Characterization of a Novel Thermostable 7α-Hydroxysteroid Dehydrogenase.

BACKGROUND: 7α-Hydroxysteroid dehydrogenase (7α-HSDH) plays a pivotal role in vivo in the biotransformation of secondary bile acids and has great potential in industrial biosynthesis due to its broad substrate specificity. In this study, we expressed and characterized a novel thermostable 7α-HSDH (named Sa 7α-HSDH). METHODS: The DNA sequence was derived from the black bear gut microbiome metagenomic sequencing data, and the coding sequence of Sa 7α-HSDH was chemically synthesized. The heterologous expression of the enzyme was carried out using the pGEX-6p-1 vector. Subsequently, the activity of the purified enzyme was studied by measuring the absorbance change at 340 nm. Finally, the three-dimensional structure was predicted with AlphaFold2. RESULTS: Coenzyme screening results confirmed it to be NAD(H) dependent. Substrate specificity test revealed that Sa 7α-HSDH could catalyze taurochenodeoxycholic acid (TCDCA) with catalytic efficiency (kcat/Km) 3.81 S-1 mM-1. The optimum temperature of Sa 7α-HSDH was measured to be 75°C, confirming that it belongs to thermophilic enzymes. Additionally, its thermostability was assessed using an accelerated stability test over 32 hours. The catalytic activity of Sa 7α-HSDH remained largely unchanged for the first 24 hours and retained over 90% of its functionality after 32 hours at 50°C. Sa 7α-HSDH exhibited maximal activity at pH 10. The effect of metal ions-K+, Na+, Mg2+ and Cu2+-on the enzymatic activity of Sa 7α-HSDH was investigated. Only Mg2+ was observed to enhance the enzyme's activity by 27% at a concentration of 300 mM. Neither K+ nor Na+ had a significant influence on activity. Only Cu2+ was found to reduce enzyme activity. CONCLUSION: We characterized the thermostable 7α-HSDH, which provides a promising biocatalyst for bioconversion of steroids at high reaction temperatures.

Structure-based rational design of hydroxysteroid dehydrogenases for improving and diversifying steroid synthesis.

A group of steroidogenic enzymes, hydroxysteroid dehydrogenases are involved in steroid metabolism which is very important in the cell: signaling, growth, reproduction, and energy homeostasis. The enzymes show an inherent function in the interconversion of ketosteroids and hydroxysteroids in a position- and stereospecific manner on the steroid nucleus and side-chains. However, the biocatalysis of steroids reaction is a vital and demanding, yet challenging, task to produce the desired enantiopure products with non-natural substrates or non-natural cofactors, and/or in non-physiological conditions. This has driven the use of protein design strategies to improve their inherent biosynthetic efficiency or activate their silent catalytic ability. In this review, the innate features and catalytic characteristics of enzymes based on sequence-structure-function relationships of steroidogenic enzymes are reviewed. Combining structure information and catalytic mechanisms, progress in protein redesign to stimulate potential function, for example, substrate specificity, cofactor dependence, and catalytic stability are discussed.

Sequence and structure-guided discovery of a novel NADH-dependent 7ß-hydroxysteroid dehydrogenase for efficient biosynthesis of ursodeoxycholic acid.

7ß-Hydroxysteroid dehydrogenases (7ß-HSDHs) have attracted increasing attention due to their crucial roles in the biosynthesis of ursodeoxycholic acid (UDCA). However, most published 7ß-HSDHs are strictly NADPH-dependent oxidoreductases with poor activity and low productivity. Compared with NADPH, NADH is more stable and cheaper, making it the more popular cofactor for industrial applications of dehydrogenases. Herein, by using a sequence and structure-guided genome mining approach based on the structural information of conserved cofactor-binding motifs, we uncovered a novel NADH-dependent 7ß-HSDH (Cle7ß-HSDH). The Cle7ß-HSDH was overexpressed, purified, and characterized. It exhibited high specific activity (9.6 U/mg), good pH stability and thermostability, significant methanol tolerance, and showed excellent catalytic efficiencies (kcat/Km) towards 7-oxo-lithocholic acid (7-oxo-LCA) and NADH (70.8 mM-1s-1 and 31.8 mM-1s-1, respectively). Molecular docking and mutational analyses revealed that Asp42 could play a considerable role in NADH binding and recognition. Coupling with a glucose dehydrogenase for NADH regeneration, up to 20 mM 7-oxo-LCA could be completely transformed to UDCA within 90 min by Cle7ß-HSDH. This study provides an efficient approach for mining promising enzymes from genomic databases for cost-effective biotechnological applications.

Expression and Functional Characterization of a Novel NAD(H)- dependent 3α-HSDH.

BACKGROUND: 3α-Hydroxysteroid dehydrogenase (3α-HSDH) reversibly catalyzes the oxidation of the C3-hydroxyl group of steroids, and has been used in clinical applications to detect serum total bile acid (TBA). In this study, A novel 3α-HSDH (called Sb 3α-HSDH) was expressed and characterized. METHODS: Plasmid pGEX-6p-1 was used for the expression of Sb 3α-HSDH in Escherichia coli (BL21), and activities were determined by recording the change in absorbance at 340 nm with/without adding of ions. A prediction of its three-dimensional structure was performed with AlphaFold. RESULTS: The substrate specificity test indicated that Sb 3α-HSDH is NAD(H)-dependent and has no activity with NADP(H). We also showed that Sb 3α-HSDH can catalyze the oxidation reaction of GCDCA and GUDCA with catalytic efficiencies (kcat/Km) of 29.060 and 45.839 s-1mM-1, respectively. The temperature dependence of catalysis suggests that Sb 3α-HSDH is a member of the mesophilic enzymes with its best activity at about 45 °C. The optimum pH of Sb 3α-HSDH was found to be between pH 8.0 and 9.0. The effect of ions, including K+, Mg2+, Na+, Cu2+, Mn2+, Fe2+, and Fe3+ on enzyme activity was evaluated and K+ and Mg2+ were found to enhance the activity of Sb 3α-HSDH by about 20% at concentrations of 200 mM and 50 mM, respectively. The well-conserved GIG motif, the active sites, and the Rossmann fold in the threedimensional structure indicate that Sb 3α-HSDH belongs to the "classical" type of SDR superfamily. CONCLUSION: We expressed and characterized a novel NAD(H)-dependent 3α-HSDH with typical threedimensional characteristics of the SDRs that exhibited substrate specificity to GCDCA and GUDCA.

Reconstruction of Acinetobacter johnsonii ICE_NC genome using hybrid de novo genome assemblies and identification of the 12α-hydroxysteroid dehydrogenase gene.

AIMS: The role of a Acinetobacter johnsonii strain, isolated from a soil sample, in the biotransformation of bile acids (BAs) was already described but the enzymes responsible for these transformations were only partially purified and molecularly characterized. METHODS AND RESULTS: This study describes the use of hybrid de novo assemblies, that combine long-read Oxford Nanopore and short-read Illumina sequencing strategies, to reconstruct the entire genome of A. johnsonii ICE_NC strain and to identify the coding region for a 12α-hydroxysteroid dehydrogenase (12α-HSDH), involved in BAs metabolism. The de novo assembly of the A. johnsonii ICE_NC genome was generated using Canu and Unicycler, both strategies yielded a circular chromosome of about 3.6 Mb and one 117 kb long plasmid. Gene annotation was performed on the final assemblies and the gene for 12α-HSDH was detected on the plasmid. CONCLUSIONS: Our findings illustrate the added value of long read sequencing in addressing the challenges of whole genome characterization and plasmid reconstruction in bacteria. These approaches also allowed the identification of the A. johnsonii ICE_NC gene for the 12α-HSDH enzyme, whose activity was confirmed at the biochemical level. SIGNIFICANCE AND IMPACT OR THE STUDY: At present, this is the first report on the characterization of a 12α-HSDH gene in an A. johnsonii strain able to biotransform cholic acid into ursodeoxycholic acid, a promising therapeutic agent for several diseases.

An Overview of 7α- and 7ß-Hydroxysteroid Dehydrogenases: Structure, Specificity and Practical Application.

7α-Hydroxysteroid dehydrogenase and 7ß-hydroxysteroid dehydrogenase are key enzymes involved in bile acid metabolism. They catalyze the epimerization of a hydroxyl group through 7-keto bile acid intermediates. Basic research of the two enzymes has focused on exploring new enzymes and the structure-function relationship. The application research focused on the in vitro biosynthesis of bile acid drugs and the exploration and improvement of their catalytic ability based on molecular engineering. This article summarized the primary and advanced structural characteristics, specificities, biochemical properties, and applications of the two enzymes. The emphasis is also given to obtaining novel 7α-hydroxysteroid dehydrogenase and 7ß-hydroxysteroid dehydrogenase that are thermally stable and active in the presence of organic solvents, high substrate concentration, and extreme pH values. To achieve these goals, enzyme redesigning based on protein engineering and genomics may be the most useful approaches.

Crystal structure of an apo 7α-hydroxysteroid dehydrogenase reveals key structural changes induced by substrate and co-factor binding.

7α-Hydroxysteroid dehydrogenase (7α-HSDH) catalyzes the dehydrogenation of a hydroxyl group at the 7α position in steroid substrates using NAD+ or NADP+ as a co-factor. Although studies have determined the binary and ternary complex structures, detailed structural changes induced by ligand and co-factor binding remain unclear, because ligand-free structures are not yet available. Here, we present the crystal structure of apo 7α-HSDH from Escherichia coli (Eco-7α-HSDH) at 2.7 Å resolution. We found that the apo form undergoes substantial conformational changes in the ß4-α4 loop, α7-α8 helices, and C-terminus loop among the four subunits comprising the tetramer. Furthermore, a comparison of the apo structure with the binary (NAD+)-complex and ternary (NADH and 7-oxoglycochenodeoxycholic acid)-complex Eco-7α-HSDH structures revealed that only the ternary-complex structure has a fully closed conformation, whereas the binary-complex and apo structures have a semi-closed or open conformation. This open-to-closed transition forces several catalytically important residues (S146, Y159, and K163) into correct positions for catalysis. To confirm the catalytic activity, we used alcohol dehydrogenase for NAD+ regeneration to allow efficient conversion of chenodeoxycholic acid to 7-ketolithocholic acid by Eco-7α-HSDH. These findings demonstrate that apo Eco-7α-HSDH exhibits intrinsically flexible characteristics with an open conformation. This structural information provides novel insight into the 7α-HSDH reaction mechanism.

Modifying the Microenvironment of Epoxy Resin to Improve the Activity of Immobilized 7α-Hydroxysteroid Dehydrogenases.

7α-Hydroxysteroid dehydrogenase (7α-HSDH) is one of the key enzymes in the catalytic reaction of taurochenodeoxycholic acid (TCDCA). To improve the activity of immobilized 7α-HSDH, the microenvironment of immobilized 7α-HSDH was modified with epoxy resin and ethanediamine (EDA). The amino-epoxy support was characterized by Fourier transform infrared (FTIR), Spectrometer elemental analysis (EA), scanning electron microscopy (SEM), contact angle (CA), and Zetasizer. The effects of the immobilization of 7α-HSDH on the amino-epoxy resin and epoxy resin were studied. The results indicated that the relative activity of immobilized 7α-HSDH on the amino-epoxy resin increased by approximately 80%. Meanwhile, the immobilized 7α-HSDH showed favorable thermal stability and operational stability. The thermal stability of immobilized 7α-HSDH increased at temperatures ranging from 15 to 35 °C, while the relative activities of 7α-HSDH immobilized on the amino-epoxy resin and epoxy resin retained 56.4% and 61.0%. After 6 cycles, the residual activities of the 7α-HSDH immobilized on the amino-epoxy resin and epoxy resin were 81.4% and 89.5%, respectively.

Structural and biochemical characterization of 20ß-hydroxysteroid dehydrogenase from Bifidobacterium adolescentis strain L2-32.

Anaerobic bacteria inhabiting the human gastrointestinal tract have evolved various enzymes that modify host-derived steroids. The bacterial steroid-17,20-desmolase pathway cleaves the cortisol side chain, forming pro-androgens predicted to impact host physiology. Bacterial 20ß-hydroxysteroid dehydrogenase (20ß-HSDH) regulates cortisol side-chain cleavage by reducing the C-20 carboxyl group on cortisol, yielding 20ß-dihydrocortisol. Recently, the gene encoding 20ß-HSDH in Butyricicoccus desmolans ATCC 43058 was reported, and a nonredundant protein search yielded a candidate 20ß-HSDH gene in Bifidobacterium adolescentis strain L2-32. B. adolescentis 20ß-HSDH could regulate cortisol side-chain cleavage by limiting pro-androgen formation in bacteria such as Clostridium scindens and 21-dehydroxylation by Eggerthella lenta Here, the putative B. adolescentis 20ß-HSDH was cloned, overexpressed, and purified. 20ß-HSDH activity was confirmed through whole-cell and pure enzymatic assays, and it is specific for cortisol. Next, we solved the structures of recombinant 20ß-HSDH in both the apo- and holo-forms at 2.0-2.2 Å resolutions, revealing close overlap except for rearrangements near the active site. Interestingly, the structures contain a large, flexible N-terminal region that was investigated by gel-filtration chromatography and CD spectroscopy. This extended N terminus is important for protein stability because deletions of varying lengths caused structural changes and reduced enzymatic activity. A nonconserved extended N terminus was also observed in several short-chain dehydrogenase/reductase family members. B. adolescentis strains capable of 20ß-HSDH activity could alter glucocorticoid metabolism in the gut and thereby serve as potential probiotics for the management of androgen-dependent diseases.

Structural and functional characterization of a novel acidophilic 7α-hydroxysteroid dehydrogenase.

7α-Hydroxysteroid dehydrogenase (7α-HSDH) is an NAD(P)H-dependent oxidoreductase belonging to the short-chain dehydrogenases/reductases. In vitro, 7α-HSDH is involved in the efficient biotransformation of taurochenodeoxycholic acid (TCDCA) to tauroursodeoxycholic acid (TUDCA). In this study, a gene encoding novel 7α-HSDH (named as St-2-1) from fecal samples of black bear was cloned and heterologously expressed in Escherichia coli. The protein has subunits of 28.3 kDa and a native size of 56.6 kDa, which suggested a homodimer. We studied the relevant properties of the enzyme, including the optimum pH, optimum temperature, thermal stability, activators, and inhibitors. Interestingly, the data showed that St-2-1 differs from the 7α-HSDHs reported in the literature, as it functions under acidic conditions. The enzyme displayed its optimal activity at pH 5.5 (TCDCA). The acidophilic nature of 7α-HSDH expands its application environment and the natural enzyme bank of HSDHs, providing a promising candidate enzyme for the biosynthesis of TUDCA or other related chemical entities.

Ligand entry in human ileal bile acid-binding protein is mediated by histidine protonation.

Human ileal bile acid-binding protein (hI-BABP) has a key role in the intracellular transport of bile salts. To explore the role of histidine protonation in the binding process, the pH-dependence of bile salt binding and internal dynamics in hI-BABP was investigated using NMR spectroscopy and biophysical tools. Thermodynamic and kinetic measurements show an increase in the overall binding affinity and the association rate constant of the first binding step below the pKa of the histidines, suggesting that ligand binding is favoured by the protonated state. The overlap between residues exhibiting a high sensitivity to pH in their backbone amide chemical shifts and protein regions undergoing a global ms conformational exchange indicate a connection between the two processes. According to 15N NMR relaxation dispersion analysis, the slow motion is most pronounced at and above the pKa of the histidines. In agreement with the NMR measurements, MD simulations show a stabilization of the protein by histidine protonation. Hydrogen-bonding and van der Waals interactions mediating the flow of information between the C/D- and G/H-turn regions hosting the three histidines, suggest a complex way of pH-governed allosteric regulation of ligand entry involving a transition between a closed and a more open protein state.

Developing an Enzyme-Assisted Derivatization Method for Analysis of C27 Bile Alcohols and Acids by Electrospray Ionization-Mass Spectrometry.

Enzyme-assisted derivatization for sterol analysis (EADSA) is a technology designed to enhance sensitivity and specificity for sterol analysis using electrospray ionization⁻mass spectrometry. To date it has only been exploited on sterols with a 3ß-hydroxy-5-ene or 3ß-hydroxy-5α-hydrogen structure, using bacterial cholesterol oxidase enzyme to convert the 3ß-hydroxy group to a 3-oxo group for subsequent derivatization with the positively charged Girard hydrazine reagents, or on substrates with a native oxo group. Here we describe an extension of the technology by substituting 3α-hydroxysteroid dehydrogenase (3α-HSD) for cholesterol oxidase, making the method applicable to sterols with a 3α-hydroxy-5ß-hydrogen structure. The 3α-HSD enzyme works efficiently on bile alcohols and bile acids with this stereochemistry. However, as found by others, derivatization of the resultant 3-oxo group with a hydrazine reagent does not go to completion in the absence of a conjugating double bond in the sterol structure. Nevertheless, Girard P derivatives of bile alcohols and C27 acids give an intense molecular ion ([M]⁺) upon electrospray ionization and informative fragmentation spectra. The method shows promise for analysis of bile alcohols and 3α-hydroxy-5ß-C27-acids, enhancing the range of sterols that can be analyzed at high sensitivity in sterolomic studies.

Structural and Functional Biology of Aldo-Keto Reductase Steroid-Transforming Enzymes.

Aldo-keto reductases (AKRs) are monomeric NAD(P)(H)-dependent oxidoreductases that play pivotal roles in the biosynthesis and metabolism of steroids in humans. AKR1C enzymes acting as 3-ketosteroid, 17-ketosteroid, and 20-ketosteroid reductases are involved in the prereceptor regulation of ligands for the androgen, estrogen, and progesterone receptors and are considered drug targets to treat steroid hormone-dependent malignancies and endocrine disorders. In contrast, AKR1D1 is the only known steroid 5ß-reductase and is essential for bile-acid biosynthesis, the generation of ligands for the farnesoid X receptor, and the 5ß-dihydrosteroids that have their own biological activity. In this review we discuss the crystal structures of these AKRs, their kinetic and catalytic mechanisms, AKR genomics (gene expression, splice variants, polymorphic variants, and inherited genetic deficiencies), distribution in steroid target tissues, roles in steroid hormone action and disease, and inhibitor design.

Bile acid oxidation by Eggerthella lenta strains C592 and DSM 2243T.

Strains of Eggerthella lenta are capable of oxidation-reduction reactions capable of oxidizing and epimerizing bile acid hydroxyl groups. Several genes encoding these enzymes, known as hydroxysteroid dehydrogenases (HSDH) have yet to be identified. It is also uncertain whether the products of E. lenta bile acid metabolism are further metabolized by other members of the gut microbiota. We characterized a novel human fecal isolate identified as E. lenta strain C592. The complete genome of E. lenta strain C592 was sequenced and comparative genomics with the type strain (DSM 2243) revealed high conservation, but some notable differences. E. lenta strain C592 falls into group III, possessing 3α, 3ß, 7α, and 12α-hydroxysteroid dehydrogenase (HSDH) activity, as determined by mass spectrometry of thin layer chromatography (TLC) separated metabolites of primary and secondary bile acids. Incubation of E. lenta oxo-bile acid and iso-bile acid metabolites with whole-cells of the high-activity bile acid 7α-dehydroxylating bacterium, Clostridium scindens VPI 12708, resulted in minimal conversion of oxo-derivatives to lithocholic acid (LCA). Further, Iso-chenodeoxycholic acid (iso-CDCA; 3ß,7α-dihydroxy-5ß-cholan-24-oic acid) was not metabolized by C. scindens. We then located a gene encoding a novel 12α-HSDH in E. lenta DSM 2243, also encoded by strain C592, and the recombinant purified enzyme was characterized and substrate-specificity determined. Genomic analysis revealed genes encoding an Rnf complex (rnfABCDEG), an energy conserving hydrogenase (echABCDEF) complex, as well as what appears to be a complete Wood-Ljungdahl pathway. Our prediction that by changing the gas atmosphere from nitrogen to hydrogen, bile acid oxidation would be inhibited, was confirmed. These results suggest that E. lenta is an important bile acid metabolizing gut microbe and that the gas atmosphere may be an important and overlooked regulator of bile acid metabolism in the gut.

Metabolism of Oxo-Bile Acids and Characterization of Recombinant 12α-Hydroxysteroid Dehydrogenases from Bile Acid 7α-Dehydroxylating Human Gut Bacteria.

Bile acids are important cholesterol-derived nutrient signaling hormones, synthesized in the liver, that act as detergents to solubilize dietary lipids. Bile acid 7α-dehydroxylating gut bacteria generate the toxic bile acids deoxycholic acid and lithocholic acid from host bile acids. The ability of these bacteria to remove the 7-hydroxyl group is partially dependent on 7α-hydroxysteroid dehydrogenase (HSDH) activity, which reduces 7-oxo-bile acids generated by other gut bacteria. 3α-HSDH has an important enzymatic activity in the bile acid 7α-dehydroxylation pathway. 12α-HSDH activity has been reported for the low-activity bile acid 7α-dehydroxylating bacterium Clostridium leptum; however, this activity has not been reported for high-activity bile acid 7α-dehydroxylating bacteria, such as Clostridium scindens, Clostridium hylemonae, and Clostridium hiranonis Here, we demonstrate that these strains express bile acid 12α-HSDH. The recombinant enzymes were characterized from each species and shown to preferentially reduce 12-oxolithocholic acid to deoxycholic acid, with low activity against 12-oxochenodeoxycholic acid and reduced activity when bile acids were conjugated to taurine or glycine. Phylogenetic analysis suggests that 12α-HSDH is widespread among Firmicutes, Actinobacteria in the Coriobacteriaceae family, and human gut ArchaeaIMPORTANCE 12α-HSDH activity has been established in the medically important bile acid 7α-dehydroxylating bacteria C. scindens, C. hiranonis, and C. hylemonae Experiments with recombinant 12α-HSDHs from these strains are consistent with culture-based experiments that show a robust preference for 12-oxolithocholic acid over 12-oxochenodeoxycholic acid. Phylogenetic analysis identified novel members of the gut microbiome encoding 12α-HSDH. Future reengineering of 12α-HSDH enzymes to preferentially oxidize cholic acid may provide a means to industrially produce the therapeutic bile acid ursodeoxycholic acid. In addition, a cholic acid-specific 12α-HSDH expressed in the gut may be useful for the reduction in deoxycholic acid concentration, a bile acid implicated in cancers of the gastrointestinal (GI) tract.

Molecular interactions of bisphenols and analogs with glucocorticoid biosynthetic pathway enzymes: an in silico approach.

Glucocorticoids are known to have vital effects on metabolism, behavior and immunity. Any sort of impairment in their synthesis may lead to the generation of numerous ill health effects. Different environmental toxicants, including bisphenols and their analogs pose deleterious effect on the biosynthesis of glucocorticoids, thereby leading to endocrine disruption. In order to assess the effect of these environmental toxicants on gluocorticoid biosynthetic pathway, an in silico study was performed. This involved molecular docking studies of 18 ligands with the selected participating enzymes of the pathway. These enzymes were CYP11A1, CYP11B2, CYP19A1, CYP17A1, 3α/20ß-HSD, 3ß/17ß-HSD and CYP21A2. Comparison of their binding affinity was made with the known inhibitors of these enzymes. In case of CYP11A1, Bisphenol M (BP M) had the lowest docking score (D score) of -8.699 kCal/mol, and was better than that of the standard, Metyrapone. Bisphenol PH (BP PH) was found to have significant affinity with CYP11B2. In case CYP19A1, results were found to be comparable with the standards, Exemestane and Letrozole. BP PH elicited better results than the standard Abiraterone acetate against CYP17A1. BP M had a D score of -7.759 against 3α/20ß-HSD, again better results than the standard, Trilostane. Upon molecular docking of BP PH against CYP21A2, it was seen that amongst all the analogs, it had maximum interactions along with the lowest D score. From all the above instances mentioned, it is quite evident that certain BPA analogs have more potential to modulate the enzymes involved in comparison to the known inhibitors.

Engineering Clostridium absonum 7α-hydroxysteroid Dehydrogenase for Enhancing Thermostability Based on Flexible Site and ΔΔG Prediction.

BACKGROUND: Enhancing thermostability of the 7α-Hydroxysteroid dehydrogenases (7α-HSDHs) is beneficial to its industrial application broadly. For protein engineering to enhance thermostability the nonrational strategy, directed evolution, has been applied in obtaining more stable proteins through error-prone PCR or DNA rearrangement generating random mutations. However, the successful application of directed evolution needs to build a large mutant library. Site-directed mutations of CA 7α-HSDH had been performed to probe the relationship between the compactness increasing and thermostability enhancing. Although most of the mutations in ß-sheet core predicted by MAESTRO became more stable than wild type, unfortunately, all the mutations suffered dramatic activity loss. OBJECTIVE: The main objective of this study was to verify effects of the mutations in helices selected from the predicting results through MAESTRO on thermostability improving of CA 7α-HSDH. METHODS: Seven mutants, S22L, P124L, A125L, N171L, A195Q, L197E and Y259E were synthesized and verified through DNA sequencing in Sangon Biotech (Sangon, Shanghai, China). The two mutants, A104P and G105P were prepared by over-lapping PCR. The GST-fusion expression vector, pGEX-6p-1 (GE Healthcare), was used for protein expression with restriction sites BamH I and Not I. Thermostability was measured by circular dichroism (CD) spectrometer (MOS-450, BioLogic Inc). All the enzymes were diluted in PBS (pH 7.3, 10 mM) to OD222 value between 0.8 and 1, and temperature varied from 20°C to 95°C. Activity of enzyme was assayed by measuring the production of NADPH by UV-visible spectrophotometer at 340 nm. The activity assay was performed in 2 mL reaction mixture which contained PBS (pH 7.3, 10 mM), NADP+ (0.5 mM) and taurocholic acid (TCA) at 25°C. RESULTS: Based on unfolding free energy changes (ΔΔG) prediction seven mutations of Clostridium absonum (CA) 7α-HSDH were selected and experimentally verified, and these mutants fitted three-state denaturation model well, among which S22L located in the αA possessed the greatest Tm N→I increase (> 8°C). Mutants P124L, L197E, N171L and Y259E also became more stable than wild type CA 7α-HSDH with different ranges. Meanwhile, thermostability of the two mutants, A104P and G105P (in the coil between ßD and αD) resulting from the proline substitution method decreased significantly. Enzyme activity assays indicated that mutant L197E located in αF maximally maintained 28.7% of catalytic efficiency, and activity of the five mutants, P124L, A125L, N171L, A104P and G105P cannot be detected. CONCLUSION: Although all the mutants' activities decreased, the mutant L197E with the maximum activity retain suggested that the loop structure (residues 194 to 211) may be the favored candidate sites to enhance thermostability. In addition, CA 7α-HSDH may suffer structural destruction resulting from the proline substitution in A104 and G105.

Functional contribution of coenzyme specificity-determining sites of 7α-hydroxysteroid dehydrogenase from Clostridium absonum.

Studies of the molecular determinants of coenzyme specificity help to reveal the structure-function relationship of enzymes, especially with regards to coenzyme specificity-determining sites (CSDSs) that usually mediate complex interactions. NADP(H)-dependent 7α-hydroxysteroid dehydrogenase from Clostridium absonum (CA 7α-HSDH), a member of the short-chain dehydrogenase/reductase superfamily (SDRs), possesses positively charged CSDSs that mainly contain T15, R16, R38, and R194, forming complicated polar interactions with the adenosine ribose C2 phosphate group of NADP(H). The R38 residue is crucial for coenzyme anchoring, but the influence of the other residues on coenzyme utilization is still not clear. Hence, we performed alanine scanning mutagenesis and molecular dynamic (MD) simulations. The results suggest that the natural CSDSs have the greatest NADP(H)-binding affinity, but not the best activity (kcat) toward NADP+. Compared with the wild type and other mutants, the mutant R194A showed the highest catalytic efficiency (kcat/Km), which was more than three-times that of the wild type. MD simulation and kinetics analysis suggested that the importance of the CSDSs of CA 7α-HSDH should be in accordance with the following order R38>T15>R16>R194, and S39 may have a supporting role in NADP(H) anchoring for mutants R16A/T194A and T15A/R16A/T194A.

Structure of NADP+-bound 7ß-hydroxysteroid dehydrogenase reveals two cofactor-binding modes.

In mammals, bile acids/salts and their glycine and taurine conjugates are effectively recycled through enterohepatic circulation. 7ß-Hydroxysteroid dehydrogenases (7ß-HSDHs; EC 1.1.1.201), including that from the intestinal microbe Collinsella aerofaciens, catalyse the NADPH-dependent reversible oxidation of secondary bile-acid products to avoid potential toxicity. Here, the first structure of NADP+ bound to dimeric 7ß-HSDH is presented. In one active site, NADP+ adopts a conventional binding mode similar to that displayed in related enzyme structures. However, in the other active site a unique binding mode is observed in which the orientation of the nicotinamide is different. Since 7ß-HSDH has become an attractive target owing to the wide and important pharmaceutical use of its product ursodeoxycholic acid, this work provides a more detailed template to support rational protein engineering to improve the enzymatic activities of this useful biocatalyst, further improving the yield of ursodeoxycholic acid and its other applications.

Discovery of tauroursodeoxycholic acid biotransformation enzymes from the gut microbiome of black bears using metagenomics.

Tauroursodeoxycholic acid (TUDCA) has been used to treat many diseases effectively. 7α-hydroxysteroid dehydrogenase (7α-HSDH) and 7ß-hydroxysteroid dehydrogenase (7ß-HSDH) are two key enzymes that drive the efficient biosynthesis of TUDCA from taurochenodeoxycholic acid (TCDCA) in vitro. In this study, a metagenomic approach was used to isolate 7α- and 7ß-HSDHs from fecal samples of black bears. Five new 7α-HSDHs and one new 7ß-HSDH enzyme were discovered and identified from the gut microbiota of black bears, and four of them presented good enzymatic properties. Our data also suggest cooperation in the biotransformation of TUDCA by the gut microbiota in black bears. In conclusion, this work expands the natural enzyme bank of HSDHs, provides promising candidate enzymes for application in the biosynthesis TUDCA and the epimerization reaction of bile acids at the C-7 position, and provides a data set for the discovery of novel enzymes in the gut micriobiome of black bears.