T residues. Averaged backbone conformations of the two photoadducts, d-U5p5T and d-T5p5U, are similar, although the overall structure of d-U5p5T appears much more flexible than that of d-T5p5U. In particular, the sugar conformations of the 5'-end residues show a remarkable difference in flexibility.

Theoretical investigation of excimer and exciplex states of uracil and halogen derivatives: effect of nonparallelism of bases

Theoretical modeling of initial steps of the photodimerization mechanism of uracil, 5-methyl-and 5-halogen derivatives was performed. The interaction energy of bases in stacked dimers in the ground and lowest excited states was calculated as a function of the distance between the base planes and of the rotation angles within the perturbation theory for the extended Hückel treatment. The existence of excimer and exciplex region on the potential surface of the excited state was revealed. The excimer (exciplex) geometry has the planes nonparallel with more close contact of the C5-C6 bonds as compared to the ground state of dimers. The results provide new information useful for understanding the photodimerization mechanism of bases and testifies that the singlet excimer state can be a precursor of the photodimerization reaction.

Solvent- and concentration-dependent molecular interactions of taxol (Paclitaxel)

Taxol (paclitaxel) is a promising anticancer agent that has been approved for the treatment of ovarian cancer and is under investigation for the therapy of other tumors. Paclitaxel is poorly soluble in water, and information on its physical behavior in hydrophilic and hydrophobic environments is limited. Circular dichroism (CD) and nuclear magnetic resonance spectroscopy were used to investigate the effect of solvent and drug concentration on the solution conformation of paclitaxel. CD is sensitive to paclitaxel's environment, owing to the presence of effective chromophores in the vicinity of several chiral centers. It was found that (i) the conformation of the paclitaxel side chain depends on the polarity of the solvent and (ii) paclitaxel has a tendency to undergo concentration-dependent aggregation in solvents such as chloroform. To account for the observations, a model is proposed in which paclitaxel molecules are held together in stacks by intermolecular hydrogen bonds involving all four exchangeable protons. Intermolecular interactions and self-association of paclitaxel may have impact not only on the physical stability of the drug in existing formulations or investigational vehicles but also on the effect of paclitaxel in the stabilization of cellular microtubules.

An NMR and conformational investigation of the trans-syn cyclobutane photodimers of dTpdU

Two trans-syn cyclobutane photodimers of thymidylyl (3'-5') deoxyuridine were formed by deamination of the corresponding trans-syn cyclobutane photodimers of thymidylyl (3'-5') deoxycytidine and were examined by 1H-, 13C-, and 31P-nmr spectroscopy. Correlation spectroscopy, nuclear Overhauser enhancement spectroscopy, and one-dimensional heterodecoupling experiments allowed a more complete assignment of the 1H spectra, compared with previous reports by Koning et al. [(1991) European Journal of Biochemistry, Vol. 195, pp. 29-40] and Liu and Yang [(1978) Biochemistry, Vol. 17, pp. 4865-4876]. Deoxyribose ring conformations were calculated from 1H coupling constants by pseudorotational analysis, and rotamer distributions of exocyclic bonds were calculated from the observed homonuclear and heteronuclear coupling constants. The cyclobutane ring configuration (CB) of each isomer was identified, using arguments based upon observed scalar and dipolar couplings. Glycosidic bond conformation was ascertained from nuclear Overhauser enhancements observed between base and deoxyribose protons. Isomer I (S-type class; CB-; SYN-ANTI) and isomer II (N-type class; CB+; ANTI-SYN) exhibit markedly different conformational features. 31P chemical shifts and exocyclic bond rotamer distributions indicate diminished backbone flexibility for both photoproducts relative to parent thymidylyl (3'-5') deoxyuridine. Isomer I (SYN-ANTI) is particularly rigid, while isomer II (ANTI-SYN) maintains some flexibility. Also, 13C spectra were acquired and assigned unequivocally with the aid of short- and long-range two-dimensional heteronuclear shift correlation experiments.

Solution structure of nucleic acid photoadduct, deoxy-m5HO6-uridylyl(5-5)(3'-5')deoxyuridine by NMR and restrained molecular dynamics

Sensitized UV-B irradiation (sunlamps) of the dinucleoside monophosphate, d-TpF (F = fluorouracil), produces the usual cyclobutane-type photodimer and an additional defluorinated 5-5 photoadduct, d-T5p5U. In d-T5p5U, the original C5 = C6 structure is modified such that the C5 (d-T5p-) is covalently bonded with the C5 (-p5U) (where the fluorine had been) and the C6 (d-T5p-) acquires an OH group. 2D NOE data and the results of J-coupling analysis are used as constraints to refine structures of d-T5p5U in restrained molecular dynamics calculations. The structures obtained show the most probable chiralities of the C5 and C6 atoms of the Thy-portion to be 5R and 6R, respectively. The orientation of the CH3- and uracil-groups are pseudo-axial and pseudo-equatorial, respectively, with respect to the C5 atom. Glycosidic angles are high-anti and anti for the d-T5p- and the -p5U residue, respectively. C3'-endo like sugar puckering is predominant in the d-T5p- residue while C2'-endo like puckering is predominant at the -p5U residue.

UV irradiation of nucleic acids: characterization of photoproducts of thymidylyl-(3'-->5')-2'-deoxy-5-fluorouridine

The acetone-sensitized irradiation using UV-B (ultraviolet light, 280-320 nm; sunlamps) of thymidylyl(3'-->5')deoxyfluorouridine monophosphate produces two main photoproducts. The distribution of these photoproducts is dependent on the pH of the irradiation solution. At pH 6, the cis-syn cyclobutane-type photodimer is the major product, whereas at high pH (8-10) a photoadduct is the major product. These photoproducts have been identified and structurally characterized by H-1 and C-13 NMR spectroscopy. The photoadduct arises from defluorination of the 5-fluorouracil moiety. The structure of the photoadduct maintains the sugar-phosphate backbone of the starting material (d-TpF), and contains a saturated thymine moiety with an added Thy(C6-hydroxyl) and a Thy(C5)-(C5)Ura covalent bond.

Substituent effects on the puckering mode of the cyclobutane ring and the glycosyl bond of cis-syn photodimers

The cyclobutane ring (CB) puckering of a cis-syn DNA photodimer (cis-syn d-T[p]T) differs from that of a cis-syn RNA photodimer (cis-syn r-U[p]U) [J.-K. Kim and J.L. Alderfer (1992) Journal of Biomolecular Structure and Dynamics, Vol. 9, p. 1705]. In cis-syn d-T[p]T, interconversion of the CB ring between CB+ and CB- is observed, while in cis-syn r-U[p]U only CB- is observed. In the CB+ conformation, the two thymine rings of the dimer are twisted in a right-handed fashion, as are the bases in B-form DNA. In case of CB- they are twisted in a left-handed fashion. The C5 (base) and/or C2' (sugar) substituents apparently affect the CB ring flexibility in cis-syn d-T[p]T and cis-syn r-U[p]U. To study the effects of the C5 substituent on CB ring flexibility, two-dimensional nuclear Overhauser effect (NOE) and 31P-nmr experiments were performed on cis-syn d-T[p]U, cis-syn d-U[p]T, and cis-syn d-U[p]U photodimers to investigate the CB puckering mode and overall molecular conformation and dynamics. The NOE results indicate the 5-methyl group in the photodimer induces conformational flexibility of the CB ring. In cis-syn d-T[p]U and cis-syn d-U[p]T, both CB+ and CB- puckering modes are observed. This indicates interconversion between two modes takes place as observed in cis-syn d-T[p]T. In the case of cis-syn d-U[p]U, only the puckering CB- mode is observed.(ABSTRACT TRUNCATED AT 250 WORDS)

A 5-4 pyrimidine-pyrimidone photoproduct produced from mixtures of thymine and 4-thiouridine irradiated with 334 nm light

The nucleoside 4-thiouridine, present in some bacterial tRNA species, is known to be a chromophore and a target for near-UV light-induced growth delay and also mediates both photoprotection and near-UV cell killing in various bacterial strains. To investigate the photoreaction of 4-thiouridine with DNA or its precursors, we irradiated aqueous mixtures of thymine and 4-thiouridine with 334 nm light and then separated photoproducts using two or more stages of reversed-phase high performance liquid chromatography. The two equally abundant major photoproducts were analyzed by UV absorbance spectrophotometry, fast-atom bombardment and electron-impact mass spectrometry, and 1H- and 13C-NMR spectroscopy, and have been identified as two diastereomers of 6-hydroxy-5-[1-(beta-D-erythro-pentofuranosyl)-4'-pyrimidin-2'- one]dihydrothymine (O6hThy[5-4]Pdo), of molecular weight = 370.32. These two diastereomers, although stable at room temperature or below, are interconvertible by heating (90 degrees C for 5 min) in aqueous solution. The possible biological significance of this photoproduct is discussed, and an application as a crosslinker for oligonucleotides to selectively block replication is suggested.

Energy transduction during catalysis by Escherichia coli DNA photolyase

Native DNA photolyase from Escherichia coli contains 1,5-dihydroFAD (FADH2) plus 5,10-methenyltetrahydropteroylpolyglutamate. Quantum yield and action spectral data for thymine dimer repair were obtained by using a novel multiple turnover approach under aerobic conditions. This method assumes that catalysis proceeds via a (rapid-equilibrium) ordered mechanism with light as the second substrate, as verified in steady state kinetic studies. The action spectrum observed with native enzyme matched its absorption spectrum and an action spectrum simulated based on an energy transfer mechanism where dimer repair is initiated either by direct excitation of FADH2 or by pterin excitation followed by singlet-singlet energy transfer to FADH2. The quantum yield observed for dimer repair with native enzyme (phi Native = 0.722 +/- 0.0414) is similar to that observed with enzyme containing only FADH2 (phi EFADH2 = 0.655 +/- 0.0256), as expected owing to the high efficiency of energy transfer from the natural pterin to FADH2 [EET = 0.92]. The quantum yield observed for dimer repair decreased (2.1-fold) when the natural pterin was partially (68.8%) replaced with 5,10-CH(+)-H4folate (phi obs = 0.342 +/- 0.0149). This is consistent with the energy transfer mechanism (phi calc = 0.411 +/- 0.0118) since a 2-fold lower energy transfer efficiency is observed when the natural pterin is replaced with 5,10-CH(+)-H4folate (EET = 0.46) (Lipman & Jorns, 1992). The action spectrum observed for 5,10-CH(+)-H4folate-supplemented enzyme matched a simulated action spectrum which exhibited a small (5 nm) hypsochromic shift as compared with the absorption spectrum (lambda max = 385 nm).(ABSTRACT TRUNCATED AT 250 WORDS)

A Monte Carlo simulation of hydration of xanthine-derivatives and their stacked forms

Results on a Monte Carlo simulation of the hydration of monomer and possible stacked dimer forms of a purine alkaloid series in 200- and 400-water molecule clusters are presented. Investigation of different purine stacked dimers in a 200-water molecule cluster reveals that for caffeine there exists one, for theophylline two and for theobromine four dimers are energetically favorable. For caffeine, the same energetically favored stacked dimer form is observed in both the 200- and 400-water molecule cluster. The main factor stabilizing the preferred dimer stacks is the change in the interaction between water molecules of the monomer cluster and those water molecules in the dimer cluster.

Conformational variations of the cis-syn cyclobutane-type photodimer in DNA and RNA

The recent NMR study of a cis-syn photodimer B-DNA 10mer-duplex (Taylor et al., Biochemistry 29, 8858 (1990)) showed the cyclobutane (CB) ring with a puckered-twist in a right-handed sense (CB+). This is opposite to that of the crystal structure of cis-syn d-TpT(cyano-ethyl)(d-T[p]T-CE) which has a left-handed puckered-twist (CB-)(Hruska et al., Biopolymers 25, 1399 (1986)). 2D-NOESY experiments were performed on cis-syn d-T[p]T and cis-syn U[p]U at 25 and 35 degrees C, respectively, to investigate the puckering mode of the cyclobutane ring of isolated cis-syn photodimers of the DNA and RNA types. The DNA photodimers showed interconversion of the puckered-twist of the cyclobutane ring between CB- and CB+ and interconversion of the glycosidic angle between syn and anti in both nucleoside residues. Interestingly, in the RNA photodimer only the CB- puckering mode with syn conformation of the glycosidic angle of the U[p]- was observed. These different dynamical behaviors of the photodimer in DNA and RNA might portend differential conformational effects on their corresponding normal nucleic acid regions. In addition these results indicate differences in the cyclobutane ring conformation of the cis-syn d-T[p]T, not only in solution and crystalline states, but also when the dimer is isolated and in duplex forms.

Conformational features of DNA containing a cis-syn photodimer

In an effort to understand the conformational and structural changes in DNA brought about by thymine photodimer, computer modeling and molecular mechanics energy calculations were performed on DNA hexamer and dodecamer duplexes containing a cis-syn photodimer. The conformation of the crystal structure of the cyanoethyl phosphate ester of the thymine dimer (Hruska et al., Biopolymers 25, 1399-1417 (1986)) was used in modeling the photodimer portion. Various starting conformations were used in the modeling procedure and the structures were minimized both retaining and later relaxing the crystallographic geometry of the cyclobutane ring. The results indicate that most of the deformation is restricted to the thymine dimer region, and that the conformational changes decrease rapidly on either side of the region containing the photodimer. The structural changes brought about by the introduction of the photodimer can be accommodated within six base paired duplex without significant bend in the DNA. More conformational changes are observed on the 5'-side of the photodimer than on the 3'-side. The conformational features, such as backbone torsion angles and sugar puckers, of the energy minimized structures are discussed in the context of the solution structures determined by NMR on a series of oligomers containing photodimers (Rycyna et al., Biochemistry 27, 3152-3163 (1988)).

Reaction of Escherichia coli and yeast photolyases with homogeneous short-chain oligonucleotide substrates

Similar rates have been observed for dimer repair with Escherichia coli photolyase and the heterogeneous mixtures generated by UV irradiation of oligothymidylates [UV-oligo(dT)n, n greater than or equal to 4] or DNA. Comparable stability was observed for ES complexes formed with UV-oligo(dT)n, (n greater than or equal to 9) or dimer-containing DNA. In this paper, binding studies with E. coli photolyase and a series of homogeneous oligonucleotide substrates (TpT, TpTp, pTpT, TpTpT, TpTpT, TpTpTpT, TpTpTpT, TpTpTpT, TpTpTpT) show that about 80% of the binding energy observed with DNA as substrate (delta G approximately 10 kcal/mol) can be attributed to the interaction of the enzyme with a dimer-containing region that spans only four nucleotides in length. This major binding determinant (TpTpTpT) coincides with the major conformational impact region of the dimer and reflects contributions from the dimer itself (TpT, delta G = 4.6 kcal/mol), adjacent phosphates (5'p, 0.8 kcal/mol; 3'p, 1.1 kcal/mol), and adjacent thymine residues (5'T, 0.8 kcal/mol; 3'T, 1.3 kcal/mol). Similar turnover rates (average kcat = 6.7 min-1) are observed with short-chain oligonucleotide substrates and UV-oligo(dT)18, despite a 25,000-fold variation in binding constants (Kd). In contrast, the ratio Km/Kd decreases as binding affinity decreases and appears to plateau at a value near 1. Turnover with oligonucleotide substrates occurs at a rate similar to that estimated for the photochemical step (5.1 min-1), suggesting that this step is rate determining. Under these conditions, Km will approach Kd when the rate of ES complex dissociation exceeds kcat.(ABSTRACT TRUNCATED AT 250 WORDS)

Radiation chemistry of d(TpApCpG) in oxygenated solution

The radiation chemistry of the DNA tetranucleoside triphosphate d(TpApCpG) was investigated. The tetramer was X-irradiated in oxygenated aqueous solution and the various products separated by high-performance liquid chromatography. The principal modifications of the tetramer were analysed intact using nuclear magnetic resonance (NMR) spectroscopy and in some instances also by fast atom bombardment (FAB) mass spectrometry. The principal radiation-induced lesions of d(TpApCpG) were found to be a formamido modification derived from the thymine base, two stereoisomeric forms of a 1-carbamoyl-2-oxo-4,5-dihydroxyimidazolidine modification derived from the cytosine base and an 8-hydroxyguanine modification.

Ultraviolet irradiation of nucleic acids: formation, purification, and solution conformational analyses of the cis-syn and trans-syn photodimers of UpU

Uridylyl(3'-5')uridine (UpU) is subjected to aqueous acetone photosensitized radiation with sunlamps. These irradiation conditions form only cyclobutane-type photodimers. Purification of a specific configurational photodimer is accomplished by using C-18 reverse-phase high-performance liquid chromatography. Multinuclear NMR analysis is used to analyze photoproduct formation and to determine conformational features of these photodimers. Four photodimers are identified, with the cis-syn isomer predominant. The cis-syn and trans-syn photodimers of UpU exhibit markedly different furanose and exocyclic bond conformations. A comparison of the properties of the cis-syn dimers of UpU with those of dTpdT reveal many similar conformational features but also some that are different.

Ultraviolet irradiation of nucleic acids: formation, purification, and solution conformational analyses of oligothymidylates containing cis-syn photodimers

Acetone-photosensitized UV irradiation of three thymine oligomers, d(TpT), d(TpTpT), and d(TpTpTpT), forms predominantly cis-syn cyclobutyl photodimers. C-18 reverse-phase high-performance liquid chromatography is used to purify the following positional isomers: d(TpT[p]T), d(T[p]TpT), d(TpTpT[p]T), d(TpT[p]TpT), d(T[p]TpTpT), and d(T[p]TpT[p]T), where T[p]T represents the cis-syn photodimer. Conformational properties of the cis-syn dimers and adjacent thymine nucleotides have been investigated in solution by using 1H, 13C, and 31P NMR spectroscopy. These studies show that (1) the photodimer conformation in longer oligothymidylates is similar to that in the dinucleoside monophosphate and (2) the cis-syn dimer induces alterations to a greater degree on the 5' side than on the 3' side of the photodimer. Specifically, the photodimer distorts the exocyclic bonds epsilon(C3'-O3') in Tp- and gamma(C5'-C4') in -pT[p]- on the 5' side and slightly alters the furanose equilibrium of the -pT nucleotide on the 3' side of the dimer.

UV irradiation of nucleic acids: formation, purification and solution conformational analysis of the '6-4 lesion' of dTpdT

Irradiation of dTpdT with 300 kJ/m2 of 254 nm produces numerous photo-products, one of which labeled dT6pd4T[1] was purified by HPLC. dT6pd4T has a UV spectrum (H20, pH 7) with lambda max = 326 nm and lambda min = 265 nm, and a P-31 NMR resonance at -3.46 ppm (normal dTpdT occurs at -4.01 ppm; TMP, 30 degrees C). 2-D COSY NMR spectra facilitated proton resonance assignments and 2-D NOESY spectra aided analysis of spatial orientation. Carbon-13 and proton-coupled P-31 NMR spectra of dT6pd4T were also obtained. These analyses indicate: C5=C6 of dT6p- is saturated and the -pd4T base is more aromatic; the dT6p- base possesses a configuration of 5R, 6S; dT6p- and -pd4T have anti-type glycosidic conformations; furanose conformation of dT6p- is mainly C3'-endo and that of -pd4T exists in a C3'-endo in equilibrium C3'-exo; exocyclic bonds gamma (C5'-C4'), beta (05'-C5') and epsilon (C3'-03') are non-classical rotamers; dihedral angle about epsilon (C3'-03') is smaller relative to dTpdT.

13C- and 31P-NMR studies of the conformation of carcinogen-modified nucleic acid dimers

The effect of the carcinogen acetylaminofluorene (AAF) on nucleic acid structure was examined using 13C- and 31P-NMR spectroscopies. Conformational effects were compared in two AAF-modified dinucleoside monophosphates (ApG and GpA) and two AAF-modified deoxydinucleotides (dpApG and dpGpA). Changes in adenine 13C chemical shifts on formation of the AAF-adduct and as a function of temperature provided evidence of base stacking. Differences in fluorene 13C chemical shifts between the AAF-modified dimer and AAF-modified monomer provided evidence of fluorene stacking. The effect of forming the adduct on the phosphate backbone was examined using 31P-NMR. A correlation was demonstrated between the degree of adenine-fluorene stacking on one hand and the change in conformation of the backbone conformation on the other.

13C-NMR studies of the effects of the carcinogen acetylaminofluorene on the conformation of dinucleoside monophosphate

13C-NMR spectra are obtained in aqueous solution of dinucleoside monophosphates (ApG and GpA) and of their adducts formed by the addition of the carcinogen acetylaminofluorene (AAF) to the C8 position of the guanine. The base and sugar carbons of all dimers and adducts are assigned. The task of assigning base and carbohydrate resonances was accomplished using a series of reference compounds. Significant changes in many of the carbon resonances of the adducts are observed suggesting three general conformational changes, namely: (1) chemical shift changes are noted in base carbon atom resonances as a function of temperature and adduct formation which are indicative of stacking effects; (2) large upfield shifts of the furanose C2' resonance of the guanosine-adduct indicate a shift to higher populations of the syn conformation. Other shifts of carbohydrate resonances are indicative of a change in conformation of the carbohydrate itself. (3) Large temperature effects on linewidth of several fluorine and furanose resonances indicate interconversion of various conformers in the dimer adduct.