Xinyi Tao

Unraveling and engineering the production of 23,24-bisnorcholenic steroids in sterol metabolism

The catabolism of sterols in mycobacteria is highly important due to its close relevance in the pathogenesis of pathogenic strains and the biotechnological applications of nonpathogenic strains for steroid synthesis. However, some key metabolic steps remain unknown. In this study, the hsd4A gene from Mycobacterium neoaurum ATCC 25795 was investigated. The encoded protein, Hsd4A, was characterized as a dual-function enzyme, with both 17β-hydroxysteroid dehydrogenase and β-hydroxyacyl-CoA dehydrogenase activities in vitro. Using a kshAs-null strain of M. neoaurum ATCC 25795 (NwIB-XII) as a model, Hsd4A was further confirmed to exert dual-function in sterol catabolism in vivo. The deletion of hsd4A in NwIB-XII resulted in the production of 23,24-bisnorcholenic steroids (HBCs), indicating that hsd4A plays a key role in sterol side-chain degradation. Therefore, two competing pathways, the AD and HBC pathways, were proposed for the side-chain degradation. The proposed HBC pathway has great value in illustrating the production mechanism of HBCs in sterol catabolism and in developing HBCs producing strains for industrial application via metabolic engineering. Through the combined modification of hsd4A and other genes, three HBCs producing strains were constructed that resulted in promising productivities of 0.127, 0.109 and 0.074 g/l/h, respectively.

Display of adenoregulin with a novel Pichia pastoris cell surface display system.

Two Pichia pastoris cell surface display vectors were constructed. The vectors consisted of the flocculation functional domain of Flo 1p with its own secretion signal sequence or the α-factor secretion signal sequence, a polyhistidine (6×His) tag for detection, an enterokinase recognition site, and the insertion sites for target proteins. Adenoregulin (ADR) is a 33-amino-acid antimicrobial peptide isolated from Phyllomedusa bicolor skin. The ADR was expressed and displayed on the Pichia pastoris KM71 cell surface with the system reported. The displayed recombinant ADR fusion protein was detected by fluorescence microscopy and confocal laser scanning microscopy (CLSM). The antimicrobial activity of the recombinant adenoregulin was detected after proteolytic cleavage of the fusion protein on cell surface. The validity of the Pichia pastoris cell surface display vectors was proved by the displayed ADR.

The transduction of His-TAT-p53 fusion protein into the human osteogenic sarcoma cell line (Saos-2) and its influence on cell cycle arrest and apoptosis

The p53 gene is a tumor suppressor gene. It encodes a nuclear phosphoprotein p53 involved in the regulation of cell cycle arrest and apoptosis to maintain the genomic integrity of the cell. As mutations of p53 gene are found in most human cancers, p53 protein becomes a hot target in the research of anticancer therapy. In the present study, an 11-amino acid domain of TAT protein which has been demonstrated to be able to transduce across cell membranes was fused with p53. The result revealed that the fusion protein His-TAT-p53 accumulated in the nucleus and inhibited the growth of the Saos-2 cells. Besides apoptosis, an increased percentage of G2 phase suggested that the transduction of His-TAT-p53 into cells might be associated with a G2 arrest of cell cycle.

Design and evaluation of a phospholipase D based drug delivery strategy of novel phosphatidyl-prodrug

A strategy is proposed to design a safe and simple amphiphilic prodrug delivery system, based on the elevated expression of phospholipase D (PLD) in cancer cells. The method utilizes the transphosphatidylation ability of bacterial PLD on alcohol groups and the hydrolysis activity of overexpressed PLD on phospholipids in cancer cells. Doxorubicin (DOX) was selected as a test drug, and the phosphatidyl-doxorubicin (PX) was synthesized by bacterial PLD. The PX prodrug could be readily self-assembled to nanoparticles with uniform size and was stable during storage and circulation. The pharmacokinetics and biodistribution investigations indicated DOX could be selectively released from PX in cancer cells triggered by the local overexpressed PLD, and PX could significantly prolong the half-life of DOX in the tumors and decrease the distribution in heart and kidney. Moreover, the PX prodrug enhanced cellular uptake in MCF-7/ADR cells, demonstrating it could reverse the multi-drug resistance. Consequently, the prodrug displayed favorable anticancer efficacy in the MCF-7/ADR xenograft model without the cardiotoxicity and nephrotoxicity of DOX. The results demonstrated that phosphatidyl modification method can be used as an efficient strategy to develop a promising nanoscale drug delivery system for some drugs.

Single nucleotide polymorphism analysis for the production of valuable steroid intermediates in Mycobacterium neoaurum

ObjectivesTo investigate single nucleotide polymorphism (SNP) in the transformation process of phytosterol to valuable steroid intermediates in three steroid-producing Mycobacterium neoaurum strains using deep sequencing and bioinformation analysis.ResultsThe assembled contig sequences from RNA sequencing of strains producing 9α-hydroxy-4-androstene-3,17-dione (9OHAD), 1,4-androstadiene-3,17-dione (ADD), and 22-hydroxy-23, 24-bisnorchola-1,4-dien-3-one (1,4-BNA) were analyzed for the presence of putative SNPs for steroid catabolism. 413, 375, and 491 SNPs were detected in the coding domain sequences and non-coding domain sequences of RNA sequencing reads of M. neoaurum strains producing 9OHAD, ADD, and BNA, respectively. Special attention was focused on SNPs associated with genes showing differential expression at proteome level, including the genes for sterol catabolism, glycerol catabolic process, signal transduction systems, transport system and energy metabolism.ConclusionsThe work facilitates the understanding of underlying genetic changes that may be responsible for steroid accumulation in M. neoaurum and is useful for its targeted genetic engineering.

Establishment of a low-dosage-IPTG inducible expression system construction method in Escherichia coli

The lac operon is a delicate inducible gene expression element in bacteria. To efficiently induce gene expression, a sufficient dosage of an inducer, usually that of 500–1000 µM isopropyl β‐D‐1‐thiogalactopyranoside (IPTG), is required to keep repressor LacI from its binding sites, which is a heavy cost burden in low‐value‐added products. So we propose a strategy to reduce the required dosage of IPTG by restricting LacI expression. To test this strategy, we employed a reconstructed IPTG inducible expression system based on lac operon, Promoter(lacO)‐target gene‐PtacL‐lacI, where a modified promoter, Ptac, with a random synthetic library (PtacL) to instead of PlacI to optimize LacI expression in Escherichia coli. Finally, the PtacL mutant, PtacL4, which could maintain the same repression effect as the original PlacI while reducing the required dosage of IPTG from 500 to 20 µM, was selected. This method is simple and efficient and can be of a good reference point for attempts to reduce inducer concentration in the IPTG or similar inducible expression systems.

Metabolic Adaptation of Mycobacterium neoaurum ATCC 25795 in the Catabolism of Sterols for Producing Important Steroid Intermediates

To understand the adaptation of Mycobacterium neoaurum ATCC25795 ( Mn) in sterol catabolism and steroid production, we used integrated transcriptome and proteome analysis to identify the biochemical pathways utilized in this process. Metabolic alterations during sterol catabolism center on propionyl-CoA pools. Generally, enhanced pathways for metabolizing propionyl-CoA were found in Mn, which were tightly coordinated with cell-envelope biosynthesis. The cells responded to sterol substrates and toxic steroid products by changing the composition of the cell envelope. This adaptive mechanism allowed Mn to use minimally water-soluble sterol as a carbon source. Several putative efflux proteins were found to be induced in Mn. They probably transported products to the extracellular environment, protecting the cells against high intracellular levels of toxic intermediates, inhibition of which also influenced sterol uptake. The work provided various targets for rational engineering of robust Mn with powerful sterol-uptake capacity and strong tolerance to toxic products for the steroid industry.

Integrated Transcriptome and Proteome Studies Reveal the Underlying Mechanisms for Sterol Catabolism and Steroid Production in Mycobacterium neoaurum

Integrated transcriptome and proteome studies were performed to investigate sterol biotransformation in wild-type Mycobacterium neoaurum ATCC 25795 ( Mn) and the mutant strains producing steroid intermediates. Transcriptome and proteome studies indicated that several metabolic activities were noticeably dynamic, including cholesterol degradation, central carbon metabolism, cell envelope biosynthesis, glycerol metabolism, and transport. Interestingly, a poor overall correlation between mRNA and translation profiles was found, which might contribute to the metabolic adaptation in cholesterol catabolism. A gene cluster covering 111 genes was discovered to encode for cholesterol catabolism in Mn. Generally, transcription and/or translation of the genes in KstR1 regulon was upregulated, and the induction of genes in KstR2 regulon was not as significant as that of KstR1 regulon. Several induced genes showing potential roles for cholesterol catabolism were found. Further identification of these genes and investigation of the correlation among key metabolic activities could help for the development of efficient steroid-producing strains.

Engineered 3-Ketosteroid 9α-Hydroxylases in Mycobacterium neoaurum: an Efficient Platform for Production of Steroid Drugs

Steroidal drugs are widely used for anti-inflammation, anti-tumor action, endocrine regulation, and fertility management, among other uses. The two main starting materials for the industrial synthesis of steroid drugs are phytosterol and diosgenin. The phytosterol processing is carried out by microbial transformation, which is thought to be superior to the diosgenin processing by chemical conversions, given its simple and environmentally friendly process. However, diosgenin has long been used as the primary starting material instead of phytosterol. This is in response to challenges in developing efficient microbial strains for industrial phytosterol transformation, which stem from complex metabolic processes that feature many currently unclear details. In this study, we identified two oxygenase homologues of 3-ketosteroid-9α-hydroxylase, KshA1N and KshA2N, in M. neoaurum and demonstrated their crucial role in determining the yield and variety of products from phytosterol transformation. This work has practical value in developing industrial strains for phytosterol biotransformation. ABSTRACT 3-Ketosteroid 9α-hydroxylase (Ksh) consists of a terminal oxygenase (KshA) and a ferredoxin reductase and is indispensable in the cleavage of steroid nucleus in microorganisms. The activities of Kshs are crucial factors in determining the yield and distribution of products in the biotechnological transformation of sterols in industrial applications. In this study, two KshA homologues, KshA1N and KshA2N, were characterized and further engineered in a sterol-digesting strain, Mycobacterium neoaurum ATCC 25795, to construct androstenone-producing strains. kshA1N is a member of the gene cluster encoding sterol catabolism enzymes, and its transcription exhibited a 4.7-fold increase under cholesterol induction. Furthermore, null mutation of kshA1N led to the stable accumulation of androst-4-ene-3,17-dione (AD) and androst-1,4-diene-3,17-dione (ADD). We determined kshA2N to be a redundant form of kshA1N. Through a combined modification of kshA1N, kshA2N, and other key genes involved in the metabolism of sterols, we constructed a high-yield ADD-producing strain that could produce 9.36 g liter−1 ADD from the transformation of 20 g liter−1 phytosterols in 168 h. Moreover, we improved a previously established 9α-hydroxy-AD-producing strain via the overexpression of a mutant KshA1N that had enhanced Ksh activity. Genetic engineering allowed the new strain to produce 11.7 g liter−1 9α-hydroxy-4-androstene-3,17-dione (9-OHAD) from the transformation of 20.0 g liter−1 phytosterol in 120 h. IMPORTANCE Steroidal drugs are widely used for anti-inflammation, anti-tumor action, endocrine regulation, and fertility management, among other uses. The two main starting materials for the industrial synthesis of steroid drugs are phytosterol and diosgenin. The phytosterol processing is carried out by microbial transformation, which is thought to be superior to the diosgenin processing by chemical conversions, given its simple and environmentally friendly process. However, diosgenin has long been used as the primary starting material instead of phytosterol. This is in response to challenges in developing efficient microbial strains for industrial phytosterol transformation, which stem from complex metabolic processes that feature many currently unclear details. In this study, we identified two oxygenase homologues of 3-ketosteroid-9α-hydroxylase, KshA1N and KshA2N, in M. neoaurum and demonstrated their crucial role in determining the yield and variety of products from phytosterol transformation. This work has practical value in developing industrial strains for phytosterol biotransformation.