Binding of the Bovine and Porcine Pancreatic Secretory Trypsin Inhibitor (Kazal) To Human Leukocyte Elastase: A Thermodynamic Study

Abstract

The effect of pH and temperature on the apparent association equilibrium constant (K_a) for the binding of the bovine and porcine pancreatic secretory trypsin inhibitor (Kazal-type inhibitor, PSTI) to human leukocyte elastase has been investigated. At pH8.0, values of the apparent thermodynamic parameters for human leukocyte elastase: Kazal-type inhibitor complex formation are: bovine PSTT – K_a = 6.3 × 10⁴M^?1, δ5G° = -26.9kJ/mol, δH° = +11.7kJ/mol, and δS° = +1.3 × 10² entropy units; porcine PSTI –K_a = 7.0 × 10³M^?1,δG° = -21.5kJ/mol, δH° = +13.0kJ/mol, and δS° = +1.2 × 10² entropy units (values of K_a δG° and δS° were obtained at 21.0°C; values of δH° were temperature independent over the range (between 5.0°C and 45.0°C) explored). On increasing the pH from 4.5 to 9.5, values of K_a for bovine and porcine PSTI binding to human leukocyte elastase increase thus reflecting the acidic pK-shift of the His57 catalytic residue from ?7.0, in the free enzyme, to ?5.1, in the serine proteinase: inhibitor complexes. Thermodynamics of bovine and porcine PSTI binding to human leukocyte elastase has been analyzed in parallel with that of related serine (pro)enzyme/Kazal-type inhibitor systems. Considering the known molecular models, the observed binding behaviour of bovine and porcine PSTI to human leukocyte elastase was related to the inferred stereochemistry of the serine proteinase/inhibitor contact region(s).     

Production,extraction, and thermodynamics protease partitioning from Aspergillus tamarii Kita UCP1279 using PEG/sodium citrate aqueous two-phase systems

Abstract

The protease from Aspergillus tamarii Kita UCP1279 extraction by aqueous two-phase PEG-Citrate (ATPS) systems, using a factorial design 2⁴, was investigated. Then, the variables studied were polyethylene glycol (PEG) molar mass (M_PEG), concentrations of PEG (C_PEG) and citrate (C_CIT), and pH. The responses analyzed were the partition coefficient (K), activity yield (Y) and purification factor (PF). The thermodynamic parameters of the ATPS partition were estimated as a function of temperature. ATPS was able to pre-purify the protease (PF = 1.6) and obtained 84% activity yield. The thermodynamic parameters ΔG°_m (?10.89?kJ mol^?1), ΔH_m (?5.0?kJ?mol^?1) and partition ΔS_m (19.74?J mol^?1 K^?1) showed that the preferential migration of almost all protein contaminants of the crude extract to the salt-rich phase, while the preferred protease was the PEG rich phase. The extracted enzyme presents optimum temperature and pH at range of 40–50?°C and 9.0–11.0, respectively. Moreover, the enzyme was identified as serine protease based on inhibition profile. ATPS showed the satisfactory performance as the first step for Aspergillus tamarii Kita UCP1279 protease pre-purification.     

Structural characterization of a carbon monoxide adduct of a heme–DNA complex

Abstract  

The structure of a carbon monoxide (CO) adduct of a complex between heme and a parallel G-quadruplex DNA formed from a single repeat sequence of the human telomere, d(TTAGGG), has been characterized using ¹H and ¹³C NMR spectroscopy and density function theory calculations. The study revealed that the heme binds to the 3′-terminal G-quartet of the DNA though a π–π stacking interaction between the porphyrin moiety of the heme and the G-quartet. The π–π stacking interaction between the pseudo-C ₂-symmetric heme and the C ₄-symmetric G-quartet in the complex resulted in the formation of two isomers possessing heme orientations differing by 180° rotation about the pseudo-C ₂ axis with respect to the DNA. These two slowly interconverting heme orientational isomers were formed in a ratio of approximately 1:1, reflecting that their thermodynamic stabilities are identical. Exogenous CO is coordinated to heme Fe on the side of the heme opposite the G-quartet in the complex, and the nature of the Fe–CO bond in the complex is similar to that of the Fe–CO bonds in hemoproteins. These findings provide novel insights for the design of novel DNA enzymes possessing metalloporphyrins as prosthetic groups.     

Temperature-jump kinetics of the dC-G-T-G-A-A-T-T-C-G-C-G double helix containing a G . T base pair and the dC-G-C-A-G-A-A-T-T-C-G-C-G double helix containing an extra adenine

The kinetics of helix formation were investigated using the temperature-jump technique for the following two molecules: dC-G-T-G-A-A-T-T-C-G-C-G, which forms a double helix containing a G·T base pair(the G·T 12-mer), and dC-G-C-A-G-A-A-T-T-C-G-C-G, which forms a double helix containing an extra adenine (the 13-mer). When data were analyzed in an all-or-none model, the activation energy for the helix association process was 22 ± 4 kcal/mol for the G·T 12-mer and 16 ± 7 kcal/mol for the 13-mer. The activation energy for the helix-dissociation process was 68 ± 2 kcal/mol for the G·T 12-mer and 74 ± 3 kcal/mol for the 13-mer. Rate constants for recombination were near 10⁵s^?1M^?1 in the temperature range from 32 to 47°C; for the dissociation process, the rate constants varied from 1s^?1 near 32°C to 130s^?1 near 47°C. Possible effects of hairpin loops and fraying ends on the above data are discussed.     

The nature of the transition mismatches with Watson–Crick architecture: the G*·T or G·T* DNA base mispair or both? A QM/QTAIM perspective for the biological problem

This study provides the first accurate investigation of the tautomerization of the biologically important guanine*·thymine (G*·T) DNA base mispair with Watson–Crick geometry, involving the enol mutagenic tautomer of the G and the keto tautomer of the T, into the G·T* mispair (?G?=?.99?kcal?mol^?1, population?=?15.8% obtained at the MP2 level of quantum-mechanical theory in the continuum with ε?=?4), formed by the keto tautomer of the G and the enol mutagenic tautomer of the T base, using DFT and MP2 methods in vacuum and in the weakly polar medium (ε?=?4), characteristic for the hydrophobic interfaces of specific protein–nucleic acid interactions. We were first able to show that the G*·T?G·T* tautomerization occurs through the asynchronous concerted double proton transfer along two antiparallel O6H···O4 and N1···HN3 H-bonds and is assisted by the third N2H···O2 H-bond, that exists along the entire reaction pathway. The obtained results indicate that the G·T* base mispair is stable from the thermodynamic point of view complex, while it is dynamically unstable structure in vacuum and dynamically stable structure in the continuum with ε?=?4 with lifetime of 6.4·10^?12?s, that, on the one side, makes it possible to develop all six low-frequency intermolecular vibrations, but, on the other side, it is by three orders less than the time (several ns) required for the replication machinery to forcibly dissociate a base pair into the monomers during DNA replication. One of the more significant findings to emerge from this study is that the short-lived G·T* base mispair, which electronic interaction energy between the bases (?23.76?kcal?mol^?1) exceeds the analogical value for the G·C Watson–Crick nucleobase pair (?20.38?kcal?mol^?1), “escapes from the hands” of the DNA replication machinery by fast transforming into the G*·T mismatch playing an indirect role of its supplier during the DNA replication. So, exactly the G*·T mismatch was established to play the crucial role in the spontaneous point mutagenesis.     

The First Example of a Hoogsteen Basepaired DNA Duplex in Dynamic Equilibrium with a Watson-Crick Basepaired Duplex—A Structural (NMR), Kinetic and Thermodynamic Study

Abstract

A single-point substitution of the O4′ oxygen by a CH₂ group at the sugar residue of A ⁶ (i.e. 2′-deoxyaristeromycin moiety) in a self-complementary DNA duplex, 5′- d(C¹G²C³G⁴A⁵A⁶T⁷T⁸C⁹G¹⁰C¹¹G¹²)₂ ^?3, has been shown to steer the fully Watson-Crick basepaired DNA duplex (1A), akin to the native counterpart, to a doubly A ⁶:T⁷ Hoogsteen basepaired (1B) B-type DNA duplex, resulting in a dynamic equilibrium of (1A)→←(1B): K_eq = k₁/k_-1 = 0.56±0.08. The dynamic conversion of the fully Watson-Crick basepaired (1A) to the partly Hoogsteen basepaired (1B) structure is marginally kinetically and thermodynamically disfavoured [k₁ (298K) = 3.9± 0.8 sec^?1; δH°? = 164±14 kJ/mol;-TδS°? (298K) = ?92 kJ/mol giving a δG₂₉₈°? of 72 kJ/mol. Ea (k1) = 167±14 kJ/mol] compared to the reverse conversion of the Hoogsteen (1B) to the Watson-Crick (1A) structure [k-1 (298K) = 7.0±0.6 sec-1, δH°? = 153±13 kJ/mol;-TδS°? (298K) = ?82 kJ/mol giving a δG₂₉₈°? of 71 kJ/mol. Ea (k-1) = 155±13 kJ/mol]. A comparison of δG₂₉₈°? of the forward (k1) and backward (k-1) conversions, (1A)→←(1B), shows that there is ca 1 kJ/mol preference for the Watson-Crick (1A) over the double Hoogsteen basepaired (1B) DNA duplex, thus giving an equilibrium ratio of almost 2:1 in favour of the fully Watson-Crick basepaired duplex. The chemical environments of the two interconverting DNA duplexes are very different as evident from their widely separated sets of chemical shifts connected by temperature-dependent exchange peaks in the NOESY and ROESY spectra. The fully Watson-Crick basepaired structure (1A) is based on a total of 127 intra, 97 inter and 17 cross-strand distance constraints per strand, whereas the double A ⁶:T⁷ Hoogsteen basepaired (1B) structure is based on 114 intra, 92 inter and 15 cross-strand distance constraints, giving an average of 22 and 20 NOE distance constraints per residue and strand, respectively. In addition, 55 NMR-derived backbone dihedral constraints per strand were used for both structures. The main effect of the Hoogsteen basepairs in (1B) on the overall structure is a narrowing of the minor groove and a corresponding widening of the major groove. The Hoogsteen basepairing at the central A ⁶:T⁷ basepairs in (1B) has enforced a syn conformation on the glycosyl torsion of the 2′- deoxyaristeromycin moiety, A ⁶, as a result of substitution of the endocyclic 4′-oxygen in the natural sugar with a methylene group in A ⁶. A comparison of the Watson-Crick basepaired duplex (1A) to the Hoogsteen basepaired duplex (1B) shows that only a few changes, mainly in α, σ and γ torsions, in the sugar-phosphate backbone seem to be necessary to accommodate the Hoogsteen basepair.     

RNase H Activation by Stereoregular Boranophosphate Oligonucleotide

Abstract

A stereoregular all-(S _p)-boranophosphate oligodeoxyribonucleotide (BH₃ ^?-ODN) 15-mer was synthesized using an enzymatic approach. The BH₃ ^?-ODN formed a hybrid with the complementary RNA 15-mer and induced RNase H hydrolysis of the RNA strand at ODN concentrations as low as 10 nM at 37°C, but with a lower efficiency than that of its natural phosphodiester analogue.     

Recognition of a Flipped Base in a Hairpinloop DNA by a Small Peptide

Two tiny hairpin DNAs, CORE (dAGGCTTCGGCCT) and AP2 (dAGGCTXCGGCCT; X: abasic nucleotide), fold into almost the same tetraloop hairpin structure with one exception, that is, the sixth thymine (T6) of CORE is exposed to the solvent water (Kawakami, J. et al., Chem. Lett. 2001, 258–259). In the present study, we selected small peptides that bind to CORE or AP2 from a combinatorial pentapeptide library with 2.5 × 10⁶ variants. On the basis of the structural information, the selected peptide sequences should indicate the essential qualifications for recognition of the hairpin loop DNA with and without a flipped base. In the selected DNA binding peptides, aromatic amino acids such as histidine for CORE and glutamine/aspartic acid for AP2 were found to be abundant amino acids. This amino acid preference suggests that CORE-binding peptides use π–π stacking to recognize the target while hydrogen bonding is dominant for AP2-binding peptides. To investigate the binding properties of the selected peptide to the target, surface plasmon resonance was used. The binding constant of the interaction between CORE and a CORE-binding peptide (HWHHE) was about 1.1 × 10⁶ M^?1 at 25°C and the resulting binding free energy change at 25°C (ΔG°₂₅) was ?8.2 kcal mol^?1. The binding of the peptide to AP2 was also analyzed and the resulting binding constant and ΔG°₂₅ were about 4.2 × 10⁴ M^?1 and ?6.3 kcal mol^?1, respectively. The difference in the binding free energy changes (ΔΔG°₂₅) of 1.9 kcal mol^?1 was comparable to the values reported in other systems and was considered a consequence of the loss of π–π stacking. Moreover, the stabilization effect by stacking affected the dissociation step as well as the association step. Our results suggest that the existence of an aromatic ring (T6 base) produces new dominant interactions between peptides and nucleic acids, although hydrogen bonding is the preferable mode of interaction in the absence of the flipping base. These findings regarding CORE and AP2 recognition are expected to give useful information in the design of novel artificial DNA binding peptides.     

Distribution of P1 Type Nuclease in the Genus Penicillium

P₁ type nuclease, which hydrolyzes RNA and heat-denatured DNA completely into 5’-mononucleotides and also shows 3’-nucleotidase activity, was widely distributed among various species belonging to the genus Penicillium such as P. expansum, P. notatum, P. steckii and P. meleagrinum. P₁ type nucleases isolated from these strains were produced in a form of complex with malonogalactan when molds were grown on wheat bran. These enzymes showed similar characters in heat-stability (stable at 60°C), temperature optimum (60 to 70°C for RNA and heat denatured DNA, and 70°C for 3’-AMP) and sensitivity to EDTA. The enzymes from P. steckii and P. expansum were immunologically co-related to nuclease P₁.

In addition, many strains of Penicillium produced base-nonspecific RNases forming 3’-mononucleotides via 2’: 3 ’-cyclic nucleotides. These RNases showed similarity in heat-lability (completely inactivated at 60°C), temperature optimum (45 to 50°C), sensitivity to Zn²⁺ and Cu²⁺, and relative hydrolysis rate toward 2’: 3’-cyclic nucleotides (A?C>U?G).     

An FT-IR Study of DNA and RNA Conformational Transitions at Low Temperatures

Abstract

Fourier Transform Infrared (FT-IR) spectra of solid samples of DNA and RNA obtained from freeze-drying at solid CO₂ and liquid nitrogen temperatures, have been recorded and correlation between the conformational transitions and spectral changes is proposed. It is concluded that an equilibrium exists between A, B and Z conformations at low temperatures for the DNA molecule, which is temperature dependent, whereas the RNA molecule exhibits only the A conformation. The results have been compared with the metal-adducts of DNA and RNA, where one of the conformations is predominant.

Marker infrared bands for the B conformer have been found to be the strong band at 825 cm^?1 (sugar conformer mode) and a band with medium intensity at 690 cm^?1 (guanine breathing mode). The A conformation showed characteristic bands at 810 and 675 cm^?1. The B to Z conformational transition was characterized by the strong absorption bands near 820-810 cm^?1 and at 665-600 cm^?1.     

Na2CO3 Influence on DNA Double Helix Stability: Strong Anion Destabilizing Effect

Abstract

Addition of Na₂CO₃ to almost salt-free DNA solution (5·10^?5M EDTA, pH=5.7, Tm=26.5 °C) elevates both pH and the DNA melting temperature (Tm) if Na₂CO₃ concentration is less than 0.004M. For 0.004M Na₂CO₃, Tm=58 °C is maximal and pH=10.56. Further increase in concentration gives rise to a monotonous decrease in Tm to 37 °C for 1M N₂CO₃ (pH=10.57). Increase in pH is also not monotonous. The highest pH=10.87 is reached at 0.04M Na₂CO₃ (Tm=48.3 °C). To reveal the cause of this DNA destabilization, which happens in a narrow pH interval (10.56÷10.87) and a wide Na₂CO₃ concentration interval (0.004÷1M), a procedure has been developed for determining the separate influences on Tm of Na⁺, pH, and anions formed by Na₂CO₃ (HCO₃ ^? and CO₃ ^2-). Comparison of influence of anions formed by Na₂CO₃ on DNA stability with Cl^? (anion inert to DNA stability), ClO₄ ^? (strong DNA destabilizing “chaotropic” anion) and OH^? has been carried out. It has been shown that only Na⁺ and pH influence Tm in Na₂CO₃ solution at concentrations lower than 0.001M. However, the Tm decrease with concentration for [Na₂CO₃]≥0.004M is only partly caused by high pH≈10.7. Na₂CO₃ anions also exert a strong destabilizing influence at these concentrations. For 0.1M Na₂CO₃ (pH=10.84, [Na⁺]=0.2M, Tm=42.7 °C), the anion destabilizing effect is higher 20 °C. For NaClO₄ (ClO₄ ^? is a strong “chaotropic” anion), an equal anion effect occurs at much higher concentrations ～3M. This means that Na₂CO₃ gives rise to a much stronger anion effect than other salts. The effect is pH dependent. It decreases fivefold at neutral pH after addition of HCl to 0.1M Na₂CO₃ as well as after addition of NaOH for pH>11.2.     

Bioaccumulation of Gold by Filamentous Cyanobacteria Between 25 and 200°C

Plectonema boryanum UTEX 485 was reacted with aqueous AuCl ₄ ^? solutions ( ～ 2 mM Au) at 25 to 100°C for 1 month, and 200°C for one day. Addition of AuCl₄ ^? to cyanobacteria killed the cultures instantly, and Au was precipitated throughout the cells as nanoparticles. Precipitation of octahedral crystal platelets of Au occurred in the aqueous fluid, with particle size increasing with increase in temperature from about 1.5 μ m at 25°C to 10 μ m at 100°C. Addition of AuCl₄ ^? to suspensions of the dead, autoclaved cyanobacteria also precipitated Au from solution, suggesting that the presence of cell degradation products caused instability of AuCl₄ ^? .     

Left-handed Z Form in Superhelical DNA: A Theoretical Study

Abstract

This is a comprehensive statistical mechanical treatment of the Z form formation in purine- pyrimidine stretches of different length inserted into superhelical DNA. The B-Z transition for short inserts is shown to follow the “all-or-none” principle. Over some critical value of the insert length n, the B-Z transition in the insert proceeds in two stages. The flipping of m base pairs into the Z form is followed by a gradual growth of the Z-form stretch until it occupies the whole insert. By fitting the theoretical transition curves to experimental ones the fundamental thermodynamic parameters of the B-Z transition have been determined: the B-Z junction energy Fj = 4–5kcal?mol^?1 and the free energy change ΔF_B-Z = 0.5–0.7 kcal?mol^?1 under standard salt conditions. Calculations show that the B-Z transition in short purine-pyrimidine inserts may be seriously affected by cruciform formation in the carrier DNA.     

Binding of the Recombinant Proteinase Inhibitor Eglin c,of the Soybean Bowman-Birk Proteinase Inhibitor and of its Chymotrypsin and Trypsin Inhibiting Fragments to Leu-Proteinase,the Leucine Specific Serine Proteinase from Spinach (Spinacia oleracea L.) Leaves: Thermodynamic Study

Abstract

The effect of pH and temperature on the apparent association equilibrium constant (K_a) for the binding of the recombinant proteinase inhibitor eglin c (eglin c), of the soybean Bowman-Birk proteinase inhibitor (BBI) and of its chymotrypsin and trypsin inhibiting fragments (F-C and F-T, respetively) to Leuproteinase, the leucine specific serine proteinase from spinach (Spinacia oleracea L.) leaves, has been investigated. On lowering the pH from 9.5 to 4.5, values of K_a (at 21°C) for complex formation decrease thus reflecting the acidic pK-shift of the hystidyl catalytic residue from ～6.9, in the free Leu-proteinase, to ～5.1, in the enzyme: inhibitor adducts. At pH 8.0, values of the apparent thermodynamic parameters for the proteinase:inhibitor complex formation are: Leu-proteinase:eglin c - K_a = 2.2 × 10¹¹ M^-1, δG°= - 64kJ/mol, δH° = + 5.9kJ/mol, and δS° = + 240J/molK; Leu-proteinase:BBI - K_a = 3.2 × 10¹⁰ M^-1, δG° = - 59kJ/mol, δH°= + 8.8kJ/mol, and δS° = + 230J/molK; and Leu-proteinase:F-C - K_a = 1.1 × 10⁶ M^-1, δG°= - 34kJ/mol, δH° = + 18J/mol, and δS° = + 180J/molK (values of K_a, δG° and δS° were obtained at 21.0°C; values of δH° were temperature-independent over the range explored, i.e. between 10.0°C and 40.0°C). F-T does not inhibit Leu-proteinase up to an inhibitor concentration of 1.0 × 10^-3 M, suggesting that the upper limit of K_a is 1 × 10² M^-1. Considering the known molecular models, the observed binding behaviour of eglin c, BBI, F-C and F-T to Leu-proteinase has been related to the inferred stereochemistry of the enzyme/inhibitor contact region     

DNA binding,prominent photonuclease activity and antibacterial PDT of cobalt(II) complexes of phenanthroline based photosensitizers

Abstract

The chemistry of Co(II) complexes showing efficient light induced DNA cleavage activity, binding propensity to calf thymus DNA and antibacterial PDT is summarized in this article. Complexes of formulation [Co(mqt)(B)₂]ClO₄ 1–3 where mqt is 4-methylquinoline-2-thiol and B is N,N-donor heterocyclic base, viz. 1,10-phenanthroline (phen 1), dipyrido[3,2-d:2′,3′-f]quinoxaline (dpq 2) and dipyrido[3,2-a:2′,3′-c]phenazine (dppz 3) have been prepared and characterized. The DNA-binding behaviors of these three complexes were explored by absorption spectra, viscosity measurements and thermal denaturation studies. The DNA binding constants for complexes 1, 2 and 3 were determined to be 1.6?×?10³?M^?1, 1.1?×?10⁴?M^?1 and 6.4?×?10⁴?M^?1 respectively. The experimental results suggest that these complexes interact with DNA through groove binding mode. The complexes show significant photocleavage of supercoiled (SC) DNA proceeds via a type-II process forming singlet oxygen as the reactive species. Antimicrobial photodynamic therapy was studied using photodynamic antimicrobial chemotherapy (PACT) assay against E. coli and all complexes exhibited significant reduction in bacterial growth on photoirradiation.     

Improving operational stability of thermostable Pythium myriotylum secretory serine protease by preparation of cross-linked enzyme aggregates (CLEAs)

Abstract

Present study was undertaken to develop cross-linked enzyme aggregate (CLEA)of alkaline serine proteases (sp) from Pythium myriotylum (Pm), a necrotrophic oomycete reported to considerably secrete serine proteases. Among various precipitants screened for spPm1-CLEA preparation, ammonium sulfate at 80% saturation (w/v) yielded 100% activity recovery and retention of spherical morphology as observed by SEM analysis. Addition of glutaraldehyde as cross-linker at 1% (v/v) concentration with optimized ammonium sulfate concentration for 1?hour at 100?rpm yielded 100% activity recovery of spPm1-CLEA from 8-day old P. myriotylum culture filtrate. Addition of BSA (10?mg/ml) to CLEA cross-linking reaction mix reduced CLEA size from the range of 1.82–1.19?µm to 394–647?nm. spPm1-CLEA preparations retained 100% activity at temperature of 80?°C and pH 12.0 signifying their potential commercial applications. In terms of kinetic parameters, present process enhanced kinetic parameters as revealed by 1.67?U.mg^?1 specific activity, K_m of 0.062?mM and V_max of 0.145?µmol.min^?1.mg^?1 for the spPm1-CLEA compared to 0.288?U.mg^?1 specific activity, K_m of 0.060?mM and V_max of 0.20?µmol.min^?1.mg^?1 determined for the free spPm1 enzyme. Study has successfully demonstrated the concept of CLEA in enhancing spPm1 stability and the results so generated can be translated in future towards development of robust biocatalysts.     

The Influence of Nearest Neighbours on the Efficiency of Coaxial Stacking at Contiguous Stacking Hybridization of Oligodeoxyribonucleotides

Contiguous stacking hybridization of oligodeoxyribonucleotides with a stem of preformed minihairpin structure of a DNA template was studied with the use of UV‐melting technique. It was shown that the free‐energy of the coaxial stacking interaction (ΔG°_ST at 37°C, 1 M NaCl, pH 7.4) at the complementary interface XA^*pTY/ZATV (an asterisk stands for a nick) strongly depends on the type of nearest neighbor bases X and Y flanking the nicked dinucleotide step. The maximum efficiency of the coaxial stacking was observed for the PuA^*pTPy/PuATPy interface, whereas the minimum efficiency was obtained for the PyA^*pTPu/PyATPu interface. A 5′‐phosphate residue in the nick enhances the coaxial stacking. In dependence on duplex structure the observed efficiency of A^*T/AT coaxial stacking varied from (? 0.97 kcal/mol) for unphosphorylated TA^*TA/TATA interface to three‐fold higher value (? 2.78 kcal/mol) for GA^*pTT/AATC interface.     

Thermodynamics of cyclophilin catalyzed peptidyl-prolyl isomerization by nmr spectroscopy

One-dimensional nmr exchange spectroscopy was carried out to determine thermodynamic parameters of cyclophilin-induced cis-trans isomerization of succinyl-Ala-Phe-Pro-Phe-p-nitroanilide. Rate measurements were possible at physiological temperatures. The k_c/K_m of rat cyclophilin was found to he 12.8 (±0.5) s^?1 μM^?1 at 37°C, intermediate to previously reported values that used a coupled enzyme assay extrapolated to this temperature. Activation energies (ΔG^≠) for the uncatalyzed and catalyzed reaction at 37°C were found to be 19.7 and 17.1 kcal/mol, respectively, and were primarily due to an enthalpic barrier. © 1994 John Wiley & Sons, Inc.     

A Theoretical Model for the Binding of Cis-Pt(NH3)2 +2 to DNA

Abstract

The binding of cis-Pt(NH₃)₂B₁B2 to the bases B₁ and B₂, i.e., guanine (G), cytosine (C), adenine (A), and thymine (T), of DNA is studied theoretically. The components of the binding are analyzed and a model structure is proposed for the intrastrand binding to the dB,pdB₂ sequence of a kinked double helical DNA. Quantum mechanical calculations of the ligand binding energy indicates that cw-Pt(NH₃)₂ ⁺² (cis-PDA) binds to N7(G), N3(C), 02(C), 06(G), N3(A), N7(A), 04(T) and 02(T) in order of decreasing binding energy. Conformational analysis provides structures of kinked DNA in which adjacent bases chelate to cis-PDA. Only bending toward the major groove allows the construction of acceptable square planar complexes. Examples are presented for kinks of ?70° and ?40° at the receptor site to orient the base pairs for ligand binding to B, and B₂ to form a nearly square planar complex. The energies for complex formation of cis-PDA to the various intra-strand base sites in double stranded DNA are estimated. At least 32 kcal/mole separates the energetically favorable dGpdG·cis-PDA chelate from the dCpdG·cis-PDA chelate. All other possible chelate structures are much higher in energy which correlates with their lack of observation in competition with the preferred dGpdG chelate.

The second most favorable ligand energy occurs with N3(C). A novel binding site involving dC(N3)pdG(N7) is examined. Denaturation can result in an anti ? syn rotation of C about its glycosidic bond to place N3(C) in the major groove for intrastrand binding in duplex DNA. This novel intrastrand dCpdG complex and the most favored dGpdG structure are illustrated with stereographic projections.     

More pronounced salt dependence and higher reactivity for platination of the hairpin r(CGCGUUGUUCGCG) compared with d(CGCGTTGTTCGCG)

The DNA interference pathways exhibited by cisplatin and related anticancer active metal complexes have been extensively studied. Much less is known to what extent RNA interaction pathways may operate in parallel, and perhaps contribute to both antineoplastic activity and toxicity. The present study was designed with the aim of comparing the reactivity of two model systems comprising RNA and DNA hairpins, r(CGCGUUGUUCGCG) and d(CGCGTTGTTCGCG), towards a series of platinum(II) complexes. Three platinum complexes were used as metallation reagents; cis-[PtCl(NH₃)₂(OH₂)]⁺ (1), cis-[PtCl(NH₃)(c-C₆H₁₁NH₂)(OH₂)]⁺ (2), and trans-[PtCl(NH₃)(quinoline)(OH₂)]⁺ (3). The reaction kinetics were studied at pH 6.0, 25 °C, and 1.0 mM ≤ I ≤ 500 mM. For both types of nucleic acid targets, compound 3 was found to react about 1 order of magnitude more rapidly than compounds 1 and 2. Further, all platinum compounds exhibited a more pronounced salt dependence for the interaction with r(CGCGUUGUUCGCG). Chemical and enzymatic cleavage studies revealed similar interaction patterns with r(CGCGUUGUUCGCG) after long exposure times to 1 and 2. A substantial decrease of cleavage intensity was found at residues G4 and G7, indicative of bifunctional adduct formation. Circular dichroism studies showed that platinum adduct formation leads to a structural change of the ribonucleic acid. Thermal denaturation studies revealed platination to cause a decrease of the RNA melting temperatures by 5–10 °C. Our observations therefore suggest that RNA is a kinetically competitive target to DNA. Furthermore, platination causes destabilization of RNA structural elements, which may lead to deleterious intracellular effects on biologically relevant RNA targets.Electronic supplementary material Supplementary material is available in the online version of this article at and is accessible for authorized users.