Schizophrenia risk gene CAV1 is both pro-psychotic and required for atypical antipsychotic drug actions in vivo.

Caveolin-1 (Cav-1) is a scaffolding protein important for regulating receptor signaling cascades by partitioning signaling molecules into membrane microdomains. Disruption of the CAV1 gene has recently been identified as a rare structural variant associated with schizophrenia. Although Cav-1 knockout (KO) mice displayed no baseline behavioral disruptions, Cav-1 KO mice, similar to schizophrenic individuals, exhibited increased sensitivity to the psychotomimetic N-methyl-D-aspartate receptor antagonist phencyclidine (PCP). Thus, PCP disruption of prepulse inhibition (PPI) and PCP-induced mouse locomotor activity were both enhanced by genetic deletion of Cav-1. Interestingly, genetic deletion of Cav-1 rendered the atypical antipsychotics clozapine and olanzapine and the 5-HT(2A)-selective antagonist M100907 ineffective at normalizing PCP-induced disruption of PPI. We also discovered that genetic deletion of Cav-1 attenuated 5-HT(2A)-induced c-Fos and egr-1 expression in mouse frontal cortex and also reduced 5-HT(2A)-mediated Ca(2+) mobilization in primary cortical neuronal cultures. The behavioral effects of the 5-HT(2A) agonist (2,5-dimethoxy-4-iodoamphetamine) including head twitch responses and disruption of PPI were also attenuated by genetic deletion of Cav-1, indicating that Cav-1 is required for both inverse agonist (that is, atypical antipsychotic drug) and agonist actions at 5-HT(2A) receptors. This study demonstrates that disruption of the CAV1 gene--a rare structural variant associated with schizophrenia--is not only pro-psychotic but also attenuates atypical antipsychotic drug actions.

Insertion of a peptide from MuLV RT into the connection subdomain of HIV-1 RT results in a functionally active chimeric enzyme in monomeric conformation.

The natural form of the human immunodeficiency virus type one reverse transcriptase (HIV-1 RT) found in virion particles is a heterodimer composed of the p66 and p51 subunits. The catalytic activity resides in the larger subunit in the heterodimeric (p66/p51) enzyme while in the monomeric form it is inactive. In contrast, Murine leukemia virus RT (MuLV RT) is functionally active in the monomeric form. In the primary amino acid sequence alignment of MuLV RT and HIV-1 RT, we have identified three specific regions in MuLV RT, that were missing in HIV-1 RT. In a separate study, we have shown that a chimeric RT construct comprising of the polymerase domain of HIV-1 RT and RNase-H domain of MuLV RT is functionally active as monomer [20]. In this communication, we demonstrate that insertion of a peptide (corresponding to amino acid residues 480-506) from the connection subdomain of MuLV RT into the connection subdomain of HIV-1 RT (between residues 429 and 430) results in a functionally active monomeric chimeric RT. Furthermore, this chimeric enzyme does not dimerize with exogenously added p51 subunit of HIV-1RT. Functional analysis of the chimeric RT revealed template specific variations in its catalytic activity. The chimeric enzyme catalyzes DNA synthesis on both heteropolymeric DNA and homopolymeric RNA (poly rA) template but curiously lacks reverse transcriptase ability on heteropolymeric RNA template. Similar to MuLV RT, the polymerase activity of the chimeric enzyme is not affected by acetonitrile, a reagent which dissociates dimeric HIV-1 RT into inactive monomers. These results together with a proposed 3-D molecular model of the chimeric enzyme suggests that the insertion of the missing region may induce a change in the spatial position of RNase H domain such that it is functionally active in monomeric conformation.

The beta7-beta8 loop of the p51 subunit in the heterodimeric (p66/p51) human immunodeficiency virus type 1 reverse transcriptase is essential for the catalytic function of the p66 subunit.

The heterodimeric human immunodeficiency virus type 1 reverse transcriptase (HIV-1 RT) is composed of p66 and p51 subunits, p66 being the catalytic subunit. Our earlier investigation on the role of p51 in the catalytic process has shown that the p51 subunit facilitates the loading of the p66 subunit onto the template primer (TP). We had postulated that the beta7-beta8 loop of the p51 subunit may be involved in opening the polymerase cleft of p66 for DNA binding [Pandey, V. N., et al. (1996) Biochemistry 35, 2168]. We report here that deletion or alanine substitution of four residues of the beta7-beta8 loop results in severe impairment of the polymerase function of the heterodimeric enzyme. The enzyme activity was restored to the wild-type levels when the mutant p66 subunit was dimerized with the wild-type p51, suggesting that the intact beta7-beta8 loop in the p51 subunit is indispensable for the catalytic function of p66. Further, the template primer binding ability of the enzyme was significantly reduced upon deletion or alanine substitution in the beta7-beta8 loop. Interestingly, the loss of the TP binding ability of the mutant p66 was restored upon dimerization with wild-type p51. Examination of the glycerol gradient ultracentrifugation analysis revealed that while the wild-type HIV-1 RT sediments as a dimeric protein, the mutant enzymes carrying deletion or alanine substitution in both the subunits sediment predominantly as monomeric proteins, suggesting their inability to form stable dimers. In contrast, mutant p66 dimerized with wild-type p51 (p66delta/p51WT and p66Ala/p51WT) sedimented at the dimeric position. Taken together, these results clearly implicate the importance of the beta7-beta8 loop of p51 in the formation of stable functional heterodimers.

Platinum(II) and palladium(II) complexes with 2-acetylpyridine thiosemicarbazone: cytogenetic and antineoplastic effects.

The effect of three novel complexes of Pt(II) and three complexes of Pd(II) with 2-acetylpyridine thiosemicarbazone (HAcTsc) on sister chromatid exchange (SCE) rates and human lymphocyte proliferation kinetics on a molar basis was studied. Also, the effect of Pt(II) and Pd(II) complexes against leukemia P388 was investigated. Among these compounds, the most effective in inducing antitumor and cytogenetic effects were the complexes [Pt(AcTsc)2] x H2O and [Pd(AcTsc)2] while the rest, i.e. (HAcTsc), [Pt(AcTsc)Cl], [Pt(HAcTsc)2]Cl2 x 2H2O, [Pd(AcTsc)Cl] and [Pd(HAcTsc)2]Cl2, displayed marginal cytogenetic and antitumor effects.

Synthesis, crystal structure, spectral properties and cytotoxic activity of platinum(II) complexes of 2-acetyl pyridine and pyridine-2-carbaldehyde N(4)-ethyl-thiosemicarbazones.

The reactions of Na2PtCl4 with pyridine-2-carbaldehyde and 2-acetyl pyridine N(4)-ethyl-thiosemicarbazones, HFo4Et and HAc4Et respectively, afforded the complexes [Pt(Fo4Et)Cl], [Pt(HFo4Et)2]Cl2, [Pt(Fo4Et)2] and [Pt(Ac4Et)Cl], [Pt(HAc4Et)2]Cl2 x 2H2O, [Pt(Ac4Et)2]. The new complexes have been characterized by elemental analyses and spectroscopic studies. The crystal structure of the complex [Pt(Ac4Et)Cl] has been solved. The anion of Ac4E coordinates in a planar conformation to the central platinum(II) through the pyridyl N, azomethine N and thiolato S atoms. Intermolecular hydrogen, non-hydrogen bonds, pi-pi and weak Pt-pi contacts lead to aggregation and a supramolecular assembly. The cytotoxic activity for the platinum(II) complexes in comparison to that of cisplatin and thiosemicarbazones was evaluated in a pair of cisplatin-sensitive and -resistant ovarian cancer cell lines A2780 and A2780/Cp8. The platinum(II) complexes showed a cytotoxic potency in a very low micromolar range and were found able to overcome the cisplatin resistance of A2780/Cp8 cells.

Role of glutamine 151 of human immunodeficiency virus type-1 reverse transcriptase in substrate selection as assessed by site-directed mutagenesis.

A natural mutation at codon 151 (Gln --> Met; Q151M) of HIV-1 RT has been shown to confer resistance to the virus against dideoxy nucleoside analogues [Shirasaka, T., et al. (1995) Proc. Natl. Acad. Sci. U.S.A. 92, 2398], suggesting that Gln 151 may be involved in conferring sensitivity to nucleoside analogues. To understand its functional implication, we generated two mutant derivatives of this residue (Q151M and Q151N) and examined their sensitivities to ddNTPs and their ability to discriminate against rNTPs versus dNTP substrates on natural U5-PBS HIV-1 RNA template. We found that Q151M was highly discriminatory against all four ddNTPs but was able to incorporate rNTPs as efficiently as the wild type enzyme. In contrast, the Q151N mutant was only moderately resistant to ddNTPs but exhibited a higher level of discrimination against rNTPs. The fidelity of misinsertion was found to be highest for the Q151N mutant followed by Q151M and the wild type enzyme. These results point toward the importance of the amino acid side chain at position 151 in influencing the ability of the enzyme in recognition and discrimination against the sugar moieties of nucleotide substrates.

Functional analysis of amino acid residues constituting the dNTP binding pocket of HIV-1 reverse transcriptase.

In order to understand the functional implication of residues constituting the dNTP-binding pocket of human immunodeficiency virus type 1 reverse transcriptase, we performed site-directed mutagenesis at positions 65, 72, 113, 115, 151, 183, 184, and 219, and the resulting mutant enzymes were examined for their biochemical properties and nucleotide selectivity on RNA and DNA templates. Mutations at positions 65, 115, 183, 184, and 219 had negligible to moderate influence on the polymerase activity, while Ala substitution at positions 72 and 151 as well as substitution with Ala or Glu at position 113 severely impaired the polymerase function of the enzyme. The K219A, Y115F, and Q151M mutants had no influence on the fidelity; Y183A, Y183F, K65A, and Q151N mutants exhibited higher fidelity on both RNA and DNA templates, while Y115A was less error-prone selectively on a DNA template. Analysis of the three-dimensional model of the enzyme-template primer-dNTP ternary complex suggests that residues Tyr-183, Lys-65, and Gln-151 may have impact on the flexibility of the dNTP-binding pocket by virtue of their multiple interactions with the dNTP, template, primer, and other neighboring residues constituting the pocket. Recruitment of the correct versus incorrect nucleotides may be a function of the flexibility of this pocket. A relatively rigid pocket would provide greater stringency, resulting in higher fidelity of DNA synthesis in contrast to a flexible pocket. Substitution of a residue having multiple interactions with a residue having reduced interaction capability will alter the internal geometry of the pocket, thus directly influencing the fidelity.

Loss of polymerase activity due to Tyr to Phe substitution in the YMDD motif of human immunodeficiency virus type-1 reverse transcriptase is compensated by Met to Val substitution within the same motif.

Tyr183 is a constituent of the highly conserved YXDD motif common to all retroviral reverse transcriptases. The two aspartates in this motif are the crucial members of the catalytic carboxylate triad while residue X, which in the case of HIV-1 RT is Met184, is implicated in dNTP substrate recognition and fidelity of DNA synthesis. In an attempt to understand the function of Tyr183 in the catalytic mechanism, we generated mutants of this residue (Y183F and Y183A) and subjected them to in-depth analysis. The efficiency of reverse transcription of natural U5-PBS HIV-1 RNA template was severely impaired by both the conservative and nonconservative substitutions. The major defect identified was at the level of dNTP binding as determined by a 20-80-fold increase in the Km for the dNTP substrate on both homopolymeric and heteropolymeric RNA and DNA templates. A significant reduction in processivity of DNA synthesis by these mutants was also noted. However, the fidelity of DNA synthesis by the Y183F and Y183A mutants was increased significantly compared to the wild-type enzyme. Interestingly, the reduction in the polymerase activity due to single substitution of Tyr to Phe in the YMDD motif is compensated by a second substitution of Met to Val in the same motif, herein referred to as the FVDD. The loss of dNTP binding as well as decreased processivity of DNA synthesis exhibited by the Y183F mutant was also compensated by mutation at the second site. Curiously, the double mutant did not exhibit any synergistic effect in regard to fidelity of DNA synthesis as might be expected since both the single mutations (Y183F, M184V) exhibited enhanced fidelity compared to the wild-type enzyme. These data implicate Tyr183 and Met184 as important constituents of the dNTP-binding pocket. We propose a model which suggests that subtle structural changes due to mutation in the flexible beta9-beta10 loop region at the active site of the molecule influence the enzyme activity and substrate recognition.

Role of glutamine-151 of human immunodeficiency virus type-1 reverse transcriptase in RNA-directed DNA synthesis.

Glutamine-151 of HIV-1 RT has been shown to be a catalytically important residue through the characterization of its mutant phenotype Glu151Ala (Sarafianos et al., 1995a). To further understand the role of this residue, we have extended this analysis to include polymerization on natural RNA template in addition to DNA template. We find that Q151A mutant exhibited a severe reduction in the polymerase activity without any significant effect on the affinity for dNTP substrate. Unlike DNA-directed reactions, the rate-limiting step for RNA-directed reactions does not appear to be either at the dNTP binding step or the chemical step. Analysis of the products formed on natural heteromeric HIV-genomic RNA template annealed with an 18-mer DNA primer with a sequence complementary to the primer binding site (PBS) has shown that addition of nucleotides is nonlinear with time since the enzyme appears to stall on the RNA template following the incorporation of the first nucleotide. The Q151A mutant was found to be nearly devoid of pyrophosphorolytic activity on a RNA-PBS template-primer. Similar properties have been previously reported for a mutant of R72 (R72A) of HIV-1 RT (Sarafianos et al., 1995b). However, R72 was implicated in stabilizing the transition state ternary complex before and after the phosphodiester bond formation (Kaushik et al., 1996; Sarafianos et al., 1995b). Our results with Q151A suggest that the side chain of Q151 may help stabilize the side chain of R72, and the loss of pyrophosphorolysis activity observed with the Q151 mutant may be the indirect manifestation of this stabilizing effect on R72. These observations point to the functional interdependence of residues Q151 and R72 in the polymerase function of the enzyme. An analysis of the 3D model structure of HIV-1 RT bound to DNA-DNA and RNA-DNA template-primer reveals that the guanidine hydrogen of R72 seems to stabilize Q151 by hydrogen bonding with its amide oxygen. A systematic conformational search of the side chain of Q151 also suggests a stable orientation where its specific interaction with the base of the RNA template may aid in stabilizing it.

Biochemical analysis of catalytically crucial aspartate mutants of human immunodeficiency virus type 1 reverse transcriptase.

In order to clarify the role(s) of the individual member of the carboxylate triad in the catalytic mechanism of human immunodeficiency virus type 1 (HIV-1) reverse transcriptase, we carried out site-directed mutagenesis of D185, D186, and D110, followed by the extensive characterization of the properties of the individual mutant enzymes. We find that all three residues participate at or prior to the chemical step of bond formation. The incorporation pattern seen with phosphorothioate analogs of dNTP on both RNA-DNA and DNA-DNA template-primers indicated that D186 may be the residue that coordinates with the alpha-phosphate group of dNTP in the transition-state ternary complex. Further support for the role assigned to D186 was obtained by examination of the ability of the individual carboxylate mutants to catalyze the reverse of the polymerase reaction (pyrophosphorolysis). Mutants of D185 exhibited near-normal pyrophosphorolysis activity, while those of D186 were completely devoid of this activity. Thus, D185 appears to participate only in the forward reaction, probably required for the generation of nucleophile by interacting with the 3'-OH of the primer terminus, while D186 seems to be involved in both the forward and the reverse reactions, presumably by participating in the pentavalent intermediate transition state. Lack of any elemental effects during polymerization with mutant enzymes of residue D110, together with their inability to catalyze pyrophosphorolysis, suggest its probable participation in the metal-coordinated binding to the beta-gamma-phosphate of dNTP or PPi in the forward and reverse reactions, respectively. A molecular model of the ternary complex based on these results is also presented.

Targeting HIV reverse transcriptase for anti-AIDS drug design: structural and biological considerations for chemotherapeutic strategies.

The reverse transcriptase of HIV is a key target for the antiviral treatment of AIDS. Numerous potent inhibitors of RT have been described including all of the drugs that have been currently licensed for the treatment of AIDS, but their efficacy has been limited by the emergence of drug-resistant HIV variants. Extensive biochemical, genetic, and clinical data about HIV RT enzymatic mechanisms, inhibition, and drug resistance have been reported. This information, taken together with structural data from crystallographic studies of HIV-1 RT, has set the stage for structure-based design of improved inhibitors of this essential viral enzyme. Comparisons of the different crystal structures of HIV-1 RT shows that the enzyme has great conformational flexibility, providing additional possibilities for drug targeting. Recent clinical and virological data suggest that HIV-1 RT enzymes that carry drug-resistance mutations can be substantially impaired and that combinations of RT inhibitors can produce significant clinical benefit in the treatment of AIDS. An immediate goal is to use the available information to design specific inhibitors or combination therapies that will select for relatively less fit HIV variants.

Role of methionine 184 of human immunodeficiency virus type-1 reverse transcriptase in the polymerase function and fidelity of DNA synthesis.

Methionine 184 of HIV-1 RT is a constituent of the catalytically crucial and highly conserved YXDD motif in the reverse transcriptase class of enzymes. We investigated the role of this residue by substituting it with Ala and Val by site-directed mutagenesis followed by extensive characterization of the two mutant enzymes. The kinetic parameters governing DNA synthesis directed by RNA and DNA templates indicated that both M184A and M184V mutants are catalytically as efficient as the wild type enzyme. Photoaffinity labeling of both the mutant and the wild type enzyme exhibited an identical affinity for RNA-DNA and DNA-DNA template primers. We further demonstrate that M-->V substitution at 184 position significantly increases the fidelity of DNA synthesis while M-->A substitution results in a highly error-prone enzyme without having compromised its efficiency of DNA synthesis. The M184V mutant exhibited a 25-45-fold increase in mismatch selectivity (ratio of k(cat)/K(m) of correct versus incorrect nucleotides) as compared to the WT enzyme. This pattern of error-prone synthesis is also confirmed by examining the abilities of the enzyme-(template-primer) covalent complexes to incorporate correct versus incorrect nucleotide onto the immobilized template-primer. The nature of error-prone synthesis by the M184A mutant shows an increase in both the mismatch synthesis and extension of the mismatched primer termini. Using a three-dimensional molecular model of the ternary complex of HIV-1 RT, template-primer, and dNTP, we observe that the strategic location of M184 may allow it to interact with the sugar moiety of either the primer nucleotide or the dNTP substrate.

Identification of a pharmacophore for nucleoside analog inhibitors directed at HIV-1 reverse transcriptase.

An 'active analog' approach to receptor mapping was used to identify a pharmacophore for a set of thymidine nucleoside analog inhibitors of HIV-1 reverse transcriptase. The preliminary results indicate that the O2, O4', and O5' atoms are capable of adopting a unique pharmacophoric pattern which may be the key to their recognition by reverse transcriptase.

Identification and analysis of a template-primer (ds-DNA) binding cleft in E. coli DNA polymerase I: an electrostatic potential contour pattern of the modeled structure.

In the modeled structure of the Klenow fragment of E. coli DNA polymerase I, we have identified a distinct region that exhibits a strong electropositive potential contour. The examination of the distribution of the electropositive and negative potential across the two-dimensional slices of the modeled structure revealed that the positive potential was concentrated around the cleft. The approximate size and shape of the region appears well suited to accommodate eight base pairs of duplex DNA and is consistent with the position of the dsDNA binding cleft reported in the crystal structure [Beese et al., Science (1993) 260, 352-355].

A computer-assisted analysis of conserved residues in the three-dimensional structures of the polymerase domains of Escherichia coli DNA polymerase I and HIV-1 reverse transcriptase.

Using a computer-assisted molecular modeling protocol, we have completed the three-dimensional structures of HIV-1 reverse transcriptase and the Klenow fragment of DNA polymerase I based on the C alpha crystal coordinates of the individual enzymes. The two model-built structures were then used to compare the electrostatic potential contours and analyze the spatial positions of residues conserved in the catalytic domains of the two enzymes. In spite of rather weak sequence similarity and different folding patterns between the DNA-dependent DNA polymerase (pol I) and the RNA-dependent DNA polymerases (RT), we have noted the occurrence of identical or similar residues at common spatial positions in pol I and RT in a three-dimensional context. The homologous residues present at equivalent spatial position in the Klenow fragment and the p66 subunit of HIV-1 RT may therefore imply their functional similarity. Furthermore, these conserved residues may represent a similar structure-function feature in all polymerases.

Binding of DNA to large fragment of DNA polymerase I: identification of strong and weak electrostatic forces and their biological implications.

Examination of the electrostatic potential of a modeled complex, consisting of the Klenow fragment of E. coli DNA polymerase I and DNA template-primer, suggested the presence of two distinct interacting regions. The one displaying a strong electropositive potential field is generated by side chains of basic amino acid pairs and is directed towards the major groove site in DNA. The second electrostatic potential field around DNA is somewhat weaker and appears to be exerted by a pair of vicinal side chains of acidic and basic amino acids. The distribution of charges in this manner appears well suited for the binding of enzyme to the template-primer required in the enzymatic synthesis of DNA.

A molecular model of the complete three-dimensional structure of the Klenow fragment of Escherichia coli DNA polymerase I: binding of the dNTP substrate and template-primer.

A complete three-dimensional structure of the Klenow fragment of Escherichia coli DNA polymerase I (pol I) has been proposed on the basis of molecular modeling and molecular mechanics studies using available C alpha coordinates. The structure seems quite reliable because the overall surface of electrostatic potentials calculated for the molecularly modeled enzyme closely resembles that reported for the X-ray structure. The modeled structure is then used in developing a ternary complex of dTTP and (dA)25-(dT)14 poised in its active site. The orientation of both substrates in the ternary complex was primarily guided by the amino acid residues which had been known to interact with dNTP and DNA substrates from earlier studies. The proposed model (a) explains the geometrical and physicochemical relationship of the two substrates with the various critical amino acid residues involved in the binding process and (b) suggests possible roles for additional residues in the binding and/or polymerization reaction. Furthermore, the ternary complex appears to satisfy many biochemical and genetic data concerning catalytic requirements known to exist for the polymerization reaction.