Discovery and characterization of small molecule inhibitors of the aldehyde dehydrogenase 1/2 family

Buchman, Cameron D.

01 September 2016

Indiana University-Purdue University Indianapolis (IUPUI) / The human aldehyde dehydrogenase (ALDH) superfamily consists of 19 isoenzymes that are critical for normal physiology as well as the removal of toxic aldehydes. Members of the ALDH1/2 family have vital roles in cell signaling during early development, ethanol metabolism, and the removal of aldehydes derived from oxidative stress. We sought to develop selective compounds toward ALDH2 to help determine its individual contribution to biological function, as many of the ALDH1/2 family possess overlapping substrate preferences. A high-throughput screen of over 100,000 compounds uncovered a class of aromatic lactones which inhibit the ALDH1/2 enzyme family. The lactones were then characterized using a combination of enzyme kinetics, X-ray crystallography, and cell culture experiments. We found that many of the lactones are over ten times more potent toward ALDH2 than daidzin, a previously described ALDH2 inhibitor. Our ability to produce many more ALDH isoenzymes allowed us to determine that daidzin is not as selective as previously believed, inhibiting ALDH2, ALDH1B1, and ALDH1A2 with equal potency. This inhibition pattern was seen with several of the aromatic lactones as well. Structural studies show that many of the lactones bind between key aromatic residues in the ALDH1/2 enzyme substrate-binding sites. One lactone in particular mimics the position of an aldehyde substrate and alters the position of the catalytic cysteine to interfere with the productive binding of NAD+ for enzyme catalysis. Further characterization of related compounds led to the realization that the mechanism of inhibition, potency, and selectivity differs amongst the lactones based off the substituents on the aromatic scaffold and its precise binding location. Two of these compounds were found to be selective for one of the ALDH1/2 family members, BUC22, selective for ALDH1A1, and BUC27, selective for ALDH2. BUC22 demonstrates ten-fold selectivity for ALDH1A1 over ALDH1A2 and does not inhibit the remaining ALDH1/2 enzymes. Additionally, treatment with BUC22 led to decreased growth of triple-negative breast cancer cells in culture. BUC27 inhibits ALDH2 with the same potency as daidzin. Both BUC22 and BUC27 could be further developed to use as chemical tools to better understand the functional roles of ALDH1A1 and ALDH2 in biological systems.

Aldehyde dehydrogenase

Enzyme kinetics

Small molecule inhibitors

X-ray crystallography

Structural and Functional Studies on Glycosaminoglycan-degrading Enzymes from Bacteria / 細菌由来グリコサミノグリカン分解酵素系の構造と機能に関する研究

Nakamichi, Yusuke

23 May 2014

京都大学 / 0048 / 新制・課程博士 / 博士(農学) / 甲第18475号 / 農博第2075号 / 新制||農||1025(附属図書館) / 学位論文||H26||N4859(農学部図書室) / 31353 / 京都大学大学院農学研究科食品生物科学専攻 / (主査)教授 河田 照雄, 教授 保川 清, 准教授 橋本 渉 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DFAM

glycosaminoglycan

Streptococcus

hydrolase

lyase

X-ray crystallography

610

Structural and mechanistic analyses of a nicotine- degrading enzyme from Pseudomonas putida: towards design of tools and biotherapeutics

Tararina, Margarita Alexandrovna

30 January 2020

Tobacco-soil bacteria have evolved not only to tolerate high concentrations of nicotine, but to degrade it as a primary growth source. The genomes of several of these species have been sequenced, allowing for the identification of unique bacterial degradation pathways. In the Gram-negative bacteria, Pseudomonas putida, the nicotine-degrading gene cluster has been described; the encoded enzymes catabolize nicotine via the pyrrolidine pathway, ultimately forming malate and fumarate. In previous studies, the flavoenzyme, nicotine oxidoreductase (NicA2), has been identified as the first committed step of nicotine catabolism in this organism. Preliminary kinetic analysis reported that NicA2 has high specificity for S-nicotine, but a slow catalytic rate. Taking advantage of its unique evolutionary adaptation, we aim to refine the inherent catalytic function and structural features of NicA2 towards the development of a biotherapeutic for nicotine addiction, nicotine poisoning and tools for nicotine biosensor development. Our goal is to identify the factors contributing to the mechanistic and substrate-binding properties of NicA2 to improve its biotherapeutic potential. This work presents the first crystal structure of NicA2, resolved to 2.2 Å resolution, establishing it as a member of the flavin-dependent amine oxidase family with a conserved amine oxidase fold. Structural analysis identified a unique composition of the canonical aromatic cage (W427 and N462), which flanks the flavin isoalloxazine ring. Additionally, the X-ray crystallographic structure of the NicA2/S-nicotine complex was refined to 2.6 Å resolution, revealing a hydrophobic active site in support of a hydride-transfer mechanism. Analysis of enzyme activity with a series of substrate analogs and kinetic analysis of active-site residues reveal the determinants of substrate binding affording the remarkable specificity of this enzyme. Using site-directed mutagenesis of aromatic cage residues, along with analysis of the kinetics of the reductive and oxidative steps, we demonstrate that the rate-limiting reaction step is in the oxidative half-reaction. Structural analysis of an active-site variant revealed a secondary binding site consistent with kinetic analysis demonstrating substrate inhibition. Together, our findings provide kinetic and structural evidence for the catalytic mechanism of NicA2, expanding the possibilities for the generation of catalytically-efficient variants and supporting its role as a promising therapeutic strategy. / 2021-01-30T00:00:00Z

Biochemistry

Enzymology

Flavoenzyme

Nicotine

Pseudomonas putida

X-ray crystallography

A Computational Approach to Rational Engineering of Protein Crystallization

Banayan, Nooriel Elan

January 2023

X-ray crystallography is a popular method for resolving protein structures. Protein crystals need to be used for X-ray crystallography, but most naturally occurring proteins do not readily crystallize. The Hunt lab performed computational analyses showing that arginine is the most overrepresented amino acid in crystal-packing interfaces in the Protein Data Bank. Given the similar physicochemical characteristics of arginine and lysine, we hypothesized that multiple lysine-to-arginine (KR) substitutions should improve crystallization. To test this hypothesis, we developed software that ranks lysine sites in a target protein based on the redundancy-corrected KR substitution frequency in homologs. We demonstrate that three unrelated single-domain proteins can tolerate 5-11 KR substitutions with at most minor destabilization and that these substitutions consistently enhance crystallization propensity. This approach rapidly produced a 1.9 Å crystal structure of a human protein domain refractory to crystallization with its native sequence. Structures from bulk-KR-substituted domains show the engineered arginine residues frequently make high-quality hydrogen-bonds across crystal-packing interfaces. We thus demonstrate that bulk KR substitution represents a rational and efficient method for probabilistic engineering of protein surface properties to improve protein crystallization. This stands in direct contrast to earlier work and dogmas that posited that surface entropy reduction was the clear path forward to crystallzing proteins. Arginine is a high-entropy sidechain, yet it helps drive protein crystallization. To understand which structure and dynamical features of arginine give rise to crystal packing propensity, we performed 60 Molecular Dynamics (MD) simulations to measure the sidechain order parameter of arginine and compare it against crystal packing propensity. This work found that surface-exposed arginines with low order parameters are most likely to participate in crystal packing interactions. This is evidence against earlier thinking that high entropy surface sidechains oppose crystallization. Entropic barriers to protein crystallization can be enthalpically overcome.

Biophysics

X-ray crystallography

Crystalloids (Botany)

Crystallization

Arginine

Lysine

Structural and functional consequences of disease-related protein variants

Lee, Seung-Joo

30 July 2010

No description available.

Biochemistry

Prion protein

polymorphism

electron transfer protein

X-ray crystallography

Thermodynamic and structural insights into CSL mediated transcription complexes

Friedmann, David R.

09 April 2010

No description available.

Molecular Biology

Notch signaling

x-ray crystallography

thermodynamics

transcription

Resolving the molecular mechanisms of inherited deafness caused by missense mutations in cadherin 23.

Thornburg, Adrienne

28 September 2016

No description available.

Biophysics

Biochemistry

cadherin

X-ray crystallography

Differential scanning dluorimetry

Insights into the roles of metals in biology: biochemical and structural characterization of two bacterial and one archaeak metallo-enzyme

Jain, Rinku

13 September 2006

No description available.

Biophysics, General

x-ray crystallography

Peptide deformylase

MtmB

MtmC

Oligopeptidase A

Structural and mechanistic studies on eukaryotic UDP-galactopyranose mutases

Oppenheimer, Michelle Lynn

26 April 2012

Galactofuranose (Galf) is the five membered ring form of galactose. It is found on the cell wall and surface of many pathogens including Mycobacterium tuberculosis, Aspergillus fumigatus, Leishmania major, and Trypanosoma cruzi. Galf has been implicated in pathogenesis in these organisms; thus the biosynthetic pathway of Galf is a target for drug design. Galf is synthesized by the enzyme UDP-galactopyranose mutase (UGM), which converts UDP-galactopyranose (UDP-Galp) to UDP-galactofuranose (UDP-Galf). Solving the mechanism and structure of UGMs will aid in the development of specific inhibitors against these enzymes. Herein we present the detailed functional analysis of UGMs from A. fumigatus, T. cruzi, and L. major. The mechamism and structure these eukaryotic UGMs were examined by steady-state kinetics, rapid-reaction kinetics, trapping of reaction intermediates, fluorescence anisotropy, and X-ray crystallography. The mechanism first involves reduction of the required flavin by NADPH, followed by UDP-Galp binding and subsequent SN2 attack by the flavin on galactose displacing UDP to form a flavin N5-C1 galactose adduct. Next, the galactose ring opens forming an iminium ion allowing isomerization to occur. Lastly, the product is released and UGM is available to bind another substrate or be reoxidized by molecular oxygen. The three-dimensional structure of A. fumigatus UGM was solved using X-ray crystallography in four conformations: oxidized in complex with sulfate ions, reduced, reduced in complex with UDP, and reduced in complex with UDP-Galp, giving valuable information on the unique features of eukaryotic UGMs including features important for oligomerization and for substrate binding. The novel mechanism and structure provide valuable information for the development of specific inhibitors of eukaryotic UGMs. / Ph. D.

enzyme mechanism

X-ray Crystallography

flavoprotein

galactofuranose

UDP-galactopyranose mutase

State-Dependent Network Connectivity Determines Gating in a K+ Channel

Bollepalli, M.K., Fowler, P.W., Rapedius, M., Shang, Lijun, Sansom, M.S.P., Tucker, S.J., Baukrowitz, T.

26 June 2014

Yes / X-ray crystallography has provided tremendous insight into the different structural states of membrane proteins and, in particular, of ion channels. However, the molecular forces that determine the thermodynamic stability of a particular state are poorly understood. Here we analyze the different X-ray structures of an inwardly rectifying potassium channel (Kir1.1) in relation to functional data we obtained for over 190 mutants in Kir1.1. This mutagenic perturbation analysis uncovered an extensive, state-dependent network of physically interacting residues that stabilizes the pre-open and open states of the channel, but fragments upon channel closure. We demonstrate that this gating network is an important structural determinant of the thermodynamic stability of these different gating states and determines the impact of individual mutations on channel function. These results have important implications for our understanding of not only K+ channel gating but also the more general nature of conformational transitions that occur in other allosteric proteins. / Wellcome Trust

X-ray crystallography

Ion channels

Gating network

K+ channel