Characterisation and structural studies on dog heart cyclic nucleotide phosphodiesterase

Clapham, John Christopher

January 1997

No description available.

572

PDE inhibitors; Drug targets

Acanthamoeba mannose-binding protein : structural and functional characterisation of a therapeutic target for Acanthamoeba keratitis

Banjo, Taiwo Abayomi

January 2018

Acanthamoeba mannose-binding protein (AcMBP) is a virulence factor of the free-living amoeba, Acanthamoeba castellanii. It is crucial for the development of Acanthamoeba keratitis (AK), a corneal infection that often causes blindness. AK is associated with contact lens use and contaminated water sources. Therapeutic unresponsiveness is attributed to similarities in the biological processes that Acanthamoeba shares with humans and its ability to form drug-resistant cysts. I aimed to characterise AcMBP as a basis for developing future drugs against Acanthamoeba. To start with, I carried out morphological studies on the two well-known life stages of Acanthamoeba and characterised a third stage: the protocysts. Mature cysts and protocysts could not interconvert directly, but always excysted to trophozoites. This is important because Acanthamoeba can potentially be trapped as protocysts, which are likely to be more susceptible to drugs. I also studied Acanthamoeba adhesion towards various surfaces and cytopathic activities towards cells (including human corneal epithelial cells). Whilst AcMBP was important for adhesion, it is not the only receptor involved. To gain structure/function information, I expressed the extracellular portion of AcMBP and three truncated fragments. AcMBP is a Ca2+-dependent lectin (~100 kDa) that binds to mannose. Ca2+ is essential for lectin activity and stability. The extracellular fragment is monomeric, indicating that trimerisation, shown previously, depends on the membrane-spanning and/or intracellular regions. Bioinformatics revealed that lectin activity is almost certainly located in a DUF 4114 domain (~10 kDa, DUF: domain of unknown function). N-terminal fragments, including the DUF4114 domain did not bind to mannose-Sepharose, suggesting that part of the cysteine-rich domain is also important. AcMBP bound to a variety of mammalian glycans so may have more than one lectin activity. Although attempts to crystallise AcMBP were unsuccessful, future structural analysis will be useful for defining the domains and determining how it binds to mannose.

High quality genome-scale metabolic network reconstruction of Mycobacterium tuberculosis and comparison with human metabolic network : application for drug targets identification

Kalapanulak, Saowalak

January 2009

Mycobacterium tuberculosis (Mtb), a pathogenic bacterium, is the causative agent in the vast majority of human tuberculosis (TB) cases. Nearly one-third of the world’s population has been affected by TB and annually two million deaths result from the disease. Because of the high cost of medication for a long term treatment with multiple drugs and the increase of multidrug-resistant Mtb strains, faster-acting drugs and more effective vaccines are urgently demanded. Several metabolic pathways of Mtb are attractive for identifying novel drug targets against TB. Hence, a high quality genome-scale metabolic network of Mtb (HQMtb) was reconstructed to investigate its whole metabolism and explore for new drug targets. The HQMtb metabolic network was constructed using an unbiased approach by extracting gene annotation information from various databases and consolidating the data with information from literature. The HQMtb consists of 686 genes, 607 intracellular reactions, 734 metabolites and 471 E.C. numbers, 27 of which are incomplete. The HQMtb was compared with two recently published Mtb metabolic models, GSMN-TB by Beste et al. and iNJ661 model by Jamshidi and Palsson. Due to the different reconstruction methods used, the three models have different characteristics. The 68 new genes and 80 new E.C. numbers were found only in the HQMtb and resulting in approximately 52 new metabolic reactions located in various metabolic pathways, for example biosynthesis of steroid, fatty acid metabolism, and TCA cycle. Through a comparison of HQMtb with a previously published human metabolic network (EHMN) in terms of protein signatures, 42 Mtb metabolic genes were proposed as new drug targets based on two criteria: (a) their protein functional sites do not match with any human protein functional sites; (b) they are essential genes. Interestingly, 13 of them are found in a list of current validated drug targets. Among all proposed drug targets, Rv0189c, Rv3001c and Rv3607c are of interest to be tested in the laboratory because they were also proposed as drug target candidates from two research groups using different methods.

579.135

Anti-Inflammatory PARP Inhibitor Demonstrates Antidepressant Activity in Animal Model of Treatment Resistant Depression

Ordway, Gregory A., Gill, W. D., Coleman, J. B., Wang-Heaton, Hui, Brown, Russell W.

01 May 2019

Background: Major depressive disorder is associated with elevated levels of DNA oxidation, DNA damage, and gene expression of DNA repair enzymes including poly (ADP-ribose) polymerase-1 (PARP1). Elevated PARP1 activity is directly linked to neuroinflammation and PARP inhibitors are anti-inflammatory and neuroprotective. We previously showed that PARP inhibitors produce antidepressant-like effects equivalent to fluoxetine in rodent models. Here, we examined whether the PARP inhibitor 3-aminobenzamide (3AB) is effective in a rat model of treatment-resistant depression. Methods: Treatment-resistant depression was modeled with injections of lipopolysaccharide (LPS; 0.1 ug/kg/day) and daily chronic unpredictable stress (CUS) for 28 days. Anhedonia and helplessness were indexed with sucrose preference and forced swim tests, respectively, in 5 groups of rats (n¼6-8 rats/group) including unstressed, CUS, and CUS+LPS rats treated with saline, and CUS+LPS rats treated with either 3AB or fluoxetine. Results: Anhedonia induced by CUS+LPS was significantly attenuated by 3AB (p¼0.01), while fluoxetine failed to do so. Likewise, 3AB was superior to fluoxetine in reducing helplessness, where latency to immobility times were significantly lower in CUS+LPS rats treated with fluoxetine (p¼0.001) compared to unstressed rats, but not significantly different for 3AB-treated CUS+LPS rats. Conclusions: The PARP inhibitor 3AB demonstrated robust and unique antidepressant activity superior to fluoxetine in the TRD rat model. PARP is linked to neuroinflammation through release of microglia-activating factors including poly (ADP-ribose) and HMGB1, and through NF-kB activation, pathways under investigation by our lab. PARP inhibitors are currently used clinically to facilitate cytotoxicity of DNA-damaging anti-cancer treatments. Further research could implicate re-purposing non-cytotoxic PARP inhibitors for treatment-resistant depression.

treatment-resistant depression

antidepressant

novel drug targets

neuroinflammation

drug re-purposing

Biomedical Sciences

The Cell Membrane Proteome of the SKBR3/HER2+ Cells and Implications for Cancer Targeted Therapies

Karcini, Arba

02 June 2023

Breast cancer is the second most common type of cancer among women in the US and the second leading cause of cancer death. HER2+ breast cancers represent ~20% of all cancer types, are highly invasive, and can be treated by using targeted therapies against the HER2 receptor. However, these therapies are challenged by the development of drug resistance, often induced by the presence of mutations in the cell-membrane proteins and receptors and/or by alternative signaling pathways that cross-talk with- or transactivate HER2+ triggered signaling. This study was aimed at investigating the cell membrane proteome of SKBR3 cells, representative of HER2+ breast cancers, and the signaling landscape and cellular responses elicited by the cell membrane receptors when the cells are stimulated with either growth factors or therapeutic drugs. It was hypothesized that the identification of a broad range of cell membrane proteins with roles in cancer progression and signaling crosstalk will lead to a more comprehensive understanding of the biological processes that sustain the proliferation of cancer cells, and will guide the selection of more efficient drug targets. The project was conceptualized in three stages: (1) profiling the cell membrane proteins of SKBR3 cells, (2) determining the functional role of the detected cell membrane proteins in the context of cancer hallmarks and exploring their mutational profile, and (3) analyzing the cellular events that occur in response to treatment with a single therapeutic agent or a combination of drugs. Mass spectrometry technologies were used for performing proteomic and phosphoproteomic profiling of SKBR3 cells, detecting changes in the abundance of the detected proteins, and identifying the presence of mutations in the cell membrane proteins. Orthogonal enrichment methods were developed for profiling the low-abundance cell membrane proteins, for generating a rich landscape of cell membrane receptors with various functional roles and relevance to the cancer hallmarks, and for enabling the detection of potentially new drivers of aberrant proliferation. The analysis of serum-starved, stimulated (with growth factors), or inhibited (with kinase inhibitors) cells revealed alternative protein players and crosstalk activities that determine the fate of cells, and that may fuel the development of resistance to treatment with drugs. The proteome profiles that were generated in this project expand the opportunities for targeting cancer-relevant processes beyond proliferation, which is commonly attempted, broadening the landscape to also include apoptosis, invasion, and metastasis. Altogether, the findings that emerged from this work will lay the ground for future studies that aim at developing more complex and effective targeted cancer treatment approaches. / Doctor of Philosophy / Breast cancer is one of the most common cancers among women in the US and the second major contributor to cancer-related deaths. Several therapies that have been developed for the treatment of cancer target the HER2 receptor, which is overexpressed in ~20% of breast cancers and results in a highly invasive cancer phenotype. However, most patients receiving these therapies observe cancer reoccurrence within a year due to the development of resistance to the therapeutic drug. The current challenge stands in identifying novel protein targets, and in developing new therapies that can be used in combination with the existing approaches to eradicate cancer. Research has indicated that proteins located at the cell membrane play crucial roles in cancer progression and invasion due to their involvement in cell response to stimuli and in initiating signaling cascades within the cell. Knowledge about the cell membrane proteins of HER2+ breast cancer cells is limited due to the challenges associated with their isolation. Therefore, this project was aimed at profiling the cell membrane proteins of HER2+ breast cancer cells, and their intra-cellular signaling activity, to provide insights into the behavior of these cells and to support the identification of potentially novel drug targets. The three objectives of the work were to (1) isolate the cell membrane proteins through various approaches using cell culture conditions that would encourage or discourage cancer cell growth, (2) identify the cancer-relevant signaling pathways and processes represented by the detected cell membrane proteins, and (3) investigate the behavior of cancer cells when treated with drugs. To approach these objectives, a powerful analytical technology, called mass spectrometry, was utilized. Mass spectrometry can accurately and simultaneously detect the presence of the proteins in a biological sample. Our study identified cell membrane proteins that are involved in cancer progression through various signaling pathways, and how these proteins interact with each other to drive the behavior of cells. The study also provided insights into how cancer cells respond when they are treated with various drugs, uncovering to the scientific community a variety of proteins with potential therapeutic value. Lastly, this study sheds light on the complex biology of breast cancer and highlights the importance of continued research to develop more effective treatments.

Proteomics

Mass spectrometry

Breast cancer

Signaling pathways

Drug targets

Cancer hallmarks

Phosphoproteomics

Proteogenomics

The Landscape of Host Transcriptional Response Programs Commonly Perturbed by Infectious Pathogens: Towards Host-Oriented Broad-Spectrum Drug

Kidane, Yared H.

30 April 2012

The threat from infectious diseases dates as far back as prehistoric times. Pathogens continue to pose serious challenges to human health. The emergence and spread of diseases such as HIV/AIDS, Severe Acute Respiratory Syndrome (SARS), avian influenza, and the threats of bioterrorism have made infectious diseases major public health concerns. Despite many successes in the discovery of anti-infective medications, the treatment of infectious diseases faces serious challenges, which include (i) the emergence and reemergence of infectious pathogens, (ii) the ability of pathogens to adapt and develop resistance to drugs, and (ii) a shortage in the development and discovery of new anti-infective drugs. Host-Oriented Broad-Spectrum (HOBS) treatments have the promising potential to alleviate these problems. The HOBS treatment paradigm focuses on finding drug targets in human host that are simultaneously effective against a wide variety of infectious agents and toxins. In this dissertation, we present a computational approach to predict HOBS treatments by integrative analysis of three types of data, namely, (a) gene expression data representing host responses upon infection by a pathogen, (b) annotations of genes to pre-defined biological pathways and processes, and (iii) genes that are targets of known drugs. Our methods combine gene set-level enrichment with biclustering. We applied our approach to a compendium of gene expression data sets derived from host cells exposed to bacterial or to fungal pathogens, to functional annotation data from multiple databases, and to drug targets from DrugBank. We present putative host drug targets and drugs with extensive support in the literature for their potential to treat multiple bacterial and fungal infections. These results showcase the potential of our computational approach to predict HOBS drug targets that may be effective against two or more pathogens. Our study takes a clean-slate approach that promises to yield unsuspected or unknown associations between pathogens and biological processes, and thus discern candidate gene/proteins to be further probed as HOBS targets. Furthermore, by focusing on host responses to pathogens as captured by transcriptional data, our proposed approach stimulates host-oriented drug target identification, which has potential to alleviate the problem of drug resistance. / Ph. D.

drug resistance

infectious diseases

immunomodulation

host transcriptional responses

Biochemical and drug targeting studies of Mycobacterium tuberculosis cholesterol oxidase P450 enzymes

Amadi, Cecilia Nwadiuto

January 2016

Mycobacterium tuberculosis (Mtb), a deadly pathogen, has scourged mankind for many centuries and has remained a major threat to global world health. Tuberculosis, the disease caused by this bacterium, is a major cause of death in developing nations and there is potential for its re-emergence in developed countries. An alarming rise in cases of multidrug-resistant and extremely-drug resistant tuberculosis (MDR-TB and XDR-TB) that do not respond to the customary first-line antibiotics necessitates the urgent need for development of new anti-TB drugs. Mtb becomes engulfed in human macrophages post infection of the host, but persists in the harsh environment of the human lungs by utilization of host cholesterol as a carbon source. The P450s CYP125A1, CYP142A1 and CYP124A1 are responsible for catalysing the side-chain degradation of cholesterol, which is critical for cholesterol to be used in the Mtb β-oxidation pathway for energy production. This PhD thesis focuses on understanding the structure/mechanism of the Mtb cholesterol 27-oxidases with the aim of facilitating the development of novel inhibitors of these P450s, which are crucial for Mtb to infect the host and to sustain infection. CYP142A1 and CYP124A1 were purified through three chromatographic steps with contaminating proteins successfully removed to give highly pure forms of these enzymes following the final purification step. Spectrophotometric titrations indicate that CYP142A1 and CYP124A1 bind tightly to cholesterol and cholestenone (and also to branched-chain methyl lipids for CYP124A1), highlighting their physiological roles in sterol and fatty acid metabolism, respectively. Binding analyses with a range of azole antibiotics revealed tight binding to bifonazole, clotrimazole, miconazole and econazole, and weak binding to fluconazole. Studies with compounds from a fragment screening library revealed weak binding to fragment hits for the cholesterol oxidases, but much tighter binding to these enzymes was found for ‘elaborated’ hits from a previous fragment screen on the Mtb cyclodipeptide oxidase CYP121A1, indicative of improved ligand potency achieved via ‘fragment merging’ strategies, and of structural similarities between these diverse Mtb P450s. Light scattering data indicate that CYP142A1 exists in dimeric form in solution, but becomes monomeric when treated with DTT; while CYP124A1 is completely monomeric. Crystal structures of CYP142A1 and CYP124A1 in complex with cholestenone, econazole and fragment library hits were determined. CYP142A1 crystal structures with econazole and fragment hits revealed heme coordination via the heterocyclic nitrogen in an azole group, and provide important data towards design of superior inhibitor drugs. The binding of cholestenone within the active site channels of CYP124A1 and CYP142A1 revealed an alignment favourable for C27 hydroxylation of the cholestenone side chain, which supports the physiological roles of CYP142A1 and CYP124A1 (as well as CYP125A1) in host cholesterol catabolism.

615.1

Studies of Retroviral Reverse Transcriptase and Flaviviral Protease Enzymes as Antiviral Drug Targets : Applications in Antiviral Drug Discovery & Therapy

Junaid, Muhammad

January 2012

Viruses are a major threat to humans due to their unique adaptability, evolvability and  capability to control their hosts as parasites and genetic elements. HIV/AIDS is the third largest cause of death by infectious diseases in the world, and drug resistance due to the viral mutations is still the leading cause of treatment failure. The flaviviruses, such as Dengue virus (DEN) and Japanese encephalitis virus (JEV), represent other major cause of morbidity and mortality, and the areas where these viruses are endemic are spreading rapidly. No curative therapy for any flavivirus could be made available as yet. The first part of this thesis focuses on the HIV-1 drug resistance caused by mutations in a major HIV drug target, the HIV-1 reverse transcriptase (RT) as a response to the largest class of clinically used anti-retrovirals, the NRTIs. A robust proteochemometric model was created to analyse the complex mutation patterns in RT drug resistance. The model identified more than ten frequently-occurring mutations, each conferring at least two-fold decrease in susceptibility for one or several NRTIs. Using our prediction server (hivdrc.org), the model can be applied to propose optimum combination therapy for patients harbouring mutated HIV variants. The second part of the thesis encompasses studies on a promising drug target, the NS2B(H)-NS3pro, in two flaviviruses, namely the dengue virus (DEN) and Japanese encephalitis virus (JEV). Functional determinants of DEN NS2B(H)-NS3pro were identified by site-directed mutagenesis. Further, peptide inhibitors were designed using proteochemometrics (PCM) and statistical molecular design (SMD), synthesized and assayed on DEN proteases, which resulted in some novel peptides with low micromolar or sub-micromolar inhibitor activity. The very poorly characterised JEV NS2B(H)-NS3pro  was cloned, purified and the kinetic parameters of this attractive drug target were determined for a series of model substrates and inhibitor. The results identified the role in target-ligand interaction of different residues on specific positions in the target (NS2B(H)-NS3pro) and ligands (substrates/inhibitors). Overall, the findings in this thesis contribute to rational antiviral drug discovery and therapy.

Virus

enzymes

HIV/AIDS

retroviral reverse transcriptase

flaviviral protease

NRTIs

proteochemometrics

drug resistance

DEN

JEV

NS2B(H)-NS3pro

antiviral

drug targets

drug discovery

drug therapy.

Proteomická analýza rozpustných i membránových proteinů buněk lymfomu / Proteomic analysis of soluble and transmembrane proteins in human lymphoma cells

Vít, Ondřej

January 2017

In the works presented here, we studied molecular changes associated with drug resistance in human mantle cell lymphoma (MCL) cells using proteomics. Our analyses allowed us to identify causal and/or secondary changes in protein expression associated with the development of resistance to the experimental drug TRAIL and the clinically used antimetabolites cytarabine and fludarabine. Resistance of MCL cells to the recombinant proapoptotic cytokine TRAIL was associated with downregulation of key enzymes of purine metabolism. This pathway potentially represents a molecular "weakness", which could be used as a therapeutic target for selective elimination of such resistant cells. Resistance to the pyrimidine analog drug cytarabine was associated with cross-resistance to other antinucleosides. Proteomic and transcriptomic analyses showed pronounced downregulation of deoxycytidine kinase (dCK), which activates both purine and pyrimidine antinucleosides. This change explains the cross-resistance and is the causal mechanism of resistance to cytarabine. Our observations suggest that MCL patients, who do not respond to cytarabine-based therapy, should be treated with non-nucleoside drugs. MCL cells resistant to purine-derived antinucleoside fludarabine were cross-resistant to all tested antinucleosides and...

Gitelman & Gordon : mirror image syndromes reveal the roles of WNKs in blood pressure homeostasis and novel anti-hypertensive targets

Siew, Keith

January 2019

Study of Gordon (PHAII) and Gitelman (GS) syndromes revealed the importance of the WNK pathway and thiazide-sensitive Na-Cl Cotransporter (NCC) in the renal control of blood pressure. PHAII mutations lead to WNK accumulation resulting in the hyperphosphorylation of the downstream effector, SPAK, which overactivates NCC causing salt retention and hypertension. Mutations causing deletion of exon-9 in Cullin-3, which normally ubiquitylates WNKs for degradation, were recently discovered to cause the severest subtype of PHAII (PHA2E) with early onset salt-sensitive hypertension and hyperkalaemia. The reasons for this severity have remained elusive, however clues came from SPAK knock-out mice which recapitulate GS, the phenotypic mirror image of PHAII, typically caused by activation-inhibiting NCC phosphorylation site mutations resulting in salt-wasting and hypotension. As these mice were also discovered to have reduced vascular tone, it suggests the WNK pathway may have extra-renal roles in vascular smooth muscle function and highlights inhibition of SPAK function as a promising anti-hypertensive strategy with multiple sites of action. To address these possibilities the work aimed to phenotype: (1) heterozygous CUL3$^{WT/\Delta403-459}$ mice to investigate a possible vascular contribution to PHAII pathophysiology, (2) homozygous knock-out mice of MO25, a master regulator known to increase SPAK activity up to 100-fold independent of WNKs, and (3) homozygous SPAK$^{L502A/L502A}$ knock-ins, predicted to have disrupted SPAK binding to WNK/NCC, in order to validate SPAK signalling inhibition as a viable anti-hypertensive strategy. In mice, the CUL3$^{\Delta403-459}$ proteins are hyperflexible, hypermodified and ultimately have reduced WNK ubiquitylation. This lead to hypertension, hyperkalaemia, hyperchloraemia with compensated metabolic acidosis and growth retardation, which closely recapitulates human PHA2E. The discovery of increased vascular tone suggests an explanation for the severity of CUL3$^{\Delta}$$^{ex9}$PHAII. In mice, homozygous MO25$\alpha$ knock-out proved embryonically lethal, while homozygous MO25$\beta$ knock-out did not meaningfully alter blood pressure or electrolyte homeostasis. However, the SPAK$^{L502A}$ protein had a decreased ability to bind WNKs and cation-chloride cotransporters NCC and NKCC1/2, serving to reduce their activation. SPAK$^{L502A/L502A}$ mice showed typical features of GS with mild hypokalaemia, hypomagnesaemia, hypocalciuria and salt-wasting hypotension. The mice also presented with decreased markers of vascular tone potentially due to effects on cardiovascular and neuronal NKCC1. These results show that SPAK binding is crucial for blood pressure control and pharmacological inhibition of this binding is an attractive anti-hypertensive strategy.