Your search keyword '"steroid reductase"' showing total 3 results

1. Germline Mutations in Steroid Metabolizing Enzymes: A Focus on Steroid Transforming Aldo-Keto Reductases.

Author

Detlefsen AJ, Paulukinas RD, and Penning TM

Subjects

Male, Humans, Aldo-Keto Reductases genetics, Steroids metabolism, Hormones, Membrane Proteins genetics, 3-Oxo-5-alpha-Steroid 4-Dehydrogenase genetics, Germ-Line Mutation, Oxidoreductases metabolism

Abstract

Steroid hormones synchronize a variety of functions throughout all stages of life. Importantly, steroid hormone-transforming enzymes are ultimately responsible for the regulation of these potent signaling molecules. Germline mutations that cause dysfunction in these enzymes cause a variety of endocrine disorders. Mutations in SRD5A2 , HSD17B3 , and HSD3B2 genes that lead to disordered sexual development, salt wasting, and other severe disorders provide a glimpse of the impacts of mutations in steroid hormone transforming enzymes. In a departure from these established examples, this review examines disease-associated germline coding mutations in steroid-transforming members of the human aldo-keto reductase (AKR) superfamily. We consider two main categories of missense mutations: those resulting from nonsynonymous single nucleotide polymorphisms (nsSNPs) and cases resulting from familial inherited base pair substitutions. We found mutations in human AKR1C genes that disrupt androgen metabolism, which can affect male sexual development and exacerbate prostate cancer and polycystic ovary syndrome (PCOS). Others may be disease causal in the AKR1D1 gene that is responsible for bile acid deficiency. However, given the extensive roles of AKRs in steroid metabolism, we predict that with expanding publicly available data and analysis tools, there is still much to be uncovered regarding germline AKR mutations in disease.

Published

2023

2. Knockout of Arabidopsis thaliana   VEP1 , Encoding a PRISE (Progesterone 5β-Reductase/Iridoid Synthase-Like Enzyme), Leads to Metabolic Changes in Response to Exogenous Methyl Vinyl Ketone (MVK).

Author

Klein J, Ernst M, Christmann A, Tropper M, Leykauf T, Kreis W, and Munkert J

Abstract

Small or specialized natural products (SNAPs) produced by plants vary greatly in structure and function, leading to selective advantages during evolution. With a limited number of genes available, a high promiscuity of the enzymes involved allows the generation of a broad range of SNAPs in complex metabolic networks. Comparative metabolic studies may help to understand why-or why not-certain SNAPs are produced in plants. Here, we used the wound-induced, vein patterning regulating VEP1 ( At StR1, At4g24220) and its paralogue gene on locus At5g58750 ( At StR2) from Arabidopsis to study this issue. The enzymes encoded by VEP1 -like genes were clustered under the term PRISEs (progesterone 5β-reductase/iridoid synthase-like enzymes) as it was previously demonstrated that they are involved in cardenolide and/or iridoid biosynthesis in other plants. In order to further understand the general role of PRISEs and to detect additional more "accidental" roles we herein characterized A. thaliana steroid reductase 1 ( At StR1) and compared it to A. thaliana steroid reductase 2 ( At StR2). We used A. thaliana Col-0 wildtype plants as well as VEP1 knockout mutants and VEP1 knockout mutants overexpressing either At StR1 or At StR2 to investigate the effects on vein patterning and on the stress response after treatment with methyl vinyl ketone (MVK). Our results added evidence to the assumption that At StR1 and At StR2, as well as PRISEs in general, play specific roles in stress and defense situations and may be responsible for sudden metabolic shifts.

Published

2021

3. Functional Characterization of the Steroid Reductase Genes GmDET2a and GmDET2b form Glycine max .

Author

Huo W, Li B, Kuang J, He P, Xu Z, and Wang J

Subjects

3-Oxo-5-alpha-Steroid 4-Dehydrogenase metabolism, Gene Expression Regulation, Plant, Hypocotyl metabolism, Plant Leaves metabolism, Plant Proteins metabolism, Glycine max enzymology, 3-Oxo-5-alpha-Steroid 4-Dehydrogenase genetics, Plant Proteins genetics, Glycine max genetics

Abstract

Brassinosteroids are important phytohormones for plant growth and development. In soybean ( Glycine max ), BR receptors have been identified, but the genes encoding BR biosynthesis-related enzymes remain poorly understood. Here, we found that the soybean genome encodes eight steroid reductases (GmDET2a to GmDET2h). Phylogenetic analysis grouped 105 steroid reductases from moss, fern and higher plants into five subgroups and indicated that the steroid reductase family has experienced purifying selection. GmDET2a and GmDET2b, homologs of the Arabidopsis thaliana steroid 5 α -reductase AtDET2, are proteins of 263 amino acids. Ectopic expression of GmDET2a and GmDET2b rescued the defects of the Atdet2-1 mutant in both darkness and light. Compared to the mutant, the hypocotyl length and plant height of the transgenic lines GmDET2a and GmDET2b increased significantly, in both darkness and light, and the transcript levels of the BR biosynthesis-related genes CPD , DWF4 , BR6ox-1 and BR6ox-2 were downregulated in GmDET2aOX-23 and GmDET2bOX-16 lines compared to that in Atdet2-1 . Quantitative real-time PCR revealed that GmDET2a and GmDET2b are ubiquitously expressed in all tested soybean organs, including roots, leaves and hypocotyls. Moreover, epibrassinosteroid negatively regulated GmDET2a and GmDET2b expression. Sulfate deficiency downregulated GmDET2a in leaves and GmDET2b in leaves and roots; by contrast, phosphate deficiency upregulated GmDET2b in roots and leaves. Taken together, our results revealed that GmDET2a and GmDET2b function as steroid reductases., Competing Interests: The authors declare no conflict of interest.

Published

2018