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In this thesis, computational structure-based design approaches were employed to target the HIV-1 integrase and the macrophage infectivity potentiator (MIP) of Legionella pneumophila. The thesis yields valuable information about the mechanism of action of a known class of integrase inhibitors and a novel approach towards enzyme inhibition, which still is mainly unaddressed in current integrase research. For the MIP enzyme, two small-molecule MIP inhibitors were discovered. The computational studies of HIV-1 integrase have provided valuable information for IN inhibitor design. Docking experiments supported the hypothesis that the well-known diketo acid inhibitors enter the IN active site not as free ligands, but rather as metal complexes. These results help to reveal the mechanism of action of this important class of IN inhibitors.To give an impulse for the development of a novel class of inhibitors, a new strategy towards IN inhibition was introduced: An alternative binding site, the dimerization interface of an IN catalytic core domain monomer, was explored for inhibitor design. The lack of structural data of the free monomer was overcome by extensive MD studies. Snapshots derived from the MD simulation were used as protein input structures in a docking study with the inhibitory peptide YFLLKL to reveal its potential binding mode. The docking procedure showed that the peptidic ligand binds to a dimerization interface conformation which shows a Y-shaped binding site.. The next step was to address this protein conformation with small, non-peptidic molecules. The first strategy towards finding small-molecule interface binders was to create a pharmacophore model with hydrophobic features and shape constraints, aiming to find molecules with a good complementarity to the Y-shaped dimerization interface. Virtual screening yielded a total of 10 compounds, which all displayed good shape complementarity and favorable hydrophobic interactions. Unfortunately, none of the compounds showed a reproducible inhibitory activity in biological assays. Some doubts remain about the validity of the assay results: The use of BSA was critical, since it is not unlikely that BSA “intercepted” the hydrophobic candidate compounds. The first strategy towards finding small-molecule dimerization inhibitors was reconsidered: In the second approach, the satisfaction of hydrogen bonding residues at the dimerization interface, was of major interest. Two pharmacophore models were employed, which retrieved several hundred hit molecules. However, docking of these molecules showed that still many hydrogen bonding groups of the protein remained unaddressed by the ligands. Eventually, after visual inspection, only eight molecules were selected as candidate compounds for further testing (results pending). This small “yield” underlines the difficulties in finding interface binders: The IN dimerization interface is a peculiar target with frequently alternating basic, acidic, and hydrophobic residues. It is not a well-ordered binding site with continuous hydrophobic areas and distinct hydrogen bond donors / acceptors. Other protein-protein interfaces show such well-ordered binding sites. Accordingly, the peculiarity of the IN dimerization interface, in addition to the delicate task of disrupting protein-protein interactions at all, makes the development of IN dimerization inhibitors very challenging. For MIP, the studies revealed two experimentally validated MIP inhibitors, which significantly reduce MIP enzymatic activity. To our knowledge, no small-molecule MIP inhibitor has been reported in the literature so far. A detailed analysis of the available structural data of MIP and a comparison to the human PPIase counterpart, FKBP12, pointed out a conformational diversity among the MIP structures and a crucial difference between the two PPIases, which could be traced to mainly one residue (Tyr109). The detailed comparison of FKBP12 and MIP complex structures made it possible to give an explanation, why a ketoacyl-substituted pipecoline derivative most probably does not bind to MIP, but a sulfone-substituted pipecoline derivative does bind to MIP. Knowledge of Legionella MIP inhibitors could be transferred also to other organisms (e.g. trypanosoms), where homologous MIP proteins are also pathological factors.
A CD8+ cell-mediated host defense relies on cognate killing of infected target cells and on local inflammation induced by the secretion of IFN-g. Using assays of single cell resolution, it was studied to what extent these two effector function of CD8+ cells are linked. Granzyme B (GzB) is stored in cytolytic granules of CD8+ cells and its secretion is induced by antigen recognition of these cells. Following entry into the cytosol GzB induces apoptosis in the target cells. It was measured whether GzB release by individual CD8+ cells is accompanied by the secretion of IFN-gƒnƒnand of other cytokines. HIV peptide libraries were tested on bulk peripheral blood mononuclear cells and on purified CD4+ and CD8+ cells obtained from HIV infected individuals. The library included a panel of previously defined HLA class I restricted HIV peptides and an overlapping 20-mer peptide-series that covered the entire gp120 molecule. To characterize the in vivo differentiation state of the T-cells, freshly isolated lymphocytes were tested in assays of 24h duration. The data showed that only ~20% of the peptides triggered the release of both GzB and IFN-g from CD8+ cells. The majority of the HIV peptides induced either GzB or IFN-g, ~40% in each category. The GzB positive, IFN-g negative CD8+ cells did not produce IL-4 or IL-5, which suggests that they do not correspond to Tc2 cells but represent a novel Tc1 subclass, which was termed Tc1c. Also the IFN-g positive, GzB negative CD8+ cell subpopulation represents a yet undefined CD8+ effector cell lineage that was termed Tc1b. Tc1b and Tc1c cells are likely to make different, possibly antagonistic contributions to the control of HIV infection. Since IFN-g activates HIV replication in latently infected macrophages, the secretion of this cytokine by Tc1b cells in the absence of killing may have adverse effects on the host defense. In contrast, cytolysis by Tc1c cells in the absence of IFN-g production might represent the protective class of response. Further studies in the field of Tc1 effector cell diversity should lead to valuable insights for management of infections and developing rationales for vaccine design.
HIV infection of CD4+ peripheral blood lymphocytes leads to a loss of MHC dass I molecules on the surface of the infected cells as detectable by monodonal antibody staining and flow cytometry. Incubation of the infected cells at 26 oe or treatment at 37 oe with peptides leads to upregulation of MHC dass I to levels equal to those found on uninfected cells cultured und er the same conditions. The data suggest that, after HIV infection, the mechanisms responsible for peptide generation, peptide transport and thus stable association between peptides and MHC dass I molecules are severely affected.
To study the activation of HIV by human spumaretrovirus (HSRV) the long terminal repeats (LTRs) of HSRV, HIVl and HIV2 were examined with respect to their ability to function as transcriptional promoters in virus infected and uninfected cells. Transient transfections using plasmids in which the L TRs of the three viruses were coupled to the bacterial chloramphenicol acetyltransferase (CA T) gene revealed (i) the level of cat gene expression directed by the HSRV LTR was markedly increased in HSRV infected cells compared to uninfected cells, (ii) cat gene expression driven by the HIV1 LTR, but not by the HIV2 LTR could be enhanced upon HSRV infection, whereas (iii) neither in HIV1 nor in HIV2 infected cells an effect on HSRV LTR driven cat geneexpression was detected.