Unraveling Cholesterol Catabolism in Mycobacterium tuberculosis: ChsE4-ChsE5 α2β2 Acyl-CoA Dehydrogenase Initiates β-Oxidation of 3-Oxo-cholest-4-en-26-oyl CoA

Yang, Meng; Lu, Rui; Guja, K.E.; Wipperman, Matthew F.; Clair, Johnna R. St.; Bonds, Amber C.; García‐Díaz, Miguel; Sampson, Nicole S.

doi:10.1021/id500033m

Cited by 52 publications

(95 citation statements)

References 55 publications

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“…Consistent with the idea that lipids are important nutrients the early genome annotation efforts revealed that M. tuberculosis has an expanded repertoire of genes associated with lipid metabolism and β-oxidation, which exceeded 250 genes (57). Although several of the M. tuberculosis genes originally annotated as having a β-oxidation functions are now known to have anabolic activities (58, 59) or act in multimeric complexes to oxidize lipids (60, 61) the M. tuberculosis genome still encodes more genes involved in lipid metabolism and β-oxidation relative to other bacteria. Another critical pathway that is required when bacteria metabolize lipids is the anaplerotic glyoxylate cycle and a key enzyme in this pathway is isocitrate lyase (Icl).…”

Section: Lipid Utilization By M Tuberculosis In Macrophagesmentioning

confidence: 99%

The Minimal Unit of Infection:Mycobacterium tuberculosisin the Macrophage

et al. 2016

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The interaction between Mycobacterium tuberculosis and its host cell is highly complex and extremely intimate. Were it not for the disease, one might regard this interaction at the cellular level as an almost symbiotic one. The metabolic activity and physiology of both cells are shaped by this coexistence. We believe that where this appreciation has greatest significance is in the field of drug discovery. Evolution rewards efficiency, and recent data from many groups discussed in this review indicate that M. tuberculosis has evolved to utilize the environmental cues within its host to control large genetic programs or regulons. But these regulons may represent chinks in the bacterium’s armor because they include off-target effects, such as the constraint of the metabolic plasticity of M. tuberculosis . A prime example is how the presence of cholesterol within the host cell appears to limit the ability of M. tuberculosis to fully utilize or assimilate other carbon sources. And that is the reason for the title of this review. We believe firmly that, to understand the physiology of M. tuberculosis and to identify new drug targets, it is imperative that the bacterium be interrogated within the context of its host cell. The constraints induced by the environmental cues present within the host cell need to be preserved and exploited. The M. tuberculosis -infected macrophage truly is the “minimal unit of infection.”

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Section: Lipid Utilization By M Tuberculosis In Macrophagesmentioning

confidence: 99%

The Minimal Unit of Infection:Mycobacterium tuberculosisin the Macrophage

et al. 2016

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“…Microbial transformation could be carried out under mild reaction conditions with excellent yields of products and remarkable regio- and stereo-selectivity, which is hardly available for chemical synthesis. Therefore, for producing novel steroidal drugs and generating active pharmaceutical ingredients, microbial transformation is employed as a novel, efficient and economical tool (Donova 2007; García et al 2012; Yang et al 2015). For example, side chains of phytosterol, a byproduct from soybeans, sugar and paper industries, can be selectively degraded by a process similar to the β-oxidation of fatty acids, yielding 17-ketosteroids (Wei et al 2010).…”

Section: Introductionmentioning

confidence: 99%

“…The efficiency of enzymatic processes and purity of their products have obvious advantages in comparison with multi-steps chemical syntheses of hormonal drugs. However, the development of steroid biotechnology requires further studies of microorganisms able to degrade/modify steroids as well as enzymes catalyzing these reactions on the molecular level (Yang et al 2015). …”

Section: Introductionmentioning

confidence: 99%

Heterologous expression and characterization of a 3-ketosteroid-∆1-dehydrogenase from Gordonia neofelifaecis and its utilization in the bioconversion of androst-4,9(11)-dien-3,17-dione

Wang

et al. 2017

3 Biotech

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3-Ketosteroid-∆1-dehydrogenase (KstD), a key enzyme in microbial steroid catabolism, catalyzes the trans-axial elimination of the C1 and C2 hydrogen atoms of the A-ring from the polycyclic ring structure of 3-ketosteroids, and it was usually used to transform androst-4-ene-3,17-dione (AD) to produce androsta-1,4-diene-3,17-dione. Here, the KstD from Gordonia neofelifaecis was expressed efficiently in Escherichia coli. E. coli cells expressing KstD3gor were subjected to the investigation of dehydrogenation activity for different steroids. The results showed that KstD3gor has a clear preference for steroid substrates with 3-keto-4-ene configuration, and it exhibits higher activity towards steroid substrates carrying a small or no aliphatic side chain than towards substrates having a bulky side chain at the C-17 atom. The recombinant strain could efficiently convert androst-4,9(11)-dien-3,17-dione into androst-1,4,9(11)-trien-3,17-dione (with conversion rate of 96%). 1(2)-Dehydrogenation of androst-4,9(11)-dien-3,17-dione is one of the key steps in glucocorticoid production. To the best of our knowledge, this is the first study reporting on the conversion of androst-4,9(11)-dien-3,17-dione catalyzed by recombinant KstD; the expression system of KstD3gor reported here would have an impact in the industrial production of glucocorticoid in the future.

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“…FadD19 is an essential enzyme when Mtb is grown on cholesterol 16 and is the only fatty CoA ligase that has been identified to esterify the terminal cholesterol carboxylic acid. However, FadD19 is not stereoselective as it accepts both the 25 R and 25 S carboxylic acids 6 (Scheme 1). Thus, the metabolic pathway that Mtb utilizes to activate cholesterol to its CoA ester provides both the 25 R or 25 S diastereomers of 3-oxo-cholest-4-en-26-oyl CoA (3-OCS-CoA).…”

mentioning

confidence: 99%

“…5, 6, 8, 9 ChsE4-ChsE5 is the only ACAD protein regulated by KstR1 that can oxidize 3-OCS-CoA the first acyl-CoA metabolite in the side chain β-oxidation cycle. 6 …”

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confidence: 99%

α-Methyl Acyl CoA Racemase Provides Mycobacterium tuberculosis Catabolic Access to Cholesterol Esters

Schmitz

Sampson

2015

Biochemistry

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Metabolism of cholesterol by Mycobacterium tuberculosis (Mtb) contributes to its pathogenesis. We show that ChsE4-ChsE5 (Rv3504/Rv3505) specifically catalyzes dehydrogenation of the (25S)-3-oxo-cholest-4-en-26-oyl CoA diastereomer in cholesterol side chain β-oxidation. Thus a dichotomy between the supply of both 25R and 25S metabolic precursors by upstream cytochrome P450s and the substrate stereospecificity of ChsE4-ChsE5 exists. We reconcile the dilemma of 25R metabolite production by demonstration that mycobacterial MCR (Rv1143) can efficiently epimerize C25 diastereomers of 3-oxo-cholest-4-en-26-oyl-CoA. Our data suggest that cholesterol and cholesterol ester precursors can converge into a single catabolic pathway, thus widening the metabolic niche in which Mtb survives.

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Unraveling Cholesterol Catabolism in Mycobacterium tuberculosis: ChsE4-ChsE5 α₂β₂ Acyl-CoA Dehydrogenase Initiates β-Oxidation of 3-Oxo-cholest-4-en-26-oyl CoA

Cited by 52 publications

References 55 publications

The Minimal Unit of Infection:Mycobacterium tuberculosisin the Macrophage

The Minimal Unit of Infection:Mycobacterium tuberculosisin the Macrophage

Heterologous expression and characterization of a 3-ketosteroid-∆1-dehydrogenase from Gordonia neofelifaecis and its utilization in the bioconversion of androst-4,9(11)-dien-3,17-dione

α-Methyl Acyl CoA Racemase Provides Mycobacterium tuberculosis Catabolic Access to Cholesterol Esters

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