New steroid-fused P-heterocycles. Part I. Synthesis and conformational study of dioxaphosphorino[16,17-d]estrone derivatives

D-ring-fused dioxaphosphorinanes (4-6) in the estrone series were synthetized as epimeric pairs and investigated by NMR and computational methods in order to determine their stereostructures and predominant conformations. The study was performed to evaluate the influence of the rigid sterane framework on the geometry of the condensed hetero ring, with regard to the possible steric effect of the angular methyl group at position 13. Additionally, the steric and electronic effects of the P-substituents on the conformational equilibrium were examined. The distorted-boat conformation of the hetero ring of dioxaphosphorinoestrone 3-methyl ether 4a was confirmed by single-crystal X-ray analysis. This is in good agreement with the observation in solution that, in the case of the boat conformation, the anisotropic shielding effect of the phenyl group of cyclic phosphonate 4a generates an upfield shift for 17-H, as compared with the corresponding chemical shift for epimer 4b. A similar boat conformation was substantiated for derivatives 4b, 5a, 5b and 6b on the basis of the J(H, H) and J(H, P) coupling constants and also ab initio calculations, regardless of the P-configuration. At the same time, the hetero ring of 6a seems to tilt towards a chair-like conformation due to the strong equatorial preference of the N-bis(2-chloroethyl) group.     

Conformational properties of branched RNA fragments in aqueous solution

The conformational properties of branched trinucleoside diphosphates ACC, ACG, AGC, AGG, AUU, AGU, AUG, ATT, GUU, and aAUU [XYZ = X(2'p5'Y)3'p5'Z] have been studied in aqueous solution by nuclear magnetic resonance (1H, 13C), ultraviolet absorption, and circular dichroism. It is concluded from these studies that the purine ring of the central residue (X; e.g., adenosine) forms a base-base stack exclusively with the purine or pyrimidine ring of the 2'-nucleotidyl unit (Y; 2'-residue). The residue attached to the central nucleoside via the 3'-5'-linkage (Z; 3'-residue) is "free" from the influence of the other two heterocyclic rings. The ribose rings of the central nucleoside and the 2'- and 3'-residues exist as equilibrium mixtures of C2'-endo (2E)-C3'-endo (3E) conformers. The furanose ring of the central nucleoside (e.g., A) when linked to a pyrimidine nucleoside via the 2'-5'-linkage shows a higher preference for the 2E pucker conformation (e.g., AUG, AUU, ACG, ca. 80%) than those linked to a guanosine nucleoside through the same type of bond (AGU, AGG, AGC, ca. 70%). This indicates some correlation between nucleotide sequence and ribose conformational equilibrium. The 2E-3E equilibrium of 2'-pyrimidines (Y) shows significant, sometimes exclusive, preference (70-100%) for the 3E conformation; 3'-pyrimidines and 2'-guanosines have nearly equal 2E and 3E rotamer populations; and the ribose conformational equilibrium of 3'-guanosines shows a preference (60-65%) for the 2E pucker. Conformational properties were quantitatively evaluated for most of the bonds (C4'-C5', C5'-O5', C2'-O2', and C3'-O3') in the branched "trinucleotides" AUU and AGG by analysis of 1H-1H, 1H-31P, and 13C-31P coupling constants. The C4'-C5' bond of the adenosine units shows a significant preference for the gamma + conformation. The dominant conformation about C4'-C5' and C5'-O5' for the 2'-and 3'-nucleotidyl units is gamma + and beta t, respectively, with larger gamma + and beta t rotamer populations for the 2'-unit. The increased conformational purity in the 2'-residue, compared to the 3'-residue, is ascribed to the presence of an ordered (adenine----2'-residue) stacked state. The favored rotamers about C3'-O3' and C2'-O2' are epsilon- and epsilon'-, respectively. The conformational features of AUU and AGG were compared to those of their constitutive dimers A3'p5'G, A2'p5'G, A3'p5'U, and A2'p5'U and monomers 5'pG and 5'pU.     

Structure and mechanistic implications of a uroporphyrinogen III synthase-product complex

Uroporphyrinogen III synthase (U3S) catalyzes the asymmetrical cyclization of a linear tetrapyrrole to form the physiologically relevant uroporphyrinogen III (uro'gen III) isomer during heme biosynthesis. Here, we report four apoenzyme and one product complex crystal structures of the Thermus thermophilus (HB27) U3S protein. The overlay of eight crystallographically unique U3S molecules reveals a huge range of conformational flexibility, including a "closed" product complex. The product, uro'gen III, binds between the two domains and is held in place by a network of hydrogen bonds between the product's side chain carboxylates and the protein's main chain amides. Interactions of the product A and B ring carboxylate side chains with both structural domains of U3S appear to dictate the relative orientation of the domains in the closed enzyme conformation and likely remain intact during catalysis. The product C and D rings are less constrained in the structure, consistent with the conformational changes required for the catalytic cyclization with inversion of D ring orientation. A conserved tyrosine residue is potentially positioned to facilitate loss of a hydroxyl from the substrate to initiate the catalytic reaction.     

13C NMR studies of complexes of Escherichia coli dihydrofolate reductase formed with methotrexate and with folic acid.

13C NMR studies of 13C-labelled ligands bound to dihydrofolate reductase provide (DHFR) a powerful means of detecting and characterizing multiple bound conformations. Such studies of complexes of Escherichia coli DHFR with [4,7,8a,9-13C]- and [2,4a,6-13C]methotrexate (MTX) and [4,6,8a-13C]- and [2,4a,7,9-13C]folic acid confirm that in the binary complexes, MTX binds in two conformational forms and folate binds as a single conformation. Earlier studies on the corresponding complexes with Lactobacillus casei DHFR indicated that, in this case, MTX binds as a single conformation whereas folate binds in multiple conformational forms (both in its binary complex and ternary complex with NADP+); two of the bound conformational states for the folate complexes are very different from each other in that there is a 180 degrees difference in their pteridine ring orientation. In contrast, the two different conformational states observed for MTX bound to E. coli DHFR do not show such a major difference in ring orientation and bind with N1 protonated in both forms. The major difference appears to involve the manner in which the 4-NH2 group of MTX binds to the enzyme (although the same protein residues are probably involved in both interactions). Addition of either NADP+ or NADPH to the E. coli DHFR-MTX complex results in a single set of 13C signals for bound methotrexate consistent with only one conformational form in the ternary complexes.     

Conformational analysis of some phenethylamine molecules

A set of empirical potential functions (EPF), previously used in conformational energy calculations of polymers, was employed in the study of the conformational properties of a number of methyl-substituted phenethylmines, as well as phenylmethylamine, phenyl-n-propylamine, and 3,4,5-trimethoxyamphetamine. The conformational free energy was computed for each of these molecular species in four states: neutral charge-vacuo (I), neutral charge-aqueous solution (II), positive charge-vacuo (III), positive charge-aqueous solution (IV). The molecules generally adopt one of two stable conformations: a folded conformation with the amine chain perpendicular to the ring, and the amine group nearest to the ring; and an extended conformation with the amine chain perpendicular to the ring, and the amine group far from the ring. The folded conformation is usually preferred for states I, II and III, while the extended form is adopted for state IV. By using empirical potential functions it was also possible to calculate the conformational entropies associated with the minimum energy conformations, thereby allowing the Boltzmann probabilities to be determined. These probabilities are a measure of the population density of each of the various low energy regions. Some of the molecules studied have a steric “bulge” below the plane of the benzene ring. All of the compounds studied which possess this “bulge” are psychotropically inactive, and, in most cases, also pharmacologically inactive. All active compounds studied do not possess this “bulge”.     

8-Chloroguanosine: solid-state and solution conformations and their biological implications

The three-dimensional structure of 8-chloroguanosine dihydrate was determined by X-ray crystallography. The crystals belong to the orthorhombic space group P2(1)2(1)2(1), and the cell dimensions are a = 4.871 (1) A, b = 12.040 (1) A, and c = 24.506 (1) A. The structure was determined by direct methods, and least-squares refinement, which included all hydrogen atoms, converged at R = 0.031 for 1599 observed reflections. The conformation about the glycosidic bond is syn with chi CN = -131.1 degrees. The ribose ring has a C(2')-endo/C-(1')-exo (2T1) pucker, and the gauche+ conformation of the -CH2OH side chain is stabilized by an intramolecular O-(5')-H...N(3) hydrogen bond. Conformational analysis by means of 1H NMR spectroscopy showed that, in dimethyl sulfoxide, the sugar ring exhibits a marked preference for the C(2')-endo conformation (approximately 70%) and a conformation about the glycosidic bond predominantly syn (approximately 90%), hence similar to that in the solid state. However, the conformation of the exocyclic 5'-CH2OH group exhibits only a moderate preference for the gauche+ rotamer (approximately 40%), presumably due to the inability to form the intramolecular hydrogen bond to N(3) in a polar medium. The conformational features are examined in relation to the behavior of 8-substituted purine nucleosides in several enzymatic systems, with due account taken of the steric bulk and electronegativities of the 8-substituents.     

DFT study of alpha- and beta-D-allopyranose at the B3LYP/6-311++G ** level of theory

One hundred and two conformations of alpha- and beta-D-allopyranose, the C-3 substituted epimer of glucopyranose, were geometry optimized using the density functional, B3LYP, and the basis set, 6-311++G **. Full geometry optimization was performed on different ring geometries and on the hydroxymethyl rotamers (gg/gt/tg). Analytically derived Hessians were used to calculate zero point energy, enthalpy, and entropy. The lowest energy and free energy conformation found is the alpha-tg(g-)-4C1-c conformation, which is only slightly higher in electronic (approximately 0.2 kcal/mol) and free energy than the lowest energy alpha-D-glucopyranose. The in vacuo calculations showed a small (approximately 0.3 kcal/mol) energetic preference for the alpha- over the beta-anomer for allopyranose in the 4C1 conformation, whereas in the 1C4 conformation a considerable (approximately 1.6 kcal/mol) energetic preference for the beta- over the alpha-anomer for allopyranose was encountered. The results are compared to previous aldohexose calculations in vacuo. Boat and skew forms were found that remained stable upon gradient optimization although many starting boat conformations moved to other skew forms upon optimization. As found for glucose, mannose, and galactose the orientation and interaction of the hydroxyl groups make the most significant contributions to the conformation/energy relationship in vacuo. A comparison of different basis sets and density functionals is made in the Discussion section, confirming the appropriateness of the level of theory used here.     

Synthesis and evaluation of novel heterocyclic inhibitors of GSK-3

A set of novel heterocyclic pyrimidyl hydrazones has been synthesized as inhibitors of glycogen synthase kinase-3 (GSK-3) with the most active exhibiting low nanomolar activity. Quantum mechanical calculations indicate that of the conformational factors that could determine binding affinity, the planarity of the phenyl ring in relation to the central core and the conformation of the hydrazone chain may be the most influential.     

Synthesis and conformation of four 16,17-diols in the 3-methoxy-13alpha-estra-1,3,5(10)-triene series

All four diasteromeric 16,17-diols in the 3-methoxy-13alpha-estra-1,3,5(10)-triene series have been synthesized. The trans-diols 1 and 2 can be obtained by hydroborating the 17-enol acetate 6 (61%, ratio 27:73, preferred alpha attack). OsO(4) dihydroxylation of the olefin 7 yielded the cis-diols 3 and 4 (ratio 13:87). The dihydroxylation proceeds with preference for beta attack caused by a C-ring twist-boat form of 7. The conformations of the diols 2 and 4, the 17-benzyl-17-hydroxy compounds 9 and 10 (obtained by Grignard reaction), and the 16alpha-bromo-17beta-hydroxy compound 8 were determined by X-ray analysis and by 1H NMR spectroscopy in solution. Some compounds, in spite of a 17beta-hydroxy group, had a conformation with a ring C chair form (4, 8, 9) caused by intermolecular interaction in the solid state. The rest of the compounds studied here (2, 10) possessed a conformation with a ring C twist-boat form, which has been also found for all 17beta-substituted compounds in solution. The preferred conformation of the D-ring with 17beta-substituents seems to be the 16beta-envelope form or near this form, but the existence of the 16alpha-envelope form (inversion of the ring D) for some compounds showed great variance in the conformation of ring D, which is substituent dependent.     

Absolute configurations and conformations of the opioid agonist and antagonist enantiomers of picenadol

The absolute configurations of the enantiomers of the opiod picenadol [cis-1,3-dimethyl-4-propyl-4-propyl-4-(3-hydroxyphenyl)piperidine; cis-3-methyl, 4-propyl] have been determined by an X-ray crystallographic study of the chloride salt of the (+)-enantiomer. The agonist (+)-enantiomer and the antagonist (?)-enantiomer were found to have the 3R, 4R and 3S, 4S absolute configurations, respectively. The conformational properties of the enantiomers were also examined with MM2–87 calculations. There was good agreement between the computed global minimum and the crystallographic structure with the phenyl ring approximately bisecting the piperidine ring by both methods. This orientation of the phenyl ring differs from that of related opioids such as the phenylmorphans, prodines, meperidine, and ketobemidone in which the phenyl ring tends to eclipse one edge of the piperidine ring. Because the phenyl ring bisects the piperidine ring in picenadol, there is little difference in the three-dimensional orientations of the phenyl rings of the two enantiomers when one superimposes the piperidine rings. The agonist (+)-enantiomer is ambiguous with respect to an opioid ligand model, which suggests that agonist activity requires a specific range of dihedral angles for the phenyl ring. While the global minimum of the agonist is not consistent with the model, a second conformer that is only 1.2 kcal/mol above the global minimum is consistent. An alternative explanation is that agonist or antagonist activity is solely due to the presence of the 3-methyl group on the different edges of the piperidine ring. MM2–87 calculations were also performed on the opioid agonist des-3-methyl analog of picenadol and the closely related trans-1,3,4-trimethyl-4-(3-hydroxyphenyl)piperidines (trans-3-methyl, 4-methyl) in which both enantiomers are opioid antagonists. The conformational properties of these compounds are consistent with the ligand model. © 1995 Wiley-Liss, Inc.     

A nuclear magnetic resonance study of the ribotrinucleoside diphophate UpUpC

500 MHz 1H, 67.89 MHz 13C and 80.97 MHz 31P-NMR studies are reported on the ribotrinucleoside diphosphate UpUpC, the triplet codon corresponding to the amino acid phenylalanine. Complete spectral assignments are given and conformational parameters for the backbone and the furanose rings are determined. All three nucleotide units show a near-balance for the N/S equilibrium with a slight preference for the N-type ribose (approximately 60%). The backbone conformation around the C3'-03' bonds show a preference for the trans domain, while the orientation around the C5'-05' bonds is predominantly trans.     

Conformations of cyclic 3',5'-nucleotides. Effect of the base on the synanti conformer distribution

The furanose and the phosphate rings of cyclic 3′,5′-nucleotides are locked in the ₄T³ and chair conformations respectively. The only variable which shows major conformational flexibility in these molecules is the rotation about the glycosyl bond which describes the orientation of the base relative to the sugar-phosphate bicyclic system. The glycosyl torsion angle has been analyzed for cyclic nucleotides with different purine and pyrimidine bases by use of conformational energy calculations. The results indicate that all the pyrimidine bases, U, T and C show a very strong energetic preference for the anti range of conformations. The calculations predict that among cyclic 3′,5′-purine nucleotides cyclic GMP and cyclic IMP favor the syn conformation to the anti by 95:5 and 70:30 respectively, while cyclic AMP shows a preference for the anti conformation to syn by 70:30. Thus the purines show a greater probability for the syn conformation than the pyrimidines in cyclic 3′,5′-nucleotides.     

A comparative molecular modeling study of dydrogesterone with other progestational agents through theoretical calculations and nuclear magnetic resonance spectroscopy

6-Dehydroretroprogesterone (dydrogesterone) and three other natural or synthetic progestins (progesterone, retroprogesterone, and 6-dehydroprogesterone) were submitted to a conformational study through theoretical calculations at the B3LYP/6-31G(*) level and high field NMR spectroscopy. The study allows to define the role of the two structural features which differentiate these steroids, i.e., the C9 and C10 configuration and the C6-C7 unsaturation. The combined effects of the conformational preference of A ring, determined by the configuration at C9 and C10, and the enhanced rigidity due to the C6-C7 double bond, could account both for the higher activity and selectivity of dydrogesterone with respect to the other three steroids.     

CNDO/2 molecular orbital calculations on the antifolate DAMP and some related species: structural geometries, ring distortions, change distributions and conformational characteristics

Geometry-optimized CNDO/2 molecular orbital calculations were carried out on 2, 4-diamino-5-(1-adamantyl 1)-6-methyl pyrimidine (DAMP), a potent inhibitor of mammalian dihydrofolate reductase which is now in clinical trials, and on its inactive 5-(1-naphthyl) analogue (DNMP-1). Crystallographic data show that DAMP (as the ethylsulfonate salt) has a severely distorted, N1 protonated, pyrimidine ring and has steric crowding of the 6-methyl and adamantyl hydrogens whereas DNMP-2 (as a methanol complex) has a planar, nonprotonated pyrimidine ring that is nearly perpendicular to the naphthalene ring. The CNDO/2 results largely reproduce the crystal structure geometry and show that the ring distortions in DAMP are initiated by steric conflicts between the adamantyl group and the 4- and 6-substituents on the ring. In DNMP-1, the non-interfering naphthyl ring induces little strain within the pyrimidine ring and the effect of protonation is negligible. Rotation about the bond joining the two ring groups is restricted in DAMP by a broad barrier of ca. 8.0 kcal mol-1, and no conformation was successful in relieving steric conflicts and hence reducing the ring distortions. In DNMP-1, rotation is less hindered overall with a broad region of accessible conformational space and a maximum barrier of ca. 7.2 kcal mol-1 for the coplanar conformation. The electronic charge distributions of DAMP and DNMP-1 are almost identical and protonation is preferred at N1 rather than at N3 by ca. 3.7 kcal mol-1 for both DAMP and DNMP-1. The calculations establish that the present methodology can be useful as a predictive tool with regard to the structure and conformational characteristics of these and related species.     

Theoretical study of the structure of adenosine deaminase complexes with adenosine analogues: I. Aza-, deaza- and isomeric azadeazaanalogues of adenosine

The conformational models of the active site of adenosine deaminase (ADA) and its complexes in the basic state with adenosine and 13 isosteric analogues of the aza, deaza, and azadeaza series were constructed. The optimization of the conformational energy of the active site and the nucleoside bound with it in the complex was achieved in the force field of the whole enzyme (the 1ADD structure was used) within the molecular mechanics model using the AMBER 99 potentials. The stable conformational states of each of the complexes, as well as the optimal conformation of the ADA in the absence of ligand, were determined. It was proved that the conformational state that is close to the structure of the ADA complex with 1-deazaadenosine (1ADD) known from the X-ray study corresponds to one of the local minima of the potential surface. Another, a significantly deeper minimum was determined; it differs from the first minimum by the mutual orientation of side chains of amino acid residues. A similar conformational state is optimal for the ADA active site in the absence of the bound ligand. A qualitative correlation exists between the values of potential energies of the complexes in this conformation and the enzymatic activity of ADA toward the corresponding nucleosides. The dynamics of conformational conversions of the active site after the binding of substrate or its analogues, as well as the possibility of the estimation of the inhibitory properties of nucleosides on the basis of calculations, are discussed.     

Identification of a major human serum DNA-binding protein as beta 1H of the alternative pathway of complement activation

The conformation of the molecule cyclo (Aha-$\text{Cys-Phe-D-Trp-Lys-Thr-Cys}$) was studied by empirical conformational energy calculations. The low-energy structure found contains a type II' bend centered at the D-Trp-Lys residues. The lowest energy conformer has the aromatic ring of DTrp positioned such that the γ-protons of the Lys side-chain are in the shielding region (i.e., perpendicular to the center of the aromatic ring). This is in agreement with the NMR results. A mechanism of action for the inhibition of GH release is presented which suggests a conformational change occurs in the D-Trp side-chain ring upon binding to the receptor. The resulting structure has the Phe-D-Trp ring-ring stacking suggested to be responsible for binding and agonist activity of model growth-hormone releasing peptides.     

Theoretical Study of the Structure of Adenosine Deaminase Complexes with Adenosine Analogues: I. Aza-, Deaza-, and Isomeric Azadeazaanalogues of Adenosine

Conformational models of the active site of adenosine deaminase (ADA) and its complexes in the basic state with adenosine and 13-isosteric analogues of the aza, deaza, and azadeaza series were constructed. The optimization of the conformational energy of the active site and the nucleoside bound with it in the complex was achieved in the force field of the whole enzyme [the structure of ADA complex with 1-deazaadenosine (1ADD) was used] within the molecular mechanics model using the AMBER 99 potentials. The stable conformational states of each of the complexes, as well as the optimal conformation of ADA in the absence of ligand, were determined. It was proved that the conformational state that is close to the structure of the ADA complex with 1ADD known from X-ray study corresponds to one of the local minima of the potential surface. Another, a significantly deeper minimum was determined; it differs from the first minimum by the mutual orientation of side chains of amino acid residues. A similar conformational state is optimal for the ADA active site in the absence of bound ligand. A qualitative correlation exists between the values of potential energies of the complexes in this conformation and the enzymatic activity of ADA toward the corresponding nucleosides. The dynamics of conformational conversions of the active site after the binding of substrate or its analogues, as well as the possibility of the estimation of the inhibitory properties of nucleosides on the basis of calculations, are discussed.     

Can the stereochemical outcome of glycosylation reactions be controlled by the conformational preferences of the glycosyl donor?

Previous static and dynamical density functional theory studies of the 2,6-di-O-acetyl-3,4-O-isopropylidene-D-galactopyranosyl cations and their methanol adducts has led to an hypothesis that these cations exist in two families of conformers characterized as (2)S(O) and B(2,5), respectively. These families differ by ring inversion, each with its own reactivity. New calculations on the 2,6-di-O-acetyl-3,4-di-O-methyl-D-galactopyranosyl cation confirmed these trends. Removing the isopropylidene group allows more flexibility, but two families of conformers can be discerned with the monocyclic oxocarbenium ions in the E(3) conformation and the bicyclic dioxolenium ions in the (4)H(5) conformation. Attack on the beta-face of these monocyclic cations is favored by hydrogen bonding and the anomeric effect. The experimentally observed high beta-stereoselectivity of mannopyranosyl donors and high alpha-stereoselectivity of glucopyranosyl donors with the 4,6-O-benzylidene protecting groups can be rationalized assuming that the trans-fused 1,3-dioxane ring allows population of only one family of conformers. The combination of hydrogen bonding and conformational changes of the pyranose ring in response to the C-5[bond]O-5[bond]C-1[bond]C-2 torsion angle changes are identified as key factors in stereoselectivity. Based on these observations a strategy to design face discriminated glycosyl donors that exist predominantly in only one family of conformers is proposed.     

Stereodynamics of Nitrogen Chiral Centers in aza‐β3‐Cyclodipeptides

The present work is devoted to the synthesis, conformational analysis, and stereodynamic study of aza‐β³‐cyclodipeptides. This pseudopeptidic ring shows E/Z hydrazide bond isomerism, eight‐membered ring conformation, and chirotopic nitrogen atoms, all of which are elements that are prone to modulate the ring shape. The (E,E) twist boat conformation observed in the solid state by X‐ray diffraction is also the ground conformation in solution, and emerges as the lowest in energy when using quantum chemical calculations. The relative configuration associated with ring chirality and with the two nitrogen chiral centers is governed by steric crowding and adopts the (P)S_NS_N/(M)R_NR_N combination which projects side chains in equatorial position. The nitrogen pyramidal inversion (NPI) at the two chiral centers is correlated with the ring reversal. The process is significantly hindered as was shown by VT‐NMR experiments run in C₂D₂Cl₄, which did not make it possible to determine the barrier to inversion. Finally, these findings make it conceivable to resolve enantiomers of aza‐β³‐cyclodipeptides by modulating the backbone decoration appropriately. Chirality 25:341–349, 2013. © 2013 Wiley Periodicals, Inc.