The inhibition process of HIV-1 integrase by diketoacids molecules: Understanding the factors governing the better efficiency of dolutegravir.

The Human Immunodeficiency Virus-1 integrase is responsible for the covalent insertion of a newly synthesized double-stranded viral DNA into the host cells, and is an emerging target for antivirus drug design. Raltegravir (RAL) and elvitegravir (EVG) are the first two integrase strand transfer inhibitors used in therapy. However, treated patients eventually develop detrimental resistance mutations. By contrast, a recently approved drug, dolutegravir (DTG), presents a high barrier to resistance. This study aims to understand the increased efficiency of DTG upon focusing on its interaction properties with viral DNA. The results showed DTG to be involved in more extended interactions with viral DNA than EVG. Such interactions involve the halobenzene and scaffold of DTG and EVG and bases 5'G-43', 3'A35'and 3'C45'.

Presence of divalent cation is not mandatory for the formation of intramolecular purine-motif triplex containing human c-jun protooncogene target.

Modulation of endogenous gene function, through sequence-specific recognition of double helical DNA via oligonucleotide-directed triplex formation, is a promising approach. Compared to the formation of pyrimidine motif triplexes, which require relatively low pH, purine motif appears to be the most gifted for their stability under physiological conditions. Our previous work has demonstrated formation of magnesium-ion dependent highly stable intermolecular triplexes using a purine third strand of varied lengths, at the purine•pyrimidine (Pu•Py) targets of SIV/HIV-2 (vpx) genes (Svinarchuk, F., Monnot, M., Merle, A., Malvy, C., and Fermandjian, S. (1995) Nucleic Acids Res. 23, 3831-3836). Herein, we show that a designed intramolecular version of the 11-bp core sequence of the said targets, which also constitutes an integral, short, and symmetrical segment (G(2)AG(5)AG(2))•(C(2)TC(5)TC(2)) of human c-jun protooncogene forms a stable triplex, even in the absence of magnesium. The sequence d-C(2)TC(5)TC(2)T(5)G(2)AG(5)AG(2)T(5)G(2)AG(5)AG(2) (I-Pu) folds back twice onto itself to form an intramolecular triple helix via a double hairpin formation. The design ensures that the orientation of the intact third strand is antiparallel with respect to the oligopurine strand of the duplex. The triple helix formation has been revealed by non-denaturating gel assays, UV-thermal denaturation, and circular dichroism (CD) spectroscopy. The monophasic melting curve, recorded in the presence of sodium, represented the dissociation of intramolecular triplex to single strand in one step; however, the addition of magnesium bestowed thermal stability to the triplex. Formation of intramolecular triple helix at neutral pH in sodium, with or without magnesium cations, was also confirmed by gel electrophoresis. The triplex, mediated by sodium alone, destabilizes in the presence of 5'-C(2)TC(5)TC(2)-3', an oligonucleotide complementary to the 3'-oligopurine segments of I-Pu, whereas in the presence of magnesium the triplex remained impervious. CD spectra showed the signatures of triplex structure with A-like DNA conformation. We suggest that the possible formation of pH and magnesium-independent purine-motif triplexes at genomic Pu•Py sequences may be pertinent to gene regulation.

Specificity of LTR DNA recognition by a peptide mimicking the HIV-1 integrase {alpha}4 helix.

HIV-1 integrase integrates retroviral DNA through 3'-processing and strand transfer reactions in the presence of a divalent cation (Mg(2+) or Mn(2+)). The alpha4 helix exposed at the catalytic core surface is essential to the specific recognition of viral DNA. To define group determinants of recognition, we used a model composed of a peptide analogue of the alpha4 helix, oligonucleotides mimicking processed and unprocessed U5 LTR end and 5 mM Mg(2+). Circular dichroism, fluorescence and NMR experiments confirmed the implication of the alpha4 helix polar/charged face in specific and non-specific bindings to LTR ends. The specific binding requires unprocessed LTR ends-i.e. an unaltered 3'-processing site CA downward arrowGT3'-and is reinforced by Mg(2+) (K(d) decreases from 2 to 0.8 nM). The latter likely interacts with the ApG and GpT3' steps of the 3'-processing site. With deletion of GT3', only persists non-specific binding (K(d) of 100 microM). Proton chemical shift deviations showed that specific binding need conserved amino acids in the alpha4 helix and conserved nucleotide bases and backbone groups at LTR ends. We suggest a conserved recognition mechanism based on both direct and indirect readout and which is subject to evolutionary pressure.

Chirality in dynamic supramolecular nanotubes induced by a chiral solvent.

Amplification of chirality has been reported in polymeric systems. It has also been shown that related effects can occur in polymer-like dynamic supramolecular aggregates, if a subtle balance between noncovalent interactions allows the coupling between a chiral information and a cooperative aggregation process. In this context, we report a strong majority-rules effect in the formation of chiral dynamic nanotubes from chiral bisurea monomers. Furthermore, similar helical nanotubes (with the same circular dichroism signature) can be obtained from racemic monomers in a chiral solvent. Competition experiments reveal the relative strength of the helical bias induced by the chiral monomer or by the chiral solvent. The nanotube handedness is imposed by the monomer chirality, whatever the solvent chirality. However, the chirality of the solvent has a significant effect on the degree of chiral induction.

C-->G base mutations in the CArG box of c-fos serum response element alter its bending flexibility. Consequences for core-SRF recognition.

By binding to the CArG box sequence, the serum response factor (SRF) activates several muscle-specific genes, as well as genes that respond to mitogens. The core domain of the SRF (core-SRF) binds as a dimer to the CArG box C-5C-4A-3T-2A-1T+1T+2A+3G+4G+5 of the c-fos serum response element (SREfos). However, previous studies using 20-mer DNAs have shown that the binding stoichiometry of core-SRF is significantly altered by mutations C-5-->G (SREGfos) and C-5C-4-->GG (SREGGfos) of the CArG box [A Huet, A Parlakian, M-C Arnaud, J-M Glandières, P Valat, S Fermandjian, D Paulin, B Alpert & C Zentz (2005) FEBS J272, 3105-3119]. To understand these effects, we carried out a comparative analysis of the three 20-mer DNAs SREfos, SREGfos and SREGGfos in aqueous solution. Their CD spectra were of the B-DNA type with small differences generated by variations in the mutual arrangement of the base pairs. Analysis by singular value decomposition of a set of Raman spectra recorded as a function of temperature, revealed a premelting transition associated with a conformational shift in the DNA double helices from a bent to a linear form. Time-resolved fluorescence anisotropy shows that the fluorescein reporter linked to the oligonucleotide 5'-ends experiences twisting motions of the double helices related to the interconversion between bent and linear conformers. The three SREs present various bent populations submitted, however, to particular internal dynamics, decisive for the mutual adjustment of binding partners and therefore specific complex formation.

Does topoisomerase II specifically recognize and cleave hairpins, cruciforms and crossovers of DNA?

DNA topoisomerase II is an enzyme that specializes in DNA disentanglement. It catalyzes the interconversion of DNA between different topological states. This event requires the passage of one duplex through another one via a transient double-strand break. Topoisomerase II is able to process any type of DNA, including structures such as DNA juxtapositions (crossovers), DNA hairpins or cruciforms, which are recognized with high specificity. In this review, we focused our attention on topoisomerase II recognizing DNA substrates that possess particular geometries. A strong cleavage site, as we identified in pBR322 DNA in the presence of ellipticine (site 22), appears to be characterized by a cruciform structure formed from two stable hairpins. The same sequence could also constitute a four-way junction structure stabilized by interactions involving ATC sequences. The latter have been shown to be able to promote Holliday junctions. We reviewed the recent literature that deals with the preferential recognition of crossovers by various topoisomerases. The single molecule relaxation experiments have demonstrated the differential abilities of the topoisomerases to recognize crossovers. It appears that enzymes, which distinguish the chirality of the crossovers, possess specialized domains dedicated to this function. We also stress that the formation of crossovers is dependent on the presence of adequate stabilizing sequences. Investigation of the impact of such structures on enzyme activity is important in order to both improve our knowledge of the mechanism of action of the topoisomerase II and to develop new inhibitors of this enzyme.

Molecular modelling studies on the interactions of human DNA topoisomerase IB with pyridoxal-compounds.

Candida guilliermondii and human DNA topoisomerases I are inhibited by PL (pyridoxal), PLP (pyridoxal 5'-phosphate) and PLP-AMP (pyridoxal 5'-diphospho-5'-adenosine) (PL

Conformations and dynamics of the phosphodiester backbone of a DNA fragment that bears a strong topoisomerase II cleavage site.

The dynamics of the DNA phosphodiester backbone conformations have been studied for a strong topoisomerase II cleavage site (site 22) using molecular dynamics simulations in explicit water and in the presence of sodium ions. We investigated the backbone motions and more particularly the BI/BII transitions involving the epsilon and zeta angles. The consensus cleavage site is adjacent to the phosphate which shows the most important phosphodiester backbone flexibility in the sequence. We infer that these latter properties could be responsible for the preferential cleavage at this site possibly through the perturbation of the cleavage/ligation activities of the topoisomerase II. More generally, the steps pur-pur and pyr-pur are those presenting the highest BII contents. Relations are observed between the backbone phosphodiester BI/BII transitions and the flexibility of the deoxyribose sugar and the helical parameters such as roll. The roll is sequence dependent when the related phosphate is in the BI form, whereas this appears not to be true when it is in the BII form. The BI/BII transitions are associated with water migration, and new relations are observed with counterions. Indeed, it is observed that a strong coupling exists between the BII form and the presence of sodium ions near the adjacent sugar deoxyribose. The presence of sodium ions in the O4' surroundings or their binding could assist the BI to BII transition by furnishing energy. The implications of these new findings and, namely, their importance in the context of the sequence-dependent behavior of BI/BII transitions will be investigated in future studies.

Structural and functional characterizations reveal the importance of a zinc binding domain in Bloom's syndrome helicase.

Bloom's syndrome (BS) is an autosomal recessive human disorder characterized by genomic instability and a predisposition to a wide variety of cancers. The gene mutated in BS, BLM, encodes a protein containing three domains: an N-terminal domain whose function remains elusive, a helicase domain characterized by seven 'signature' motifs conserved in a wide range of helicases and a C-terminal extension that can be further divided into two sub-domains: RecQ-Ct and HRDC. The RecQ-Ct domain appears essential because two point-mutations altering highly conserved cysteine residues within this domain have been found in BS patients. We report herein that BLM contains a zinc ion. Modelling studies suggest that four conserved cysteine residues within the RecQ-Ct domain coordinate this zinc ion and subsequent mutagenesis studies further confirm this prediction. Biochemical and biophysical studies show that the ATPase, helicase and DNA binding activities of the mutants are severely modified. Structural analysis of both wild-type and mutant proteins reveal that alteration of cysteine residues does not significantly change the overall conformation. The observed defects in ATPase and helicase activities were inferred to result from a compromise of DNA binding. Our results implicate an important role of this zinc binding domain in both DNA binding and protein conformation. They could be pivotal for understanding the molecular basis of BS disease.

Pre-organized structure of viral DNA at the binding-processing site of HIV-1 integrase.

The integration of the human immunodeficiency virus type 1 DNA into the host cell genome is catalysed by the viral integrase (IN). The reaction consists of a 3'-processing [dinucleotide released from each 3' end of the viral long terminal repeat (LTR)] followed by a strand transfer (insertion of the viral genome into the human chromosome). A 17 base pair oligonucleotide d(GGAAAATCTCTAGCAGT), d(ACTGCTAGAGATTTTCC) reproducing the U5-LTR extremity of viral DNA that contains the IN attachment site was analysed by NMR using the classical NOEs and scalar coupling constants in conjunction with a small set of residual dipolar coupling constants (RDCs) measured at the 13C/15N natural abundance. The combination of these two types of parameters in calculations significantly improved the DNA structure determination. The well-known features of A-tracts were clearly identified by RDCs in the first part of the molecule. The binding/cleavage site at the viral DNA end is distinguishable by a loss of regular base stacking and a distorted minor groove that can aid its specific recognition by IN.

Self-association and DNA binding properties of the human topoisomerase IIA alpha2HTH module.

The eukaryotic topoisomerase II is an ubiquitous nuclear enzyme involved in vital cellular functions. It is also the target for some of the most active anticancer drugs. In the various crystal structures of yeast topoisomerase II, the 701-748 segment homologous to the human topoisomerase II alpha 724-771 segment folds into a compact alpha(2)beta(1)alpha(3)talpha(4) conformation, hereafter termed alpha(2)HTH module (helix turn helix (HTH), alpha(3)talpha(4)). The crystal structure of gyrase A has suggested a model wherein HTH is involved in both the enzyme dimerization and the binding to DNA. These two properties were investigated in solution, using the recombinant alpha(2)HTH module of human topoisomerase II alpha and its synthetic components HTH, alpha(4), alpha(3) and turn. The homology-based structure model of human alpha(2)HTH superposed that of yeast in the crystal structure with a rmsd of 1.03 A. Circular dichroism spectra showed that the helical content of human alpha(2)HTH in solution is similar to that of its counterpart within yeast topoisomerase II in the solid state. The chemical cross-linking data indicated that alpha(2)HTH self-associated into dimers while gel mobility shift assays and anisotropy fluorescence titrations demonstrated that alpha(2)HTH, HTH and alpha(4), but not alpha(3), bind efficiently to DNA (dissociation constants of 3.10(-7) M for alpha(2)HTH and alpha(4), of 3.10(-6) M for HTH and of only 1.10(-5) M for alpha(3)). Correlatively, alpha(2)HTH, alpha(4) and HTH, but not alpha(3), were able to inhibit topoisomerase II in DNA relaxation assays, stipulating that alpha(4) is the DNA recognition helix. All suggests that the alpha(2)HTH module once separated from the whole protein conserves a compact conformation, integral to specific dimerization and DNA recognition. The module may thus be used for the search of drugs efficient in hindering topoisomerase II dimerization or binding to DNA.

Pyridoxal 5'-phosphate inactivates DNA topoisomerase IB by modifying the lysine general acid.

The present results demonstrate that pyridoxal, pyridoxal 5'-phosphate (PLP) and pyridoxal 5'-diphospho-5'-adenosine (PLP-AMP) inhibit Candida guilliermondii and human DNA topoisomerases I in forming an aldimine with the epsilon-amino group of an active site lysine. PLP acts as a competitive inhibitor of C.guilliermondii topoisomerase I (K(i) = 40 microM) that blocks the cleavable complex formation. Chemical reduction of PLP-treated enzyme reveals incorporation of 1 mol of PLP per mol of protein. The limited trypsic proteolysis releases a 17 residue peptide bearing a lysine-bound PLP (KPPNTVIFDFLGK*DSIR). Targeted lysine (K*) in C.guilliermondii topoisomerase I corresponds to that found in topoisomerase I of Homo sapiens (K532), Candida albicans (K468), Saccharomyces cerevisiae (K458) and Schizosaccharomyces pombe (K505). In the human enzyme, K532, belonging to the active site acts as a general acid catalyst and is therefore essential for activity. The spatial orientation of K532-PLP within the active site was approached by molecular modeling using available crystallographic data. The PLP moiety was found at close proximity of several active residues. PLP could be involved in the cellular control of topoisomerases IB. It constitutes an efficient tool to explore topoisomerase IB dynamics during catalysis and is also a lead for new drugs that trap the lysine general acid.

L-nucleotides and 8-methylguanine of d(C1m8G2C3G4C5LG6LC7G8C9G10)2 act cooperatively to promote a left-handed helix under physiological salt conditions.

The structure and thermal stability of a hetero chiral decaoligodeoxyribonucleotide duplex d(C1m8 G2C3G4C5LG6LC7G8C9G10)d(C11m8G12C13G14C15LG16LC17G18C19G20) (O1) with two contiguous pairs of enantiomeric 2'-deoxy-L-ribonucleotides (C5LG6L/C15LG16L) at its centre and an 8-methylguanine at position 2/12 was analysed by circular dichroism, NMR and molecular modelling. O1 resolves in a left-handed helical structure already at low salt concentration (0.1 M NaCl). The central L2-sugar portion assumes a B* left-handed conformation (mirror-image of right-handed B-DNA) while its flanking D4-sugar portions adopt the known Z left-handed conformation. The resulting Z4-B2*-Z4 structure (left-handed helix) is the reverse of that of B4-Z2*-B4 (right-handed helix) displayed by the nearly related decaoligodeoxyribonucleotide d(mC1G2mC3G4C5L G6LmC7G8mC9G10)2, at the same low salt concentration (0.1 M NaCl). In the same experimental conditions, d(C1m8G2C3G4C5G6C7G8C9G10)2 (O2), the stereoregular version of O1, resolves into a right-handed B-DNA helix. Thus, both the 8-methylguanine and the enantiomeric step CLpGL at the centre of the molecule are needed to induce left-handed helicity. Remarkably, in the various heterochiral decaoligodeoxyribonucleotides so far analysed by us, when the central CLpGL adopts the B* (respectively Z*) conformation, then the adjacent steps automatically resolves in the Z (respectively B) conformation. This allows a good optimisation of the base-base stackings and base-sugar van der Waals interactions at the ZB*/B*Z (respectively BZ*/Z*B) junctions so that the Z4-B2*-Z4 (respectively B4-Z2*-B4) helix displays a Tm (approximately 65 degrees C) that is only 5 degrees C lower than the one of its homochiral counterpart. Here we anticipate that a large variety of DNA helices can be generated at low salt concentration by manipulating internal factors such as sugar configuration, duplex length, nucleotide composition and base methylation. These helices can constitute powerful tools for structural and biological investigations, especially as they can be used in physiological conditions.

A targeted DNA substrate mechanism for the inhibition of HIV-1 integrase by inhibitors with antiretroviral activity.

We recently reported that viral DNA could be the primary target of raltegravir (RAL), an efficient anti-HIV-1 drug, which acts by inhibiting integrase. To elucidate this mechanism, we conducted a comparative analysis of RAL and TB11, a diketoacid abandoned as an anti-HIV-1 drug for its weak efficiency and marked toxicity, and tested the effects of the catalytic cofactor Mg(2+) (5 mm) on drug-binding properties. We used circular dichroism and fluorescence to determine drug affinities for viral DNA long terminal repeats (LTRs) and peptides derived from the integrase active site and DNA retardation assays to assess drug intercalation into DNA base pairs. We found that RAL bound more tightly to LTR ends than did TB11 (a diketo acid bearing an azido group) and that Mg(2+) significantly increased the affinity of both RAL and TB11. We also observed a good relationship between drug binding with processed LTR and strand transfer inhibition. This unusual type of inhibition was caused by Mg(2+)-assisted binding of drugs to DNA substrate, rather than to enzyme. Notably, while RAL bound exclusively to the cleavable/cleaved site, TB11 further intercalated into DNA base pairs and interacted with the integrase-derived peptides. These unwanted binding sites explain the weaker bioavailability and higher toxicity of TB11 compared with the more effective RAL.

Circular dichroism and fluorescence of a tyrosine side-chain residue monitors the concentration-dependent equilibrium between U-shaped and coiled-coil conformations of a peptide derived from the catalytic core of HIV-1 integrase.

The peptide denoted K159 (30 residues) derives from the catalytic core (CC) sequence of HIV-1 integrase (IN, residues 147-175). In the crystal structure of CC, the corresponding segment belongs to the alpha4 helix (residues 148-168, including residues Glu 152, Lys 156 and Lys 159, crucial for enzyme activity and DNA recognition), a loop (residues 169-171) and a part of the alpha5 helix (171-175), involved in enzyme dimerization. We used the fluorescence and the circular dichroism (CD) properties in the near-UV of the aromatic side chain of a tyrosine residue added at the C-terminal end of K159 in order to analyze the behavior of the concentrated and diluted peptide in aqueous trifluoroethanol (TFE), in an attempt to connect the information obtainable at high (NMR), medium (CD) and low (fluorescence) concentrations of the peptide. Altogether, the C-terminal tyrosine residue provided indirect information on the global conformation of K159 and on the local orientation and environment of the residue. The propensity of TFE to stabilize alpha-helical conformations in peptides was confirmed in CD and fluorescence experiments at relatively high (20-160 microM) and low (2-16 microM) concentrations, respectively. At relatively high concentration, stabilization of the peptide into alpha-helical conformation favored its auto-association likely in parallel coiled-coil dimers, as pointed out in our previous work [Eur. J. Biochem. 253 (1998) 236]. This was further confirmed by ANS (1-anilinonaphtalene-8-sulfonic acid) analysis and fluorescence temperature coefficient measurement. With diluted K159, a Stern-Volmer analysis with positively and negatively charged quenchers indicated that, when the intermolecular interactions were absent, the tyrosine was in a positively charged environment, as if the peptide folded into a U-shaped conformation similar to that present in the crystal structure of the enzyme.

Mechanism of binding of serum response factor to serum response element.

Serum response factor (SRF) is a MADS transcription factor that binds to the CArG box sequence of the serum response element (SRE). Through its binding to CArG sequences, SRF activates several muscle-specific genes as well as genes that respond to mitogens. The thermodynamic parameters of the interaction of core-SRF (the 124-245 fragment of serum response factor) with specific oligonucleotides from c-fos and desmin promoters, were determined by spectroscopy. The rotational correlation time of core-SRF labeled with bis-ANS showed that the protein is monomeric at low concentration (10(-7) m). The titration curves for the fluorescence anisotropy of fluorescein-labeled oligonucleotide revealed that under equilibrium conditions, the core-SRF monomers were bound sequentially to SRE at very low concentration (10(-9) m). Curve-fitting data showed also major differences between the wild-type sequence and the oligonucleotide sequences mutated within the CArG box. The fluorescence of the core-SRF tyrosines was quenched by the SRE oligonucleotide. This quenching indicated that under stoichiometric conditions, core-SRF was bound as a dimer to the wild-type oligonucleotide, and as a monomer or a tetramer to the mutant oligonucleotides. Far-UV CD spectra indicated that the flexibility of core-SRF changed profoundly upon its binding to its specific target SRE. Lastly, the rotational correlation time of fluorescein-labeled SRE revealed that formation of the specific complex was accompanied by a change in the SRE internal dynamics. These results indicated that the flexibility of the two partners is crucial for the DNA-protein interaction.

Inhibitory effect of fucoidan on the adhesion of adenocarcinoma cells to fibronectin.

Fucoidans inhibit tumour cell adhesion to various substrata, but their mechanisms of action are not fully understood. Using 3H-fucoidan, we observed that fucoidan binds to fibronectin, this binding being saturable and sensitive to ionic strength and pH. The interaction occurred on at least four different sites along the polypeptide chain, two of them being the heparin-binding sequences. Moreover, when MDA-MB-231 tumour cells were exposed to DTAF-fucoidan, internalization occurred and punctuated vesicles were observed in the perinuclear region. The treated cells also showed a different morphology with a cytoskeleton devoid of vinculin and a reorganiztion of the repartition of the integrin-alpha5 subunit on the cell surface. Based on these data, we hypothesize that fucoidan inhibits the adhesion of MDA-MB-231 cells to fibronectin i) by blocking the protein's heparin- and cell-binding domains, ii) by modulating the reorganization of the integrin alpha5 subunit and iii) by down-regulating the expression of vinculin.

Structure-based virtual screening: an application to human topoisomerase II alpha.

The eukaryotic topoisomerase II is involved in several vital processes, such as replication, transcription, and recombination. Many compounds interfering with the catalytic action of this enzyme are efficient in human cancer chemotherapy. We applied a methodology combining molecular modeling and virtual screening techniques to identify human topoisomerase II alphainhibitors. Data from structural biology and enzymatic assays together with a good background on the enzyme mechanism of action were helpful in the approach. A human topoisomerase II alpha model provided an insight into the structural features responsible for the activity of the enzyme. A protocol comprising several substructural and protein structure-based three-dimensional pharmacophore filters enabled the successful retrieving of inhibitors of the enzyme from large databases of compounds, thus validating the approach. A subset of protein structural features required for the enzyme inhibition at the protein-DNA interface were identified and incorporated into the pharmacophore models. Compounds sharing a DNA-intercalating chromophore and a moiety interfering with the protein active site emerged as good inhibitors.

Use of Chlamydomonas reinhardtii mutants for anticancer drug screening.

We investigated the possibility of utilizing alga cells instead of mammalian cells for the screening of anticancer drugs. The alga cells grow in synthetic media whereas the mammalian cells require complex and more expensive media along with heavy investment and manpower. To assess the validity of this new approach, analysis of growth inhibition by antitumor agents was carried out jointly on a wall-less (cw15) mutant of Chlamydomonas reinhardtii, that obviates the problem of drug uptake, and the murine leukemic cell line L1210, commonly used for anticancer drug screening. The presence of the topoisomerases I and II (approximately 97 and approximately 2 x 170 kDa, respectively) in the nuclear extracts of C. reinhardtii and their possible role as targets of the drugs was also investigated. Concentrated extracts were separated into >100 and <100 kDa fractions and their topoisomerase I and II activities were measured on relaxation of supercoiled plasmid DNA, decatenation of the catenated kinetoplast DNA and cleavage of plasmid DNA. Our results do not show significant difference in growth inhibition by antitumorals between the wall-less mutant of the alga and the murine leukemic cell line L1210. We noted that alga cells were inhibited by antibiotics that target gyrase, a bacterial variant of topoisomerase II which is also found in chloroplasts. At the molecular level, the alga nuclear fractions, >100 and <100 kDa, displayed the same activities as the mammalian enzymes topoisomerases I and II, respectively, and were blocked by the same poisons. We concluded that the wall-less cw15 mutant of C. reinhardtii could advantageously replace mammalian cells in the screening of the anticancer drugs. The alga enzymes could also provide an opportunity to delineate the phylogeny of the topoisomerase superfamily.

Unprocessed viral DNA could be the primary target of the HIV-1 integrase inhibitor raltegravir.

Integration of HIV DNA into host chromosome requires a 3'-processing (3'-P) and a strand transfer (ST) reactions catalyzed by virus integrase (IN). Raltegravir (RAL), commonly used in AIDS therapy, belongs to the family of IN ST inhibitors (INSTIs) acting on IN-viral DNA complexes (intasomes). However, studies show that RAL fails to bind IN alone, but nothing has been reported on the behaviour of RAL toward free viral DNA. Here, we assessed whether free viral DNA could be a primary target for RAL, assuming that the DNA molecule is a receptor for a huge number of pharmacological agents. Optical spectroscopy, molecular dynamics and free energy calculations, showed that RAL is a tight binder of both processed and unprocessed LTR (long terminal repeat) ends. Complex formation involved mainly van der Waals forces and was enthalpy driven. Dissociation constants (Kds) revealed that RAL affinity for unbound LTRs was stronger than for bound LTRs. Moreover, Kd value for binding of RAL to LTRs and IC50 value (half concentration for inhibition) were in same range, suggesting that RAL binding to DNA and ST inhibition are correlated events. Accommodation of RAL into terminal base-pairs of unprocessed LTR is facilitated by an extensive end fraying that lowers the RAL binding energy barrier. The RAL binding entails a weak damping of fraying and correlatively of 3'-P inhibition. Noteworthy, present calculated RAL structures bound to free viral DNA resemble those found in RAL-intasome crystals, especially concerning the contacts between the fluorobenzyl group and the conserved 5'C(4)pA(3)3' step. We propose that RAL inhibits IN, in binding first unprocessed DNA. Similarly to anticancer drug poisons acting on topoisomerases, its interaction with DNA does not alter the cut, but blocks the subsequent joining reaction. We also speculate that INSTIs having viral DNA rather IN as main target could induce less resistance.