Bachelor of Pharmacy

We present the molecular structure of the IsiA-Photosystem I (PSI) supercomplex, inferred from highresolution, crystal structures of PSI and the CP43 protein. The structure of iron-stress-induced A protein (IsiA) is similar to that of CP43, albeit with the difference that IsiA is associated with 15 chlorophylls (Chls), one more than previously assumed. The membrane-spanning helices of IsiA contain hydrophilic residues many of which bind Chl. The optimal structure of the IsiA-PSI supercomplex was inferred by systematically rearranging the IsiA monomers and PSI trimer in relation to each other. For each of the 6,969,600 structural configurations considered, we counted the number of optimal Chl-Chl connections (i.e., cases where Chlbound Mg atoms are ≤ 25 Å apart). Fifty of these configurations were found to have optimal energy-transfer potential. The 50 configurations could be divided into three variants; one of these, comprising 36 similar configurations, was found to be superior to the other configurations in terms of its potential to transfer excitation energy to the reaction centres under low-light conditions and its potential to dissipate excess energy under high-light conditions. Compared to the assumed model [Biochemistry 42 (2003) 3180-3188], the new Chl increases by 7% the ability of IsiA to harvest sunlight while the rearrangement of the constituent components of the IsiA-PSI supercomplex increases by 228% the energy-transfer potential. In conclusion, our model allows us to explain how the IsiA-PSI supercomplex may act as an efficient light-harvesting structure under low-light conditions and as an efficient dissipater of excess energy under high-light conditions.

Background: Helical membrane proteins are vital for the interaction of cells with their environment. Predicting the location of membrane helices in protein amino acid sequences provides substantial understanding of their structure and function and identifies membrane proteins in sequenced genomes. Currently there is no comprehensive benchmark tool for evaluating prediction methods, and there is no publication comparing all available prediction tools. Current benchmark literature is outdated, as recently determined membrane protein structures are not included. Current literature is also limited to global assessments, as specialised benchmarks for predicting specific classes of membrane proteins were not previously carried out.

Background: G protein-coupled receptors (GPCRs) are abundant, activate complex signalling and represent the targets for up to ~60% of pharmaceuticals but there is a paucity of structural data. Bovine rhodopsin is the first GPCR for which high-resolution structures have been completed but significant variations in structure are likely to exist among the GPCRs. Because of this, considerable effort has been expended on developing in silico tools for refining structures of individual GPCRs. We have developed REPIMPS, a modification of the inverse-folding software Profiles-3D, to assess and predict the rotational orientation and vertical position of helices within the helix bundle of individual GPCRs. We highlight the value of the method by applying it to the Baldwin GPCR template but the method can, in principle, be applied to any low-or high-resolution membrane protein template or structure.

With the continued growth of three dimensional structural information databases comes a corresponding increase in interest in this data for the study of new sequences and an ever-increasing incentive to improve automatic structure annotation methods. We examined various methods of presenting structural information in 3D, focussing on means of identifying regions of interest and the display of related structures. Using such information we investigated how this can be used to view variations between structures.

Fundamentally new approaches are required for the development of vaccines to pre-empt and protect against emerging and pandemic influenzas. Current strategies involve post-emergent homotypic vaccines that are modelled upon select circulating 'seasonal' influenzas, but cannot induce cross-strain protection against newly evolved or zoonotically introduced highly pathogenic influenza (HPI). Avian H5N1 and the less-lethal 2009 H1N1 and their reassortants loom as candidates to seed a future HPI pandemic. Therefore, more universal 'seasoned' vaccine approaches are urgently needed for heterotypic protection ahead of time. Pivotal to this is the need to understand mechanisms that can deliver broad strain protection. Heterotypic and heterosubtypic humoral immunities have largely been overlooked for influenza cross-protection, with most 'seasoned' vaccine efforts for humans focussed on heterotypic cellular immunity. However, 5 years ago we began to identify direct and indirect indicators of humoral-herd immunity to protein sites preserved among H1N1, H3N2 and H5N1 influenzas. Since then the evidence for cross-protective antibodies in humans has been accumulating. Now proposed is a rationale to stimulate and enhance pre-existing heterotypic humoral responses that, together with cell-mediated initiatives, will deliver pre-emptive and universal human protection against emerging epidemic and pandemic influenzas.

The structures, molecular interactions and functions of CD4 in a subset of T lymphocytes have been well characterized. The CD4 receptors of other cell types have, however, been poorly documented. We have previously shown that lymphocytes and monocytes/macrophages differ in their expression of CD4 monomers and dimers. In the present study, we have shown further significant differences. Variability in the blocking of CD4 mAb binding by sulfated polyanions indicated differences in exofacial CD4 structures. In contrast to the well-documented 55 kDa monomers in lymphocytic cells, monocytic cells were found to coexpress two monomer isoforms: the 55 kDa form and a novel 59 kDa species. Experimental uncoupling of CD4 disulfides indicated that the oxidized 55 kDa monomer could be converted to the 59 kDa form. This was achieved by chemical reduction of purified native or recombinant CD4, or in cell transfection experiments by mutation of cysteine to alanine in domain 1 (D1) (Cys16 or Cys84) and in domain 4 (D4) (Cys303 or Cys345). All of these modifications promote CD4 distension on SDS-PAGE analysis and indicate that, when CD4 interb-sheet disulfides in the D1 and D4 Ig folds are disrupted, there is an unravelling of the oxidized form to an extended 59 kDa unfolded state. We hypothesize that this may be a transition-state, structural-intermediate in the formation of disulfide-linked homodimers. Also identified were CD4-tyrosine kinase dissimilarities in which lymphocyte CD4 associated with Lck, but monocyte CD4 associated with HcK. These findings show that there is complex heterogeneity in structures and interactions in the CD4 of T lymphocytes and monocytes.

The vitamin D receptor (VDR) is a ligand-dependent transcription factor that heterodimerizes with retinoid X receptor (RXR) and interacts with the basal transcription machinery and transcriptional cofactors to regulate target gene activity. The p160 coactivator GRIP1 and the distinct coregulator Ski-interacting protein (SKIP)/NCoA-62 synergistically enhance ligand-dependent VDR transcriptional activity. Both coregulators bind directly to and form a ternary complex with VDR, with GRIP1 contacting the activation function-2 (AF-2) domain and SKIP/NCoA-62 interacting through an AF-2 independent interface. It was previously reported that SKIP/NCoA-62 interaction with VDR was independent of the heterodimerization interface (specifically, helices H10/H11). In contrast, the present study defines specific residues within a conserved and surface-exposed region of VDR helix H10 that are required for interaction with SKIP/NCoA-62 and for full ligand-dependent transactivation activity. SKIP/NCoA-62, the basal transcription factor TFIIB, and RXR all interacted with VDR helix H10 mutants at reduced levels compared with wild type in the absence of ligand and exhibited different degrees of increased interaction upon ligand addition. Thus, SKIP/ NCoA-62 interacts with VDR at a highly conserved region not previously associated with coregulator binding to regulate transactivation by a molecular mechanism distinct from that of p160 coactivators.

Major histocompatibility complex (MHC) class I molecules are transmembrane glycoproteins that present antigenic peptides to CD81 T cells and are subsequently important for the initiation of an immune response. In this study novel MHC class I sequences from the tammar wallaby (Macropus eugenii) have been characterized. Analysis and comparative modeling of these and existing marsupial molecules reveals potential functional polymorphisms within peptide-binding grooves, MHC assembly motifs and the T cell receptor recognition interface. In addition, we show that a previously identified marsupial-specific insertion is within a region, which is known as a putative NK cell receptor (Ly49A) binding site in the mouse, suggesting that this site may be functionally active in marsupials. Further, the analysis highlighted differences in structural and sequence based grouping of marsupial MHC class I molecules.

The development of high-throughput genome sequencing and protein structure determination techniques have provided researchers with a wealth of biological data. Integrated analysis of such data is difficult due to the disparate nature of the repositories used to store this biological data and of the software used for its analysis. This paper presents a framework based upon the use of semi-structured database management systems that would provide an integrated interface for the collection, storage and retrieval of biological data from existing repositories and of biological information generated by existing analysis programs. A simple implementation that integrates information from databases and analytical programs is presented as a proof of concept.

Human interferond (HuIFNa8), a type I interferon (IFN), is a cytokine belonging to the hematopoietic superfamily that includes human growth hormone (HGH). Recent data identified two human type I IFN receptor components. One component (p40) was purified from human urine by its ability to bind to immobilized type I IFN. A second receptor component (IFNAR), consisting of two cytokine receptor-like domains (D200 and D200'), was identified by expression cloning. Murine cells transfected with a gene encoding this protein were able to produce an antiviral response to human IFNa8. Both of these receptor proteins have been identified as members of the immunoglobulin superfamily of which H G H receptor is a member. The cytokine receptor-like structural motifs present in p40 and IFNAR were modeled based on the HGH receptor X-ray structure. Models of the complexes of HuIFNa8 with the receptor subunits were built by superpositioning the conserved C a backbone of the HuIFNa8 and receptor subunit models with HGH and its receptor complex. The HuIFNa8 model was constructed from the Ca coordinates of murine interferon-p crystal structure. Electrostatic potentials and hydrophobic interactions appear to favor the model of HuIFNa8 interacting with p40 at site 1 and the D200' domain of IFNAR at site 2 because there are regions of complementary electrostatic potential and hydrophobic interactions at both of the proposed binding interfaces. Some of the predicted receptor binding residues within HuIFNa8 correspond to functionally important residues determined previously for human IFNal, IFNa2, and IFNa4 subtypes by site-directed mutagenesis studies. The models predict regions of interaction between HuIFNa8 and each of the receptor proteins, and provide insights into interactions between other type I IFNs (IFN-a subtypes and IFN-p) and their respective receptor components.

The Profiles-3D application, an inverse-folding methodology appropriate for water-soluble proteins, has been modified to allow the determination of structural properties of integral-membrane proteins (IMPs) and for testing the validity of solved and model structures of IMPs. The modification, known as reverseenvironment prediction of integral membrane protein structure (REPIMPS), takes into account the fact that exposed areas of side chains for many residues in IMPs are in contact with lipid and not the aqueous phase. This (1) allows lipid-exposed residues to be classified into the correct physicochemical environment class, (2) significantly improves compatibility scores for IMPs whose structures have been solved, and (3) reduces the possibility of rejecting a three-dimensional structure for an IMP because the presence of lipid was not included. Validation tests of REPIMPS showed that it (1) can locate the transmembrane domain of IMPs with single transmembrane helices more frequently than a range of other methodologies, (2) can rotationally orient transmembrane helices with respect to the lipid environment and surrounding helices in IMPs with multiple transmembrane helices, and (3) has the potential to accurately locate transmembrane domains in IMPs with multiple transmembrane helices. We conclude that correcting for the presence of the lipid environment surrounding the transmembrane segments of IMPs is an essential step for reasonable modeling and verification of the three-dimensional structures of these proteins.

Juvenile Hormone Esterase (JHE) plays an essential role in the development of insects since it is partially responsible for clearing juvenile hormone (JH), one of the hormones that is responsible for insect metamorphosis. JHE is a 60 kDa enzyme that selectively hydrolyzes the ␣/␤ unsaturated ester of JH. Because of its pivotal role in insect development, we have targeted JHE for use as a biopesticide. In this study, we have constructed a homology-based molecular model of JHE from the agricultural crop pest, Heliothis virescens. JHE is a member of the ␣/␤ hydrolase fold family of enzymes and was built according to two structures in the same family: acetylcholinesterase from Torpedo californica and lipase from Geotrichum candidum. Analysis of the active site region reveals extensive conservation between JHE and its templates. A surprise was the presence of a conserved Ser near the catalytic triad. Docking of JH III into the active site has provided insight into protein-substrate interactions that are corroborated by experimental observation. The model is being used as a predictive basis to design biopesticides. In this regard, we have identified a site on the protein surface that is suggestive of a recognition site for the putative JHE receptor. Proteins 1999; 34: 184-196. 1999 Wiley-Liss, Inc.

The community-wide GPCR Dock assessment is conducted to evaluate the status of molecular modeling and ligand docking for human G proteincoupled receptors. The present round of the assessment was based on the recent structures of dopamine D3 and CXCR4 chemokine receptors bound to small molecule antagonists and CXCR4 with a synthetic cyclopeptide. Thirty-five groups submitted their receptor-ligand complex structure predictions prior to the release of the crystallographic coordinates. With closely related homology modeling templates, as for dopamine D3 receptor, and with incorporation of biochemical and QSAR data, modern computational techniques predicted complex details with accuracy approaching experimental. In contrast, CXCR4 complexes that had less-characterized interactions and only distant homology to the known GPCR structures still remained very challenging. The assessment results provide guidance for modeling and crystallographic communities in method development and target selection for further expansion of the structural coverage of the GPCR universe.

Of the 600+ known proteases identified in mammals, a significant percentage are involved or implicated in pathogenic and cancer processes. The Dipeptidyl Peptidase IV (DPIV) gene family, comprising four enzyme members DPIV, Fibroblast Activation Protein (FAP), DP8 and DP9 and two non-enzyme members DP6 (DPL1) and DP10 (DPL2), are interesting in this regard due to their multiple diverse functions, varying patterns of distribution/localisation and subtle but significant differences in structure/substrate recognition. In addition, their engagement in cell biological processes involves both enzymatic and non-enzymatic capabilities. This article examines in detail our current understanding of the biological involvement of this unique enzyme family and their overall potential as therapeutic targets.

Rhodopsin was the first G protein-coupled receptor (GPCR) for which a high-resolution crystal structure was obtained. Several crystal structures have now been solved representing different activation states of the receptor. These structures, together with those from lower resolution techniques (e.g. electron microscopy), shed light on the stepwise process by which energy from an extracellular photon is transduced across the membrane to the intracellular compartment thereby activating signalling mechanisms responsible for very low-level light detection. Controversy remains in several areas including: (i) transmembrane helix movements responsible for the transduction process, (ii) the stoichiometry of coupling to G proteins and their mode of activation, (iii) the role, if any, of receptor oligomerisation and (iv) the suitability of using structures of this GPCR as templates for modelling the structures of other GPCRs, and their mechanisms of activation.

High-molecular-weight arginine-and lysine-specific (Kgp) gingipains are essential virulence factors expressed by the oral pathogen Porphyromonas gingivalis. Haemagglutinin/adhesin (HA) regions of these proteases have been implicated in targeting catalytic domains to biological substrates and in other adhesive functions. We now report the crystal structure of the K3 adhesin domain/module of Kgp, which folds into the distinct b-jelly roll sandwich topology previously observed for K2. A conserved structural feature of K3, previously observed in the Kgp K2 module, is the half-way point anchoring of the surface exposed loops via an arginine residue found in otherwise highly variable sequences. Small-angle X-ray scattering data for the recombinant construct K1K2K3 confirmed a structure comprising a tandem repeat of three homologous modules, K1, K2 and K3 while also indicating an unusual 'y'-shape arrangement of the modules connected by variable linker sequences. Only the K2 and K3 modules and a K1K2 construct were observed to be potently haemolytic. K2, K3 and the K1K2 construct showed preferential recognition of haem-albumin over albumin whereas only low affinity binding was detected for K1 and the K1K2K3 construct. The data indicate replication of some biological functions over the three adhesin domains of Kgp while other functions are restricted.

It is estimated that 20% of genes in the human genome encode for integral membrane proteins (IMPs) and some estimates are much higher. IMPs control a broad range of events essential to the proper functioning of cells, tissues and organisms. IMPs include the most common targets of clinically useful drugs, such as the G protein coupled receptors (GPCR), the target for more than 50% of prescription drugs . However there is a dearth of high-resolution 3D structural information on the IMPs. The number of the IMPs depositions in the major structural holding, the Protein Data Bank is less than 0.4% of the collection [2]. Therefore good prediction methods of IMPs structures are to be highly valued. In this paper we apply Conditional Random Fields (CRFs) to build a probabilistic model to segment and label sequence data to solve the membrane protein helix prediction problem. The advantage of CRFs is that it allows seamless and principled integration of biological domain knowledge into the model. Our results show that the CRF model outperforms other well known helix prediction approaches on several important measures.

Hydrogen peroxide (H 2 O 2 ) can act as an intracellular messenger by oxidizing sulfhydryl groups in cysteines that can be oxidized at neutral pH. The oxidizing agents H 2 O 2 and pyrroloquinoline quinone and the large thiol reagents N-ethylmaleimide and 4-(hydroxymercuri) benzoate each inhibited dipeptidyl peptidase (DP) activity in the intracellular DPIV-related proteins DP8 and DP9 at pH 7.5. In contrast, these treatments did not alter activity in DPIV and fibroblast activation protein. Peptidase inhibition was completely reversed by 2-mercaptoethanol or reduced glutathione. Alkylation of DP8 by the small thiol reagent iodoacetamide prevented inhibition by H 2 O 2, N-ethylmaleimide or pyrroloquinoline quinone. Two cysteines were reactive per peptidase monomer. We exploited these properties to highly purify DP8 by thiol affinity chromatography. Homology modelling of DP8 and DP9 was consistent with the proposal that the mechanism involves decreased protein flexibility caused by intramolecular disulfide bonding. These novel data show that DP8 and DP9 are reversibly inactivated by oxidants at neutral pH and suggest that DP8 and DP9 are H 2 O 2 sensing proteins.