We report the 2.4 A resolution X-ray structure of a complex in which a small molecule flips a base out of a DNA helical stack. The small molecule is a metalloporphyrin, CuTMPyP4 [copper(II) meso-tetra(N-methyl-4-pyridyl)porphyrin], and the DNA is a hexamer duplex, [d(CGATCG)]2. The porphyrin system, with the copper atom near the helical axis, is located within the helical stack. The porphyrin binds by normal intercalation between the C and G of 5' TCG 3' and by extruding the C of 5' CGA 3'. The DNA forms a distorted right-handed helix with only four normal cross-strand Watson-Crick base pairs. Two pyridyl rings are located in each groove of the DNA. The complex appears to be extensively stabilized by electrostatic interactions between positively charged nitrogen atoms of the pyridyl rings and negatively charged phosphate oxygen atoms of the DNA. Favorable electrostatic interactions appear to draw the porphyrin into the duplex interior, offsetting unfavorable steric clashes between the pyridyl rings and the DNA backbone. These pyridyl-backbone clashes extend the DNA along its axis and preclude formation of van der Waals stacking contacts in the interior of the complex. Stacking contacts are the primary contributor to stability of DNA. The unusual lack of van der Waals stacking contacts in the porphyrin complex destabilizes the DNA duplex and decreases the energetic cost of local melting. Thus extrusion of a base appears to be facilitated by pyridyl-DNA steric clashes.
The regions upstream from forty-three procaryotic promoters were examined for nucleotide distributions which have been associated with DNA curvature. The analysis procedure assigned a DNA curvature score based on the phasing of the 5' and 3' ends of An and Tn tracts, n greater than or equal to 3. The weighting scheme for the curvature score was based on recent studies which showed that tracts of An and Tn periodically phased with the helix repeat cause DNA curvature. Results show that promoters which have high transcription initiation rates in vivo tend to have high curvature scores in their upstream regions. Regions downstream from the transcription start-point do not have sequences correlated with DNA curvature. Four promoters which have been shown to have upstream activation regions have curvature scores above 1.5 in their -40 to -150 regions. The correlations observed lend support to the hypothesis that DNA curvature is associated with upstream activation of transcription.
X-ray structures of trypsin from bovine pancreas inactivated by diphenyl [N-(benzyloxycarbonyl)amino](4-amidinophenyl)methanephosphonate [Z-(4-AmPhGly)P(OPh)2] were determined at 113 and 293 K to 1.8 angstrom resolution and refined to R factors of 0.211 (113 K) and 0. 178 (293 K). The structures reveal a tetrahedral phosphorus covalently bonded to the O gamma of the active site serine. Covalent bond formation is accompanied by the loss of both phenoxy groups. The D-stereoisomer of Z-(4-AmPhGly)P-(OPh)2 is not observed in the complex. The L-stereoisomer of the inhibitor forms contacts with several residues in the trypsin active site. One of the phosphonate oxygens is inserted into the oxyanion hole and forms hydrogen bonds to the amides of Gly193, Asp194, and Ser195. The second phosphonate oxygen forms hydrogen bonds to N epsilon 2 of His 57. The p-amidinophenylglycine moiety binds into the trypsin primary specificity pocket, interacting with Asp189. The amide forms a hydrogen bond to the carbonyl oxygen atom of Ser214. The inhibitor moiety, from the 113 K structure of trypsin inactivated by the reaction product of Z-(4-AmPhGly)P(OPh)2, was docked into human thrombin [Bode, W., Mayr, I., Baumann, U., Huber, R., Stone, S. R., & Hofsteenge, J. (1989) EMBO J. 8, 3467-3475] and energy minimized. The inhibitor fits well into the thrombin active site, forming favorable contacts similar to those in the trypsin complex with no bad contacts.
A series of 7-amino-4-chloro-3-(3-isothioureidopropoxy)isocoumarin (NH2-CiTPrOIC) derivatives with various substituents at the 7- and 3-positions have been synthesized as inhibitors of several blood coagulation enzymes. Isocoumarins substituted with basic groups such as guanidino or isothioureidoalkoxy groups were previously shown to be potent irreversible inhibitors of blood coagulation enzymes [Kam et al. Biochemistry 1988, 27, 2547-2557]. Substituted isocoumarins with an isothioureidoethoxy group at the 3-position and a large hydrophobic group at the 7-position are better inhibitors for thrombin, factor VIIa, factor Xa, factor XIa, factor IIa, and factor IXa than NH2-CiTPrOIC (4). PhNHCONH-CiTEtOIC (14), (S)-Ph(CH3)CHNHCONH-CiTEtOIC (25), and (R)-Ph(CH3)CHNHCONH-CiTEtOIC (26) inhibit thrombin quite potently and have kobs/[I] values of (1-4) x 10(4) M-1 s-1. Modeled structures of several isocoumarins noncovalently complexed with human alpha-thrombin suggest that H-bonding between the 7-substituent and the Lys-60F NH3+ relates to the inhibitory potency. Thrombin inhibited by 14, 25, or 26 is quite stable, and only 4-16% of enzymatic activity is regained after incubation for 20 days in 0.1 M Hepes, pH 7.5 buffer. However, 100, 67, and 65% of enzyme activity, respectively, is regained with the addition of 0.38 M hydroxylamine. With normal citrated pig or human plasma, these isocoumarin derivatives prolong the prothrombin time ca. 1.3-3.1-fold and also prolong the activated partial thromboplastin time more than 3-7-fold at 32 microM. Thus, these compounds are effective anticoagulants in vitro and may be useful in vivo.
The influence of inverted repeat sequences on the melting transitions of linear DNAs has been examined. Derivative melting curves (DMC) of a 514 base pair (bp) DNA, seven subfragments of this DNA, and four other DNAs have been compared to predictions of DNA melting theory. The 514-bp DNA contains three inverted repeat sequences that can form cruciform structures in supercoiled DNA. We refer to these sequences as c-inverted repeats. Previous work showed that the DMC of this DNA, unlike a number of other DNAs, is not accurately predicted by DNA melting theory. Since the theoretical model does not include hairpin-like structures, it was suggested that hairpin or cruciform formation in these inverted repeats may be responsible for this discrepancy. Our results support this hypothesis. Predicted DMCs are in good agreement with DNAs with no inverted repeats, or inverted repeats not evident in supercoiled DNA. Differences between the theoretical and experimental Tm's are less than or equal to 0.3 degrees C. DNA molecules that contain one or more of the three c-inverted repeats are not as accurately predicted. Experimental Tm values are lower than predicted values by 0.7-3.8 degrees C. It is concluded that some inverted repeat sequences can form hairpin-like structures during the melting of linear DNAs. These structures appear to lower overall DNA stability.
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