Design, synthesis, and evaluation of cysteine protease inhibitors

Bridges, Sylvia Shadinger

09 June 2008

Proteases are enzymes that cleave protein amide bonds. Proteases are involved in a myriad of biological processes and are considered good targets for drug design. The proteases described herein are cysteine proteases, which utilize a cysteine residue thiol to attack the amide carbonyl, leading to amide bond cleavage. Irreversible inhibitors of cysteine proteases react with the active site cysteine, forming a covalent bond and rendering the enzyme inactive. The first project involved the design and synthesis of aza-peptide epoxide inhibitors for calpain, a clan CA, ubiquitous, calcium-activated human enzyme involved in neurodegeneration. These inhibitors proved to be poor inactivators of calpain, demonstrating that the aza-peptide epoxide is a warhead specific to clan CD cysteine proteases (caspases, gingipains). Subsequently, a known epoxide inhibitor of calpain was optimized to create a more potent inhibitor. Several of these inhibitors were more potent than the parent, and all were demonstrated to inhibit calpain in a breast cancer cell line which was treated with paclitaxel to spike calpain activity. The second project involved the design and solid phase synthesis of aza-peptide Michael acceptor caspases inhibitors. The two goals of this project were to develop a solid phase method for synthesis of inhibitors that are tedious to synthesize in solution phase, and to use a variety of amino acid residues to determine the optimal interactions in the P3? position for various caspases. The synthesis was successful, and the optimal P3? residues were determined. The third project involved the kinetic evaluation of aza-peptide epoxide and Michael acceptor inhibitor designed for the gingipains. Gingipains K and R are virulence factors in the pathology of Porphyromonas gingivalis involved in gingivitis and periodontal disease. These inhibitors proved to be extremely potent inactivators of gingipains, with some of the highest rates of inhibition measured in the Powers laboratory. Gingipain K preferred larger, aromatic moieties in the P1? position, while gingipain R preferred the Michael acceptor inhibitors, with the P1? substituent having less of an impact on potency.

Clostripain

Proteinase

Cysteine proteinases Inhibitors

Epigenetic regulation of gene expression of cystatin 6, CST6, in hepatocellular carcinoma

Ma, Ka-li, Marcella, 馬嘉莉

January 2005

published_or_final_version / Medical Sciences / Master / Master of Medical Sciences

Liver - Cancer - Genetic aspects.

Cysteine proteinases - Inhibitors.

Antioncogenes.

Genetic regulation.

Synthesis and kinetics of cysteine proteinase inhibitors

Tehrani, Kamin A.

08 1900

No description available.

Cysteine proteinases Inhibitors

Serine proteinases Inhibitors

Dynamics

Mechanics, Analytic

Motion

Synthesis and investigation of viral cysteine protease inhibitors and biosynthetic studies on subtilosin A

Miyyapuram, Venugopal

Unknown Date

No description available.

Peptide antibiotics -- Synthesis

Cyclic peptides -- Synthesis

SARS (Disease) -- Chemotherapy

Bacillus subtilis -- Genetics

Studies of genes expressed in the brain and regulated by transforming growth factor ��

Solem, Michele Lee

22 July 1992

Graduation date: 1993

Glycoproteins

Transforming growth factors-beta

Cysteine proteinases -- Inhibitors

Astrocytes

Gene expression

Genetic regulation

Design, synthesis and evaluation of cysteine protease inhibitors

Ovat, Asli

06 April 2009

Cysteine proteases are important drug targets due to their involvement in many biological processes such as protein turnover, digestion, blood coagulation, apoptosis, cell differentiation, cell signaling, and the immune response. In this thesis, we have reported the design, synthesis and evaluation of clan CA and clan CD cysteine protease inhibitors. Aza-peptidyl Michael acceptor and epoxide inhibitors for asparaginyl endopeptidases (legumains) from the bloodfluke, Schistosoma mansoni (SmAE) and the hard tick, Ixodes ricinus (IrAE) were designed and synthesized. SARs were similar, but with some notable exceptions. Both enzymes prefer disubstituted amides to monosubstituted amides in the P1' position and potency increased as we increased the hydrophobicity of the inhibitor in this position. Extending the inhibitor to P5 resulted in increased inhibitory potency, especially against IrAE, and both enzymes prefer small over large hydrophobic residues in the P2 position. Aza-peptide Michael acceptor inhibitors are more potent than aza-peptide epoxide inhibitors and, for some of these compounds, second order inhibition rate constants are the fastest yet discovered. We have also synthesized aza-peptidyl Michael acceptor and epoxide inhibitors for the parasitic cysteine proteases; cruzain, rhodesain. We have found that monosubstituted amides were favored over disubstituted amides indicating the involvement of the amide hydrogen in a H-bond network. We have shown that aza-peptide epoxides were as potent as Michael acceptors and we have obtained compounds with IC50 values as low as 20 nM. We have worked on the synthesis of heterocyclic peptidyl α-ketoamides, peptidyl ketones and aza-peptidyl ketones as calpain inhibitors. We have synthesized peptidyl α-ketoamides with nucleotide bases in the primed region to create compounds that can cross the blood-brain barrier. We have improved the potency by introducing a hydrophobic group on the adenine ring. We have obtained compounds with Ki values in the nanomolar range. We have designed peptidyl aminoketones as a new class of inhibitors for calpain. Peptidyl aminoketones were less potent than peptidyl α-ketoamides but still reasonable inhibitors of calpain that have the potential to cross the BBB.

Legumain

Calpain

Protease

Cysteine

Cysteine proteinases

Cysteine proteinases Inhibitors

Protease inhibitors

Biosynthesis

Epoxy compounds

Trypanopain : a possible target for anti-trypanosomal agents?

Troeberg, Linda.

January 1997

The protozoan parasite Trypanosoma brucei brucei causes nagana in cattle and is a widely used model for human sleeping sickness. The major lysosomal cysteine proteinases (trypanopains) of African trypanosomes may contribute to pathogenesis by degrading proteins in the mammalian bloodstream and also appear to be essential for the viability of T. cruzi and T. congolense. This study describes the first purification to electrophoretic homogeneity of trypanopain-Tb from T. b. brucei and the first reported characterisation of its enzymatic properties. Trypanopain-Tb was purified from bloodstream forms of T. b. brucei by a combination of three phase partitioning (between ammonium sulfate and tertiary butanol), and chromatography on quaternary amine or pepstatin A-Sepharose resins. Trypanopain-Tb was found to be a typical cysteine proteinase, in that it is inhibited by typical cysteine proteinase inhibitors and requires reducing agents for full activity. Trypanopain has cathepsin L-like specificity for synthetic substrates and readily degrades various proteins. In vitro analysis of the kinetics of trypanopain interaction with cystatins suggested that these are likely to inhibit any trypanopain released into the mammalian bloodstream. Furthermore, no trypanopain-like activity was detectable in the blood of infected hosts, so it appears that trypanopain is unlikely to contribute directly to pathogenesis by degrading bloodstream host proteins. Antibodies against a peptide corresponding to a region of the trypanopain active site were produced in rabbits and chickens. Both enzyme activity-enhancing and enzyme activity inhibiting antibodies were produced and these effects varied with the substrate tested. Thus, the in vivo effects of anti-trypanopain antibodies will only become clearly understood once the physiological substrates of trypanopain have been identified. Various cysteine proteinase inhibitors, including peptidyl diazomethylketones, killed cultured bloodstream forms of T. b. brucei. Use of biotinylated derivatives of peptidyl diazomethylketone and fluoromethylketone inhibitors suggested that trypanopain is the likely intracellular target of these inhibitors, indicating that the enzyme is essential for parasite viability. Furthermore, chalcones (a class of reversible cysteine proteinase inhibitors) killed in vitro cultured parasites and also prolonged the life of T. b. brucei-infected mice. Thus, trypanopain-Tb seems to be a possible target for new anti-trypanosomal drugs. / Thesis (Ph.D.)-University of Natal, Pietermaritzburg, 1997.

Trypanopain.

Cysteine proteinases--Inhibitors.

Trypanosomiasis--Chemoprevention.

Trypanosoma brucei--Control.

Proteolytic enzymes.

Theses--Biochemistry.

Characterisation of caspase- 14 in the human placenta : evidence for trophoblast-specific inhibition of differentiation by caspase- 14

White, Lloyd

January 2009

[Truncated abstract] The placenta forms a barrier regulating the transfer of gases, nutrients and wastes between the mother and the developing conceptus, and also produces hormones affecting both the fetus and the mother. This barrier is formed by the differentiation of the outer layer of the blastocyst- the trophoblast- to facilitate implantation and subsequent invasion of the uterus. The trophoblast consists of an underlying proliferative pool of cytotrophoblasts, which differentiate to replenish the overlying continuous, multi-nucleated syncytiotrophoblast that forms the barrier between the mother and fetus. Moreover, the location of the syncytiotrophoblast directly in contact with the maternal circulation suggests an endothelial role for the trophoblast regulating blood flow, thrombosis and immune cell adhesion. Disruption to the function of the human trophoblast may result in preeclampsia, a maternally manifested disorder of pregnancy characterised by hypertension and proteinurea. Blood flow to preeclamptic placentae is reduced and the cytotrophoblast pool is diminished; however the exact cause (or causes) remains elusive. Many potential causes are hypothesised, including endothelial damage, premature remodelling of maternal spiral arteries, increased oxidative stress and impaired trophoblast differentiation and apoptosis. Caspase-14 is an unusual caspase in that it is not involved in apoptosis. Furthermore, it possesses a limited, predominantly epithelial, tissue distribution. In the epidermis, caspase-14 is expressed in the apical differentiating layers. Here it cleaves profilaggrin to stabilise intracellular keratin intermediate filaments, and indirectly provides natural hydration and UV protection to the corneocytes. Thus, caspase-14 is vital to the maintenance of the barrier function of the skin. ... As differentiation-associated genes were elevated in the absence of caspase-14, this implies that caspase-14 suppresses biochemical trophoblast differentiation. The cytoskeletal keratin network was also examined following RNA Interference. The synthesis of cytokeratin 18 was significantly enhanced after caspase-14 suppression during BeWo differentiation, linking caspase-14 with keratin homeostasis. Therefore caspase-14 suppresses trophoblast differentiation, potentially through modulation of the cytoskeletal keratin filament network. The precise mechanism remains to be elucidated, however the identification of pathways regulated by caspase-14 advances our knowledge of trophoblast differentiation and potential causes of disorders of pregnancy. In summary, caspase-14 appears to be involved in the suppression of differentiation in the human trophoblast. As disorders of pregnancy such as preeclampsia often feature disturbed differentiation and a diminished cytotrophoblast pool, a greater understanding of caspase-14 biology in the human placenta could lead potential therapies for various disorders of pregnancy.

Cysteine proteinases -- Inhibitors

Trophoblast

Pregnancy proteins -- physiology

Placenta -- Molecular aspects

Reproductive biology

Placenta

Differentiation

Molecular biology

Falcipains as malarial drug targets

Kanzi, Aquillah Mumo

January 2013

Malaria is an infectious disease caused by parasites of the Plasmodium genus with mortality rates of more than a million annually, hence a major global public health concern. Plasmodium falciparum (P. falciparum) accounts for over 90% of malaria incidence. Increased resistance to antimalarial drugs by the Plasmodium parasite, coupled with the lack of an effective malaria vaccine necessitates the urgent need for new research avenues to develop novel and more potent antimalarial drugs. This study focused on falcipains, a group of P. falciparum cysteine proteases that belong to the clan CA and papain family C1, that have emerged as potential drug targets due to their involvement in a range of crucial functions in the P. falciparum life cycle. Recently, falcipain-2 has been validated as a drug target but little is known of its Plasmodium orthologs. Currently, there are several falcipain inhibitors that have been identified, most of which are peptide based but none has proceeded to drug development due to associated poor pharmacological profiles and susceptibility to degradation by host cysteine proteases. Non-peptides inhibitors have been shown to be more stable in vivo but limited information exists. In vivo studies on falcipain-2 and falcipain-3 inhibitors have also been complicated by varying outcomes, thus a good understanding of the structural variations of falcipain Plasmodium orthologs at the active site could go a long way to ease in vivo results interpretation and effective inhibitor design. In this study, we use bioinformatics approaches to perform comparative sequence and structural analysis and molecular docking to characterize protein-inhibitor interactions of falcipain homologs at the active site. Known FP-2 and FP-3 small molecule nonpeptide inhibitors were used to identify residue variations and their effect on inhibitor binding. This was done with the aim of screening a collection of selected non-peptide compounds of South African natural origin to identify possible new inhibitor leads. Natural compounds with high binding affinities across all Plasmodium orthologs were identified. These compounds were then used to search the ZINC database for similar compounds which could have better binding affinities across all selected falcipain homologs. Compounds with high binding affinities across all Plasmodium orthologs were found.

Malaria

Malaria -- Chemotherapy

Plasmodium falciparum

Antimalarials -- Development

Cysteine proteinases

Cysteine proteinases -- Inhibitors

Papain

Drug development

Bioinformatics

High-throughput modelling and structural investigation of cysteine protease complexes with protein inhibitors

Kroon, Matthys Christoffel

January 2013

The papain-like cysteine protease family (C1 proteases) is highly important because of its involvement in research and industrial applications and its role in various human diseases. Protein inhibitors are an important aspect of C1 protease biology and are relevant to its clinical, industrial and research importance. To study the interaction between the proteases and the inhibitors it is very useful to have accurate structural models of the protease-inhibitor complexes. To this end, a high-throughput pipeline for modelling complexes of papain-like cysteine proteases and protein inhibitors was implemented and tested (Tastan Bishop & Kroon, 2011). The pipeline utilizes a novel technique for obtaining modelling templates by using superpositioning to combine coordinates from separate experimental structures. To test the pipeline, models of complexes with known structures (test set) were modelled using many different templates and the resultant models evaluated to compare the quality of the different templates. It was found that use of the new technique to obtain templates did not introduce significant errors, while allowing closer homologs to be used for modelling - leading to more accurate models. The test set models were also used to evaluate certain steps of the modelling protocol. The effect of Rosetta energy minimization on model accuracy and the use of Rosetta energy and DOPE Z-score values to identify accurate models were investigated. Several complexes were then modelled using the best available templates according to criteria informed by the previous results. A website was built that allows a user to download any of the metrics or models produced in the study. This website is accessible at http://rubi.ru.ac.za/cpmdb

Cysteine proteinases

Cysteine proteinases -- Inhibitors

Papain

Cystatins

Malaria -- Chemotherapy

Homology (Biology)

Protein-protein interactions