Affinage

AKR1C4

Aldo-keto reductase family 1 member C4 · UniProt P17516

Length
323 aa
Mass
37.1 kDa
Annotated
2026-06-09
17 papers in source corpus 8 papers cited in narrative 8 extracted findings
Cross-family judge vs UniProt: Affinage preferred faithfulness: 5/5 claims corpus-supported (100%)

Mechanistic narrative

Synthesis pass · prose summary of the discoveries below

AKR1C4 is a virtually liver-specific, NAD(P)(H)-dependent aldo-keto reductase that catalyzes the stereospecific interconversion of ketosteroids and hydroxysteroids at the 3-, 17-, and 20-positions, thereby governing the levels of active sex hormones and dihydrosteroid metabolites (PMID:10998348). It is the most catalytically efficient AKR1C isoform, inactivating 5α-DHT to 3α-androstanediol, oxidizing testosterone, reducing oestrone to 17β-oestradiol, and forming 5α/5β-tetrahydrosteroids (PMID:10998348); it is the major hepatic enzyme of the 5β-pathway, reducing 5β-dihydrotestosterone preferentially to the 3α-hydroxy configuration (PMID:21521174). Its distinctive catalytic behavior derives in part from His-216 (in place of the Tyr conserved in AKR1C1–1C3), which orients the nicotinamide ring of the coenzyme and shapes the substrate-binding cavity, modulating cofactor affinity, substrate-dependent kinetics, and inhibitor sensitivity (PMID:11104674). Hepatic, cell-type-restricted expression is established by cooperative transactivation through HNF-4α/HNF-4γ and HNF-1α binding to adjacent promoter elements—with non-activating vHNF-1-C occupancy explaining silencing in non-hepatic cells—and is further induced by LXRα binding to an upstream response element (PMID:11284743, PMID:12220531, PMID:18024509). Beyond steroid metabolism, AKR1C4 enzymatic activity suppresses ferroptosis to confer chemotherapy resistance in colorectal cancer cells, an effect lost in a catalytically dead mutant (PMID:38890190).

Mechanistic history

Synthesis pass · year-by-year structured walk · 7 steps
  1. 2000 High

    Established that AKR1C4 is a bona fide, highly efficient steroid-metabolizing oxidoreductase, defining its molecular activity and the liver-restricted context in which it operates.

    Evidence Recombinant protein kinetics, product identification, and isoform-specific RT-PCR across AKR1C1–1C4

    PMID:10998348

    Open questions at the time
    • In vitro substrate preferences do not establish the dominant physiological reaction direction in hepatocytes
    • Did not resolve structural basis of catalytic superiority over other isoforms
  2. 2000 High

    Pinpointed His-216 as a determinant of AKR1C4's cofactor orientation and substrate cavity, explaining its kinetic distinctiveness from the Tyr-216 paralogs.

    Evidence Site-directed mutagenesis (H216Y, H216F) with kinetic, inhibitor, and activator binding analysis on purified enzymes

    PMID:11104674

    Open questions at the time
    • No crystal structure of AKR1C4 itself; interpretation rests on family member structures
    • Effect of His-216 on the full physiological substrate panel not exhaustively mapped
  3. 2001 High

    Resolved how hepatic AKR1C4 transcription is driven, showing cooperative control by adjacent HNF-4α/γ and HNF-1α cis-elements.

    Evidence Luciferase reporters, footprinting, EMSA/supershift, and promoter mutagenesis in HepG2 cells

    PMID:11284743

    Open questions at the time
    • Did not address signals upstream that modulate HNF factor activity
    • Promoter analysis in a single hepatic cell line
  4. 2002 Medium

    Explained tissue-restricted expression as differential transcription-factor occupancy, with non-activating vHNF-1-C occupying the same elements in non-hepatic cells.

    Evidence Reporter assays, supershift EMSA, RT-PCR, and vHNF-1-C transfection in HepG2 vs ACHN cells

    PMID:12220531

    Open questions at the time
    • Single-lab extension of the prior promoter study
    • Does not establish in vivo relevance of vHNF-1-C silencing across tissues
  5. 2007 Medium

    Added a nuclear-receptor input by showing LXRα directly activates AKR1C4 transcription, linking the gene to lipid/sterol-sensing regulation.

    Evidence HMM prediction of response elements plus ChIP/microarray and protein expression analysis

    PMID:18024509

    Open questions at the time
    • Physiological ligand/condition triggering LXRα-driven induction not defined
    • Two complementary methods from a single lab
  6. 2011 High

    Identified AKR1C4 as the principal hepatic enzyme of the 5β-pathway, defining its stereochemical product preference for 5β-dihydrotestosterone.

    Evidence In vitro reconstitution with LC-MS product characterization, kinetics, and molecular docking across AKR1C1–1C4

    PMID:21521174

    Open questions at the time
    • In vivo flux through the 5β-pathway not directly quantified
    • Docking model not validated by experimental structure
  7. 2024 Medium

    Extended AKR1C4 function beyond steroid metabolism, demonstrating that its catalytic activity suppresses ferroptosis and drives chemoresistance in colorectal cancer.

    Evidence CRISPR/Cas9 knockout, Y55A catalytic-dead rescue, viability/iron/lipid-peroxidation readouts in chemoresistant cell lines

    PMID:38890190

    Open questions at the time
    • The metabolic substrate/product responsible for ferroptosis suppression is not identified
    • Single-lab cell-line study without in vivo confirmation
    • Mechanism linking enzymatic output to lipid peroxidation unresolved

Open questions

Synthesis pass · forward-looking unresolved questions
  • It remains unknown how AKR1C4's steroid-reductase chemistry mechanistically connects to lipid-peroxidation/ferroptosis control, and whether its in vivo physiological role is dominated by steroid clearance or by the cancer-associated activity.
  • No identified endogenous substrate bridging steroid metabolism and ferroptosis
  • No experimentally determined AKR1C4 structure
  • In vivo physiological consequences of expression changes not established

Mechanism profile

Synthesis pass · controlled-vocabulary classification · explore literature graph →
Molecular activity
GO:0016491 oxidoreductase activity 4
Pathway
R-HSA-1430728 Metabolism 2

Evidence

Reading pass · 8 per-paper findings extracted from the source corpus
Year Finding Method Journal Conf PMIDs
2000 AKR1C4 (type 1 3α-HSD) functions as a highly catalytically efficient NAD(P)(H)-dependent ketosteroid reductase and hydroxysteroid oxidase, acting on 3-, 17-, and 20-positions of steroids. It is the most catalytically efficient isoform (k_cat/K_m 10–30-fold higher than AKR1C1–1C3), inactivates 5α-DHT to 3α-androstanediol, oxidizes testosterone to androstene-3,17-dione, reduces oestrone to 17β-oestradiol, and forms 5α/5β-tetrahydrosteroids. It is virtually liver-specific in tissue distribution. Recombinant protein expression, kinetic parameter determination, product identification by biochemical assay, isoform-specific RT-PCR for tissue distribution The Biochemical journal High 10998348
2011 AKR1C4 is the major enzyme responsible for the hepatic formation of the 5β-tetrahydrosteroid of testosterone via the 5β-pathway: it reduces 5β-dihydrotestosterone predominantly to the 3α-hydroxy configuration, with the stereochemistry explained by molecular docking. AKR1C4 has the highest kinetic efficiency for this substrate among AKR1C1–1C4. In vitro enzymatic assay with purified recombinant AKR1C1–1C4, product characterization by liquid chromatography-MS, kinetic parameter determination, molecular docking The Biochemical journal High 21521174
2000 His-216 in AKR1C4 (unique compared to the conserved Tyr-216 in AKR1C1–1C3) plays a key role in orienting the nicotinamide ring of the coenzyme and shaping the substrate-binding cavity. Replacement of His-216 with Tyr or Phe decreased K_m for NADP+ ~3-fold, differentially altered K_m and k_cat for substrates depending on structure (bile acids with 12α-OH vs. others), changed inhibitor sensitivity, and reduced stimulatory effects of non-essential activators. Site-directed mutagenesis of AKR1C4 (H216Y, H216F), kinetic analysis with purified mutant enzymes, inhibitor and activator binding assays The Biochemical journal High 11104674
2001 Transcription of the human AKR1C4 (DD4) gene in hepatic cells is cooperatively regulated by HNF-4α and HNF-4γ binding to a cis-element at −701 to −684, and HNF-1α binding to a cis-element at −682 to −666. Mutation of either element reduces luciferase reporter activity to ~10% and ~8% of wild-type, respectively. Luciferase reporter assay in HepG2 cells, 1,10-phenanthroline-copper footprinting, gel-shift (EMSA) assay, supershift assay with antibodies to HNF-4α, HNF-4γ, HNF-1α, promoter deletion/mutation analysis The Biochemical journal High 11284743
2002 Cell-type-specific expression of AKR1C4 (DD4) is determined by differential occupancy of the HNF-4/HNF-1 promoter elements: in hepatic HepG2 cells, HNF-4α, HNF-4γ, and HNF-1α activate transcription, whereas in non-expressing ACHN renal cells, vHNF-1-C (a truncated isoform lacking transcriptional activation domain) occupies the same elements without activating transcription. Reporter gene (luciferase) assay, supershift EMSA with isoform-specific antibodies, semi-quantitative RT-PCR, transfection with vHNF-1-C expression plasmid Archives of biochemistry and biophysics Medium 12220531
2007 LXRα (NR1H3) binds to a response element ~1.5 kb upstream of the AKR1C4 transcription start site and mediates transcriptional activation of AKR1C4, leading to increased AKR1C4 protein expression. This was identified by hidden Markov model prediction combined with chromatin immunoprecipitation/microarray analysis. Hidden Markov model prediction of nuclear receptor response elements, chromatin immunoprecipitation (ChIP)/microarray, demonstration of LXRα binding to the LXRE and transcriptional activation of AKR1C4 Molecular pharmacology Medium 18024509
1995 The AKR1C4 gene (as CHDR/chlordecone reductase) and closely related dihydrodiol dehydrogenase genes (DDH1, DDH2) are all located on human chromosome 10p14–p15. PCR with gene-specific primers on human/hamster hybrid DNA panel, fluorescence in situ hybridization (FISH) Genomics Medium 7789999
2024 AKR1C4 enzymatic activity is required to suppress ferroptosis and confer chemotherapy resistance in colorectal cancer cells: CRISPR/Cas9 knockout of AKR1C4 enhances sensitivity to 5-FU, irinotecan, and oxaliplatin by inducing ferroptosis (increased total iron and lipid peroxidation). A Y55A catalytic mutant of AKR1C4 fails to rescue chemoresistance, demonstrating that enzymatic activity is necessary. CRISPR/Cas9 knockout, catalytic point mutant (Y55A) rescue assay, SRB cell viability assay, total iron content measurement, lipid peroxidation measurement, acquisition of chemoresistant cell lines by long-term drug induction Cancer chemotherapy and pharmacology Medium 38890190

Source papers

Stage 0 corpus · 17 papers · ranked by NIH iCite citations
Year Title Journal Citations PMID
2000 Human 3alpha-hydroxysteroid dehydrogenase isoforms (AKR1C1-AKR1C4) of the aldo-keto reductase superfamily: functional plasticity and tissue distribution reveals roles in the inactivation and formation of male and female sex hormones. The Biochemical journal 516 10998348
2017 Aldo-Keto Reductase AKR1C1-AKR1C4: Functions, Regulation, and Intervention for Anti-cancer Therapy. Frontiers in pharmacology 105 28352233
2011 Stereospecific reduction of 5β-reduced steroids by human ketosteroid reductases of the AKR (aldo-keto reductase) superfamily: role of AKR1C1-AKR1C4 in the metabolism of testosterone and progesterone via the 5β-reductase pathway. The Biochemical journal 38 21521174
2003 Drosophila dd4 mutants reveal that gammaTuRC is required to maintain juxtaposed half spindles in spermatocytes. Journal of cell science 27 12571290
2011 AKR1C4 gene variant associated with low euthymic serum progesterone and a history of mood irritability in males with bipolar disorder. Journal of affective disorders 26 21570127
2007 Regulation of human 3 alpha-hydroxysteroid dehydrogenase (AKR1C4) expression by the liver X receptor alpha. Molecular pharmacology 25 18024509
2020 Discovery of an Inducible Toluene Monooxygenase That Cooxidizes 1,4-Dioxane and 1,1-Dichloroethylene in Propanotrophic Azoarcus sp. Strain DD4. Applied and environmental microbiology 23 32591384
2000 Molecular cloning of the crustacean DD4 cDNA encoding a Ca(2+)-binding protein. Biochemical and biophysical research communications 23 11006119
1995 Localization of multiple human dihydrodiol dehydrogenase (DDH1 and DDH2) and chlordecone reductase (CHDR) genes in chromosome 10 by the polymerase chain reaction and fluorescence in situ hybridization. Genomics 23 7789999
2012 Polymorphisms in AKR1C4 and HSD3B2 and differences in serum DHEAS and progesterone are associated with paranoid ideation during mania or hypomania in bipolar disorder. European neuropsychopharmacology : the journal of the European College of Neuropsychopharmacology 22 22356824
2001 Co-operative regulation of the transcription of human dihydrodiol dehydrogenase (DD)4/aldo-keto reductase (AKR)1C4 gene by hepatocyte nuclear factor (HNF)-4alpha/gamma and HNF-1alpha. The Biochemical journal 17 11284743
2021 Large trans-ethnic meta-analysis identifies AKR1C4 as a novel gene associated with age at menarche. Human reproduction (Oxford, England) 10 34021356
2002 Expression pattern of dd4, a sole member of the d4 family of transcription factors in Drosophila melanogaster. Mechanisms of development 7 12175496
2000 Kinetic alteration of a human dihydrodiol/3alpha-hydroxysteroid dehydrogenase isoenzyme, AKR1C4, by replacement of histidine-216 with tyrosine or phenylalanine. The Biochemical journal 6 11104674
2002 Hepatocyte nuclear factor (HNF)-4 alpha/gamma, HNF-1 alpha, and vHNF-1 regulate the cell-specific expression of the human dihydrodiol dehydrogenase (DD)4/AKR1C4 gene. Archives of biochemistry and biophysics 5 12220531
2025 Genetic and computational analysis of AKR1C4 gene rs17134592 polymorphism in breast cancer among the Bangladeshi population. Scientific reports 1 40721470
2024 AKR1C4 regulates the sensitivity of colorectal cancer cells to chemotherapy through ferroptosis modulation. Cancer chemotherapy and pharmacology 1 38890190

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