Selective effect of ionization of nitrogen bases on the thermostability of AT- and GC-pairs of DNA

The ionization specific influence of nitrogen bases on thermostability of AT- and GC-pairs of DNA has been investigated by the method of DNAs melting temperature analysis. It has been shown that the change of temperature interval of DNA helix-coil transition when changing pH environment is due to specific ionization of AT- and GC-pairs of nitrogen bases.     

Transient states in reaction centers containing reduced bacteriopheophytin

Photosynthetic reaction centers isolated from Rhodopseudomonas sphaeroides strain R-26 were excited with non-saturating 7-ps, 600-nm flashes under various conditions, and the resulting absorbance changes were measured. If the quinone electron acceptor (Q) is in the oxidized state, flash excitation generates a transient state (P^F), in which an electron has moved from the primary electron donor (P, a dimer of bacteriochlorophylls) to an acceptor complex involving a special bacteriopheophytin (H) and another bacteriochlorophyll (B). P^F decays in 200 ps as an electron moves from H to Q. If Q and the acceptor complex are reduced photochemically before the excitation, the flash generates a different transient state of P with a high quantum yield. This state decays with a lifetime of 340 ps. There is no indication of electron transfer from P to B under these conditions, but this does not rule out the possibility that B is an intermediate electron carrier between P and H. Measurements of the yield of fluorescence from P under various conditions show that the 340 ps state is not the fluorescent excited singlet state of P. The transient state could be a triplet state, a charge-transfer state of P, or another excited singlet state that is not fluorescent.     

Characterization of photosynthetic reaction centers with specific isotope labels

In this minireview the information at the atomic level that has been obtained by studying photosynthetic reaction centers with site-directed isotope labelling is discussed. The required isotopically labelled RCs are prepared using isotopically labelled amino acids and cofactors that have been prepared via organic total synthetic chemistry. In some cases the results of isotopically labelled RCs that are prepared via other methods are also discussed.     

Tetraplex DNA specific ligands based on the fluorenone-carboxamide scaffold

A series of fluorenone-carboxamide compounds was analyzed with regard to DNA binding properties by UV spectroscopy and competition dialysis methods. The morpholino derivative 10 provided interesting results in terms of affinity and specificity toward the DNA G-tetraplex structures. Interactions against this target were evaluated by a comparative molecular modeling study in agreement with the experimental data, proposing a model for the rational design of new agents with potent and selective DNA tetraplex binding properties.     

Adenine specific DNA chemical sequencing reaction.

Reaction of DNA with K2PdCl4 at pH 2.0 followed by a piperidine workup produces specific cleavage at adenine (A) residues. Product analysis revealed the K2PdCl4 reaction involves selective depurination at adenine, affording an excision reaction analogous to the other chemical DNA sequencing reactions. Adenine residues methylated at the exocyclic amine (N6) react with lower efficiency than unmethylated adenine in an identical sequence. This simple protocol specific for A may be a useful addition to current chemical sequencing reactions.     

Simple and rapid preparation of gapped plasmid DNA for incorporation of oligomers containing specific DNA lesions

The cytotoxicity, mutagenicity, and carcinogenicity of DNA base lesions are largely determined by the responses of cellular DNA repair proteins, DNA polymerases, and signaling pathways. Elucidation of these processes is thus of high biochemical interest. Such studies increasingly rely on DNA substrates containing specific lesions at defined locations. Although short synthetic DNA oligomers have frequently proved useful, circular plasmid substrates are preferable for much biochemical work, and essential for in vivo studies. However, the complexity of current approaches for preparing such substrates and limitations inherent in the procedures have posed problems. We present here a simple, highly versatile procedure for preparing gapped duplex plasmids, into which oligomers incorporating specific lesions can easily be inserted. Endonuclease N.BstNBI was used to nick twice the same strand of a pUC19-derived plasmid (pUC19HBDa), at two GAGTCNNNN sequences separated by 22 bases. Removal of the 22-nt oligomer and further purification produced a highly pure gapped plasmid. To illustrate application of this procedure, 22-nt oligonucleotides containing a single uracil residue were ligated into the gapped molecules. The pUC19HB(Da) plasmid can be modified to accept almost any DNA-lesion-containing oligomer. Using this new approach to incorporate specific DNA lesions into popular reporter genes will facilitate in vivo study of cellular responses to DNA damage.     

Site specific labeling of Rhodobacter sphaeroides reaction centers with dye probes for surface pH measurements

Covalently bound pH sensitive dyes are an important tool for characterizing the proteolytic reactions of protein complexes that play key roles in biological energy transduction. Here we demonstrate the feasibility of this method for photosynthetic reaction centers (RCs) for the first time, by the highly selective attachment of two thiol reactive derivatives of fluorescein to the two H subunit cysteines of the photosynthetic RC from Rhodobacter sphaeroides R-26 The pK(a) shifts of the dyes upon binding to the protein and in response to high salt were measured, and interpreted based on the structure of the RC. 2-[(5-fluoresceinyl)aminocarbonyl]ethyl-methanethiosulfonate was attached to Cys H156 and fluorescein-5-maleimide to Cys H234. By following the absorption changes of bound fluorescein (500 nm), and those of the hydrophilic pH indicator 8-hydroxypyrene-1,3,6-tris-sulfonic acid (468 nm), the surface and bulk pH were monitored separately with less than 5% crosstalk. Flash-induced proton uptake and external calibrations by mixing with aliquots of acid were measured in different redox states of the RCs. The results indicate that the charge in the quinone acceptor complex after flash activation (primary quinone acceptor (Q(A))- or secondary quinone acceptor (Q(B))-) has no effect on the surface pH and potential in the vicinity of these two attachment sites, between pH 6.5 and 9. Application of the method to other surface locations is discussed.     

Monoclonal antibodies specific for beta-adrenergic ligands

After somatic cell fusion between splenocytes of immunized BALB/c mice and NS-1 myeloma cells, eight clones were obtained secreting anti-alprenolol antibodies as characterized by means of an ELISA. Four of these were subcloned and were studied further. The association constant for alprenolol ranged from 1.9 X 10(6) M-1 to 24 to 10(6) M-1. Competitive inhibition of [3H]-l-dihydroalprenolol binding revealed cross-reactivity with beta-adrenergic ligands, with a higher avidity for antagonists than for agonists. Two of the antibodies had a higher affinity for the l-isomer than for the d-isomer. The most stereospecific of these antibodies showed only affinity for beta-adrenergic antagonists and for the agonist isoproterenol. The other recognized both beta-adrenergic antagonists and agonists; it also showed an increase in tryptophan fluorescence after ligand binding. This property was used for the physicochemical study of the hapten-antibody interaction.     

Synthetic procedures to monomethyl-platinum(II) complexes containing nitrogen ligands of biological relevance

The complex trans-bis(dimethylsulfoxide)chloromethylplatinum(II) (1) is fairly soluble in water, where it undergoes multiple equilibria involving the formation of geometrically distinct [Pt(H(2)O)(DMSO)Cl(CH(3))] aqua-species. On reacting an aqueous solution of 1 with monodentate nitrogen donor ligands L, such as pyridines or amines, two well distinct patterns of behavior can be recognized: (i) a single stage fast substitution of one DMSO by the entering ligand, yielding a complex of the type trans(C,N)-[Pt(DMSO)(L)Cl(CH(3))] which contains four different groups coordinated to the metal and which undergoes a slow conversion into its cis-isomer, (ii) a double substitution affording cationic complex ions of the type cis-[Pt(L)(2)(DMSO)(CH(3))](+). When this latter reaction is carried out using sterically hindered ligands, slow rotation of the bulk ligand around the Pt[bond]N bond allows for the identification of head-to-head and head-to-tail rotamers in solution, through (1)H NMR spectrometry. The addition of chloride anion to 1 leads to the anionic species cis-[Pt(DMSO)Cl(2)(CH(3))](-), where a molecule of DMSO still remains coordinated to the metal center, despite its quite fast rate of ligand exchange (k(exch) with free DMSO=12+/-1 s(-1)). The reaction of complex 1 with bidentate ligands, such as ethylenediamine (en) or simple amino acids, leads to the cationic species [Pt(en)(DMSO)(CH(3))](+) or to the neutral [Pt(DMSO)(N[bond]O)(CH(3))], (where N[bond]-O[double bond]GlyO(-), AlaO(-)).     

Interaction of DNA with actinocin amides containing cationoid centers in the amide groups

Complexes of DNA with actinocin derivatives containing ω-dialkylaminoalkyl groups in the1 and/or 9 positions of the chromophore were studied by spectrophotometric titration, circular dichroism, and viscometry. Induced circular dichroism (ICD) spectra of the DNA-ligand complexes were compared for the cases of the complexes of known structure established by other methods. It was shown that the presence of an isoelliptic point in the long-wavelength absorption band of the ICD spectra of the ligand under monomeric binding conditions could indicate intercalation of the actinocin chromophore into DNA. The separation of the cationoid center and the chromosphore upon elongation of the methylene chain increases the aggregability of the ligand pn the surface of the DNA double helix, which prevents the intercalation of the chromophore.     

Drug recognition of DNA. Proposal for GC minor groove specific ligands: vinylexins

In a previous publication in this journal we have proposed an isolexin-like prototype of a GC minor groove specific ligand. The present paper is devoted to refinements of this prototype (increase in specificity and in DNA binding energy). It is shown that only a very limited improvement can be obtained by increasing the proton accepting capabilities of the heteroaromatic ring systems of the prototype, although these rings interact directly with the proton donating NH2 group of guanine. On the other hand a significant increase both in GC specificity and in DNA binding energy is obtained by replacing the NH linkers of the isolexin by C = C double bonds (yielding what we term "vinylexins"). Specificity is still largely conserved and the DNA binding energy is significantly increased in monocationic vinylexins, which should thus be efficient GC minor groove specific ligands. The outstanding importance for the GC specificity of the C = C linkers is evidenced by the disappearance of this specificity when these linkers are replaced by peptide bonds (peptilexins). On the other hand vinylexins with proton donating heteroaromatic rings are, as expected, AT specific. The vinylexin family may thus represent universal minor groove binding agents susceptible to bind to any given base pair sequence of DNA, following the positioning of their proton donor and proton acceptor rings. This study confirms the insufficiency of purely geometrical and/or hydrogen bonding considerations for the correct estimation of GC versus AT specificity of groove binding ligands. These can only be accounted for by taking into consideration the overall electronic properties of the interacting species and explicitly calculating the energies of complex formation including all the relevant contributions.     

Radical-pair energetics and decay mechanisms in reaction centers containing anthraquinones, naphthoquinones or benzoquinones in place of ubiquinone

In reaction centers from Rhodobacter sphaeroides (formerly called Rhodopseudomonas sphaeroides), light causes an electron-transfer reaction that forms the radical pair state (P+I-, or PF) from the initial excited singlet state (P) of a bacteriochlorophyll dimer (P). Subsequent electron transfer to a quinone (Q) produces the state P+Q-. Back electron transfer can regenerate P from P+Q-, giving rise to 'delayed' fluorescence that decays with approximately the same lifetime as P+Q-. The free-energy difference between P+Q- and P can be determined from the initial amplitude of the delayed fluorescence. In the present work, we extracted the native quinone (ubiquinone) from Rps. sphaeroides reaction centers, and replaced it by various anthraquinones, naphthoquinones, and benzoquinones. We found a rough correlation between the halfwave reduction potential (E1/2) of the quinone used for reconstitution (as measured polarographically in dimethylformamide) and the apparent free energy of the state P+Q- relatively to P. As the E1/2 of the quinone becomes more negative, the standard free-energy gap between P+Q- and P decreases. However, the correlation is quantitatively weak. Apparently, the effective midpoint potentials (Em) of the quinones in situ depend subtly on interactions with the protein environment in the reaction center. Using the value of the Em for ubiquinone determined in native reaction centers as a reference, and the standard free energies determined for P+Q- in reaction centers reconstituted with other quinones, the effective Em values of 12 different quinones in situ are estimated. In native reaction centers, or in reaction centers reconstituted with quinones that give a standard free-energy gap of more than about 0.8 eV between P+Q- and P*, charge recombination from P+Q- to the ground state (PQ) occurs almost exclusively by a temperature-insensitive mechanism, presumably electron tunneling. When reaction centers are reconstituted with quinones that give a free-energy gap between P+Q- and P* of less than 0.8 with quinones that give a free-energy gap between P+Q- and P* of less than 0.8 eV, part or all of the decay proceeds through a thermally accessible intermediate. There is a linear relationship between the log of the rate constant for the decay of P+Q- via the intermediate state and the standard free energy of P+Q-. The higher the free energy, the faster the decay. The kinetic and thermodynamic properties of the intermediate appear not to depend strongly on the quinone used for reconstitution, indicating that the intermediate is probably not simply an activated form of P+Q-.(ABSTRACT TRUNCATED AT 400 WORDS)     

DNA interactions of cobalt(III) mixed-polypyridyl complexes containing asymmetric ligands

Three novel asymmetric ligands, 3-(pyridine-2-yl)-5,6-diphenyl-as-triazine (pdtb), 3-(pyridine-2-yl)-as-triazino[5,6-f]acenaphthylene (pdta) and 3-(pyridine-2-yl)-as-triazino[5,6-f]phenanthroline (pdtp) and their cobalt(III) complexes have been synthesized and characterized. Binding of the three complexes with calf thymus DNA (CT-DNA) has been investigated by spectroscopic methods, viscosity, cyclic voltammetry, and electrophoresis measurements. The experimental results indicate that the size and shape of the intercalated ligand have a marked effect on the binding affinity of complexes to CT-DNA. Complexes 2 and 3 have also been found to promote cleavage of plasmid pBR322 DNA from the supercoiled form I to the open circular form II upon irradiation.     

Synthetic DNA and Biology

Most of the significant work has been summarized in a number of reviews and articles. In these there was, of necessity, a good deal of simplification and omission of detail .... With the passage of time, even 1 find myself accepting such simplified accounts.The Nobel lecture given on December 8, 1993 by Dr. M. Smith and published in Les Prix Nobel 1993, printed by Norstedts Tryckeri, Stockholm, Sweden 1994, republished here with the permission of the Nobel Foundation, the copyright holder.     

Mechanical detection of interaction of small specific ligands with proteins and DNA in cross-linked samples.

Cross-linked crystalline and amorphous films of different proteins and cross-linked DNA gels were found to change their mechanical properties when soaked in solutions of specific ligands at nearly physiological concentrations. This chemomechanical effect may be used to rapidly (within a few minutes) detect the ability of macromolecules to bind small (less than 1 kDa) ligand molecules, to measure concentrations of ligands (higher than 10 nM), and to estimate binding constants (lower than 10(7) M-1). Only 0.1-1 mg of protein or DNA is needed to prepare more than 10 samples sufficient for a large number of tests, provided binding is reversible. The method is recommended for rapid primary screening in search of new drugs, in biochemical studies, and as a basis for designing biosensors and other analytical instruments.     

Electron donors and acceptors in photosynthetic reaction centers

Summary A review is given of primary and associated electron transport reactions in various division of photosynthetic bacteria and in the two photosystems of plant photosynthesis. Two types of electron acceptor chains are distinguished: type Q, found in purple bacteria, Chloroflexus and system II of oxygenic photosynthesis and type F, found in green sulfur bacteria, Heliobacterium and photosystem I. Secondary donor reactions are discussed in relation to plant photosystem II.Dedicated to the memory of Warren L. Butler     

Proton and electron transfer in bacterial reaction centers

The bacterial reaction center couples light-induced electron transfer to proton pumping across the membrane by reactions of a quinone molecule Q(B) that binds two electrons and two protons at the active site. This article reviews recent experimental work on the mechanism of the proton-coupled electron transfer and the pathways for proton transfer to the Q(B) site. The mechanism of the first electron transfer, k((1))(AB), Q(-)(A)Q(B)-->Q(A)Q(-)(B), was shown to be rate limited by conformational gating. The mechanism of the second electron transfer, k((2))(AB), was shown to involve rapid reversible proton transfer to the semiquinone followed by rate-limiting electron transfer, H(+)+Q(-)(A)Q(-)(B) ifQ(-)(A)Q(B)H-->Q(A)(Q(B)H)(-). The pathways for transfer of the first and second protons were elucidated by high-resolution X-ray crystallography as well as kinetic studies showing changes in the rate of proton transfer due to site directed mutations and metal ion binding.     

Cationic perylenediimide as a specific fluorescent binder to mismatch containing DNA

Small ligand molecules, which can recognize thermodynamically unstable site within DNA, such as mismatch base pair, abasic site, and single-bulge, have attracted much attention because of their potential diagnostics and biological applications. In this paper, we describe the binding of cationic perylenediimide (cPDI) molecules to thymine-containing mismatch base pair in DNA and the formation of cPDI dimer at the mismatch site. The cPDI dimer exhibits a characteristic excimer emission at 650 nm. For T/T mismatch containing DNA, the switching behavior from the PDI dimer (650 nm) to the monomer (550 nm) emission in specific response to Hg²⁺ ion was observed.