Surfactant proteins are well known from the human lung where they are responsible for the stability and flexibility of the pulmonary surfactant system. They are able to influence the surface tension of the gas–liquid interface specifically by directly interacting with single lipids. This work describes the generation of reliable protein structure models to support the experimental characterization of two novel putative surfactant proteins called SP-G and SP-H. The obtained protein models were complemented by predicted posttranslational modifications and placed in a lipid model system mimicking the pulmonary surface. Molecular dynamics simulations of these protein-lipid systems showed the stability of the protein models and the formation of interactions between protein surface and lipid head groups on an atomic scale. Thereby, interaction interface and strength seem to be dependent on orientation and posttranslational modification of the protein. The here presented modeling was fundamental for experimental localization studies and the simulations showed that SP-G and SP-H are theoretically able to interact with lipid systems and thus are members of the surfactant protein family.

4-Hydroxybenzoate oligoprenyltransferase of E. coli, encoded in the gene ubiA, is an important key enzyme in the biosynthetic pathway to ubiquinone. It catalyzes the prenylation of 4-hydroxybenzoic acid in position 3 using an oligoprenyl diphosphate as a second substrate. Up to now, no X-ray structure of this oligoprenyltransferase or any structurally related enzyme is known. Knowledge of the tertiary structure and possible active sites is, however, essential for understanding the catalysis mechanism and the substrate specificity.With homology modeling techniques, secondary structure prediction tools, molecular dynamics simulations, and energy optimizations, a model with two putative active sites could be created and refined. One active site selected to be the most likely one for the docking of oligoprenyl diphosphate and 4-hydroxybenzoic acid is located near the N-terminus of the enzyme. It is widely accepted that residues forming an active site are usually evolutionary conserved within a family of enzymes. Multiple alignments of a multitude of related proteins clearly showed 100% conservation of the amino acid residues that form the first putative active site and therefore strongly support this hypothesis. However, an additional highly conserved region in the amino acid sequence of the ubiA enzyme could be detected, which also can be considered a putative (or rudimentary) active site. This site is characterized by a high sequence similarity to the aforementioned site and may give some hints regarding the evolutionary origin of the ubiA enzyme.Semiempirical quantum mechanical PM3 calculations have been performed to investigate the thermodynamics and kinetics of the catalysis mechanism. These results suggest a near SN1 mechanism for the cleavage of the diphosphate ion from the isoprenyl unit. The 4-hydroxybenzoic acid interestingly appears not to be activated as benzoate anion but rather as phenolate anion to allow attack of the isoprenyl cation to the phenolate, which appeared to be the rate limiting step of the whole process according to our quantum chemical calculations. Our models are a basis for developing inhibitors of this enzyme, which is crucial for bacterial aerobic metabolism.

Brassinosteroids are a class of steroidal phytohormones with high growth-promoting properties. The preferred side-chain conformations of 10 brassinosteroids were determined by means of detailed NMR investigations and molecular-modeling studies. Vacuum conformations obtained by simulated annealing calculations and Boltzmann statistical analysis were compared with solution conformations derived from NOE experiments and molecular dynamic simulations, and with X-ray structures. In general, results from simulated annealing calculations and NMR-supported molecular dynamics simulations are in good agreement. For some of the compounds investigated the conformation was less well-defined at the end of the side-chain. It could be shown that the energetically most favorable and most probable conformations also include the conformations obtained by NMR supported molecular-dynamics calculations and by X-ray analysis. For the most bioactive compound brassinolide (1) the majority of conformations show a side-chain bent towards the β-face of the steroid skeleton, whereas for the less bioactive brassinosteroids, conformations with straight side-chains or side-chains bent towards the α-face are more frequent.

Cathepsin H is involved in intracellular protein degradation and is implicated in a variety of physiological processes such as proenzyme activation, enzyme inactivation, hormone maturation, tissue remodeling, and bone matrix resorption. A model of the tertiary structure of the human lysosomal cysteine protease cathepsin H was constructed. The protein structure was built from its amino acid sequence and its homology to papain, actinidin, and cathepsin L for which crystallographic co-ordinates are available. The model was generated using the COMPOSER module of SYBYL.The position and interaction behavior of the so called mini-chain, the octapeptide EPQNCSAT, to the active-site cleft of cathepsin H could be determined by docking studies. Refinement was achieved through interactive visual and algorithmic analysis and minimization with the TRIPOS force field. The model was found to correlate with observed empirical data regarding ligand specificity. The model defines possible steric, hydrophobic, and electrostatic interactions. We anticipate that the model will serve as a tool to understand substrate specificity and may be used for the development of new specific ligands.

The human immunodeficiency virus 1 Tat protein suppresses antigen-, anti-CD3-and mitogen-induced activation of human T cells when added to T cell cultures. This activity is important for the development of AIDS because lymphocytes from HIV-infected individuals exhibit a similar antigen-specific dysfunction. Moreover, Tat was found to interact with dipeptidyl peptidase IV (DP IV). To find out the amino acid sequence important for the inhibition of the DP IV enzymatic activity we investigated N-terminal Tat(1–9) peptide analogues with amino acid substitutions in different positions. Interestingly, the exchange of Pro6 with Leu and Asp5 with Ile strongly diminished the DP IV inhibition by Tat(1–9). Based on data derived from one-and two-dimensional 1H NMR investigations the solution conformations of the three nonapeptides in water were determined by means of molecular dynamics simulations. These conformations were used for studies of the docking behavior of the peptides into a model of the active site of DP IV. The results suggest that several attractive interactions between the native Tat(1–9) and DP IV lead to a stable complex and that the reduced affinity of both L6-Tat(1–9) and I5-Tat(1–9) derivatives might be caused by conformational alterations in comparison to the parent peptide.