3 resultados para inhibitor design
em Duke University
Resumo:
Trehalose is a non-reducing disaccharide essential for pathogenic fungal survival and virulence. The biosynthesis of trehalose requires the trehalose-6-phosphate synthase, Tps1, and trehalose-6-phosphate phosphatase, Tps2. More importantly, the trehalose biosynthetic pathway is absent in mammals, conferring this pathway as an ideal target for antifungal drug design. However, lack of germane biochemical and structural information hinders antifungal drug design against these targets.
In this dissertation, macromolecular X-ray crystallography and biochemical assays were employed to understand the structures and functions of proteins involved in the trehalose biosynthetic pathway. I report here the first eukaryotic Tps1 structures from Candida albicans (C. albicans) and Aspergillus fumigatus (A. fumigatus) with substrates or substrate analogs. These structures reveal the key residues involved in substrate binding and catalysis. Subsequent enzymatic assays and cellular assays highlight the significance of these key Tps1 residues in enzyme function and fungal stress response. The Tps1 structure captured in its transition-state with a non-hydrolysable inhibitor demonstrates that Tps1 adopts an “internal return like” mechanism for catalysis. Furthermore, disruption of the trehalose biosynthetic complex formation through abolishing Tps1 dimerization reveals that complex formation has regulatory function in addition to trehalose production, providing additional targets for antifungal drug intervention.
I also present here the structure of the Tps2 N-terminal domain (Tps2NTD) from C. albicans, which may be involved in the proper formation of the trehalose biosynthetic complex. Deletion of the Tps2NTD results in a temperature sensitive phenotype. Further, I describe in this dissertation the structures of the Tps2 phosphatase domain (Tps2PD) from C. albicans, A. fumigatus and Cryptococcus neoformans (C. neoformans) in multiple conformational states. The structures of the C. albicans Tps2PD -BeF3-trehalose complex and C. neoformans Tps2PD(D24N)-T6P complex reveal extensive interactions between both glucose moieties of the trehalose involving all eight hydroxyl groups and multiple residues of both the cap and core domains of Tps2PD. These structures also reveal that steric hindrance is a key underlying factor for the exquisite substrate specificity of Tps2PD. In addition, the structures of Tps2PD in the open conformation provide direct visualization of the conformational changes of this domain that are effected by substrate binding and product release.
Last, I present the structure of the C. albicans trehalose synthase regulatory protein (Tps3) pseudo-phosphatase domain (Tps3PPD) structure. Tps3PPD adopts a haloacid dehydrogenase superfamily (HADSF) phosphatase fold with a core Rossmann-fold domain and a α/β fold cap domain. Despite lack of phosphatase activity, the cleft between the Tps3PPD core domain and cap domain presents a binding pocket for a yet uncharacterized ligand. Identification of this ligand could reveal the cellular function of Tps3 and any interconnection of the trehalose biosynthetic pathway with other cellular metabolic pathways.
Combined, these structures together with significant biochemical analyses advance our understanding of the proteins responsible for trehalose biosynthesis. These structures are ready to be exploited to rationally design or optimize inhibitors of the trehalose biosynthetic pathway enzymes. Hence, the work described in this thesis has laid the groundwork for the design of Tps1 and Tps2 specific inhibitors, which ultimately could lead to novel therapeutics to treat fungal infections.
Resumo:
In our continuing study of triterpene derivatives as potent anti-HIV agents, different C-3 conformationally restricted betulinic acid (BA, 1) derivatives were designed and synthesized in order to explore the conformational space of the C-3 pharmacophore. 3-O-Monomethylsuccinyl-betulinic acid (MSB) analogues were also designed to better understand the contribution of the C-3' dimethyl group of bevirimat (2), the first-in-class HIV maturation inhibitor, which is currently in phase IIb clinical trials. In addition, another triterpene skeleton, moronic acid (MA, 3), was also employed to study the influence of the backbone and the C-3 modification toward the anti-HIV activity of this compound class. This study enabled us to better understand the structure-activity relationships (SAR) of triterpene-derived anti-HIV agents and led to the design and synthesis of compound 12 (EC(50): 0.0006 microM), which displayed slightly better activity than 2 as a HIV-1 maturation inhibitor.
Resumo:
Histone deacetylases (HDACs) have been shown to play key roles in tumorigenesis, and
have been validated as effective enzyme target for cancer treatment. Largazole, a marine natural
product isolated from the cyanobacterium Symploca, is an extremely potent HDAC inhibitor that
has been shown to possess high differential cytotoxicity towards cancer cells along with excellent
HDAC class-selectivity. However, improvements can be made in the isoform-selectivity and
pharmacokinetic properties of largazole.
In attempts to make these improvements and furnish a more efficient biochemical probe
as well as a potential therapeutic, several largazole analogues have been designed, synthesized,
and tested for their biological activity. Three different types of analogues were prepared. First,
different chemical functionalities were introduced at the C2 position to probe the class Iselectivity profile of largazole. Additionally, docking studies led to the design of a potential
HDAC8-selective analogue. Secondly, the thiol moiety in largazole was replaced with a wide
variety of othe zinc-binding group in order to probe the effect of Zn2+ affinity on HDAC
inhibition. Lastly, three disulfide analogues of largazole were prepared in order to utilize a
different prodrug strategy to modulate the pharmacokinetic properties of largazole.
Through these analogues it was shown that C2 position can be modified significantly
without a major loss in activity while also eliciting minimal changes in isoform-selectivity. While
the Zn2+-binding group plays a major role in HDAC inhibition, it was also shown that the thiol
can be replaced by other functionalities while still retaining inhibitory activity. Lastly, the use of
a disulfide prodrug strategy was shown to affect pharmacokinetic properties resulting in varying
functional responses in vitro and in vivo.
v
Largazole is already an impressive HDAC inhibitor that shows incredible promise.
However, in order to further develop this natural product into an anti-cancer therapeutic as well as
a chemical probe, improvements in the areas of pharmacokinetics as well as isoform-selectivity
are required. Through these studies we plan on building upon existing structure–activity
relationships to further our understanding of largazole’s mechanism of inhibition so that we may
improve these properties and ultimately develop largazole into an efficient HDAC inhibitor that
may be used as an anti-cancer therapeutic as well as a chemical probe for the studying of
biochemical systems.
