Involvement of Type 10 17ß-Hydroxysteroid Dehydrogenase in the Pathogenesis of Infantile Neurodegeneration and Alzheimer's Disease.

Type 10 17ß-hydroxysteroid dehydrogenase (17ß-HSD10) is the HSD17B10 gene product playing an appreciable role in cognitive functions. It is the main hub of exercise-upregulated mitochondrial proteins and is involved in a variety of metabolic pathways including neurosteroid metabolism to regulate allopregnanolone homeostasis. Deacetylation of 17ß-HSD10 by sirtuins helps regulate its catalytic activities. 17ß-HSD10 may also play a critical role in the control of mitochondrial structure, morphology and dynamics by acting as a member of the Parkin/PINK1 pathway, and by binding to cyclophilin D to open mitochondrial permeability pore. 17ß-HSD10 also serves as a component of RNase P necessary for mitochondrial tRNA maturation. This dehydrogenase can bind with the Aß peptide thereby enhancing neurotoxicity to brain cells. Even in the absence of Aß, its quantitative and qualitative variations can result in neurodegeneration. Since elevated levels of 17ß-HSD10 were found in brain cells of Alzheimer's disease (AD) patients and mouse AD models, it is considered to be a key factor in AD pathogenesis. Since data underlying Aß-binding-alcohol dehydrogenase (ABAD) were not secured from reported experiments, ABAD appears to be a fabricated alternative term for the HSD17B10 gene product. Results of this study would encourage researchers to solve the question why elevated levels of 17ß-HSD10 are present in brains of AD patients and mouse AD models. Searching specific inhibitors of 17ß-HSD10 may find candidates to reduce senile neurodegeneration and open new approaches for the treatment of AD.

The ligation between ERMAP, galectin-9 and dectin-2 promotes Kupffer cell phagocytosis and antitumor immunity.

Kupffer cells, the liver tissue resident macrophages, are critical in the detection and clearance of cancer cells. However, the molecular mechanisms underlying their detection and phagocytosis of cancer cells are still unclear. Using in vivo genome-wide CRISPR-Cas9 knockout screening, we found that the cell-surface transmembrane protein ERMAP expressed on various cancer cells signaled to activate phagocytosis in Kupffer cells and to control of liver metastasis. ERMAP interacted with ß-galactoside binding lectin galectin-9 expressed on the surface of Kupffer cells in a manner dependent on glycosylation. Galectin-9 formed a bridging complex with ERMAP and the transmembrane receptor dectin-2, expressed on Kupffer cells, to induce the detection and phagocytosis of cancer cells by Kupffer cells. Patients with low expression of ERMAP on tumors had more liver metastases. Thus, our study identified the ERMAP-galectin-9-dectin-2 axis as an 'eat me' signal for Kupffer cells.

Infantile Neurodegeneration Results from Mutants of 17ß-Hydroxysteroid Dehydrogenase Type 10 Rather Than Aß-Binding Alcohol Dehydrogenase.

Type 10 17ß-hydroxysteroid dehydrogenase (17ß-HSD10), a homo-tetrameric multifunctional protein with 1044 residues encoded by the HSD17B10 gene, is necessary for brain cognitive function. Missense mutations result in infantile neurodegeneration, an inborn error in isoleucine metabolism. A 5-methylcytosine hotspot underlying a 388-T transition leads to the HSD10 (p.R130C) mutant to be responsible for approximately half of all cases suffering with this mitochondrial disease. Fewer females suffer with this disease due to X-inactivation. The binding capability of this dehydrogenase to Aß-peptide may play a role in Alzheimer's disease, but it appears unrelated to infantile neurodegeneration. Research on this enzyme was complicated by reports of a purported Aß-peptide-binding alcohol dehydrogenase (ABAD), formerly referred to as endoplasmic-reticulum-associated Aß-binding protein (ERAB). Reports concerning both ABAD and ERAB in the literature reflect features inconsistent with the known functions of 17ß-HSD10. It is clarified here that ERAB is reportedly a longer subunit of 17ß-HSD10 (262 residues). 17ß-HSD10 exhibits L-3-hydroxyacyl-CoA dehydrogenase activity and is thus also referred to in the literature as short-chain 3-hydorxyacyl-CoA dehydrogenase or type II 3-hydorxyacyl-CoA dehydrogenase. However, 17ß-HSD10 is not involved in ketone body metabolism, as reported in the literature for ABAD. Reports in the literature referring to ABAD (i.e., 17ß-HSD10) as a generalized alcohol dehydrogenase, relying on data underlying ABAD's activities, were found to be unreproducible. Furthermore, the rediscovery of ABAD/ERAB's mitochondrial localization did not cite any published research on 17ß-HSD10. Clarification of the purported ABAD/ERAB function derived from these reports on ABAD/ERAB may invigorate this research field and encourage new approaches to the understanding and treatment of HSD17B10-gene-related disorders. We establish here that infantile neurodegeneration is caused by mutants of 17ß-HSD10 but not ABAD, and so we conclude that ABAD represents a misnomer employed in high-impact journals.

Identification of GnRH-like peptide and its potential signaling pathway involved in the oocyte meiotic maturation in the Chinese mitten crab, Eriocheir sinensis.

Gonadotropin-releasing hormone (GnRH) plays a pivotal role in reproductive regulation in vertebrates. However, GnRH was rarely isolated and its function remains poorly characterized in invertebrates. The existence of GnRH in ecdysozoa has been controversial for a long. Here, we isolated and identified two GnRH-like peptides from brain tissues in Eriocheir sinensis. Immunolocalization showed that the presence of EsGnRH-like peptide in brain, ovary and hepatopancreas. Synthetic EsGnRH-like peptides can induce germinal vesicle breakdown (GVBD) of oocyte. Similar to vertebrates, ovarian transcriptomic analysis revealed a GnRH signaling pathway in the crab, in which most genes exhibited dramatically high expression at GVBD. RNAi knockdown of EsGnRHR suppressed the expression of most genes in the pathway. Co-transfection of the expression plasmid for EsGnRHR with reporter plasmid bearing CRE-luc or SRE-luc response element into 293T cells showed that EsGnRHR transduces its signal via cAMP and Ca2+ signaling transduction pathways. In vitro incubation of the crab oocyte with EsGnRH-like peptide confirmed the cAMP-PKA cascade and Ca2+ mobilization signaling cascade but lack of a PKC cascade. Our data present the first direct evidence of the existence of GnRH-like peptides in the crab and demonstrated its conserved role in the oocyte meiotic maturation as a primitive neurohormone.

3-Hydroxyacyl-CoA and Alcohol Dehydrogenase Activities of Mitochondrial Type 10 17ß-Hydroxysteroid Dehydrogenase in Neurodegeneration Study.

BACKGROUND: Mitochondrial 17ß-hydroxysteroid dehydrogenase type 10 (17ß-HSD10) is necessary for brain cognitive function, but its studies were confounded by reports of Aß-peptide binding alcohol dehydrogenase (ABAD), formerly endoplasmic reticulum-associated Aß-peptide binding protein (ERAB), for two decades so long as ABAD serves as the alternative term of 17ß-HSD10. OBJECTIVE: To determine whether those ABAD reports are true or false, even if they were published in prestigious journals. METHODS: 6xHis-tagged 17ß-HSD10 was prepared and characterized by well-established experimental procedures. RESULTS: The N-terminal 6xHis tag did not significantly interfere with the dehydrogenase activities of 17ß-HSD10, but the kinetic constants of its 3-hydroxyacyl-CoA dehydrogenase activity are drastically distinct from those of ABAD, and it was not involved in ketone body metabolism as previously reported for ABAD. Furthermore, it was impossible to measure its generalized alcohol dehydrogenase activities underlying the concept of ABAD because the experimental procedures described in ABAD reports violated basic chemical and/or biochemical principles. More incredibly, both authors and journals had not yet agreed to make any corrigenda of ABAD reports. CONCLUSION: Brain 17ß-HSD10 plays a key role in neurosteroid metabolism and further studies in this area may lead to potential treatments of neurodegeneration including AD.

Identification and characterization of a new germline-specific marker vasa gene and its promoter in the giant freshwater prawn Macrobrachium rosenbergii.

Vasa gene encodes a protein member of DEAD-box superfamily of ATP-dependent RNA helicases, which plays a key role in germline development in metazoans. In present study, we identified a new germline-specific marker Mrvasa in the prawn Macrobrachium rosenbergii, whose genomic DNA sequence consists of 14 exons and 13 introns. A 2516 bp of full-length Mrvasa cDNA encodes a protein of 603 amino acids. It contains nine conserved motifs, a zinc-finger motif, and RGG repeats. RT-PCR indicated that Mrvasa mRNA was specifically expressed in gonads. QPCR analysis further revealed that the expression of Mrvasa mRNA is much higher in testis than in ovary. In testis, the relative expression level of Mrvasa mRNA in late developing stage is significantly higher than that in early-middle developing stage. During ovarian development, no significant difference in expression was found. In situ hybridization demonstrated that Mrvasa mRNA was localized in germline cells including spermatogonia, spermatocytes, and spermatozoa in testes, and previtellogenic and vitellogenic oocytes in ovary. We then isolated the Mrvasa promoter and determined the transcription core region of this promoter. This is the first report on identification of vasa core promoter in crustaceans. Our results will provide a useful germline-specific marker Mrvasa for tracing germline cell formation and development in M. rosenbergii.

Identification and characterization of sex-biased and differentially expressed miRNAs in gonadal developments of the Chinese mitten crab, Eriocheir sinensis.

MicroRNA (miRNA) is a posttranscriptional downregulator that plays a vital role in a wide variety of biological processes. In this study, we constructed five ovarian and testicular small RNA libraries using two somatic libraries as reference controls for the identification of sex-biased miRNAs and gonadal differentially expressed miRNAs (DEMs) of the Chinese mitten crab, Eriocheir sinensis. A total of 535 known and 243 novel miRNAs were identified, including 312 sex-biased miRNAs and 402 gonadal DEMs. KEGG pathway analysis showed that DEM target genes were statistically enriched in MAPK, Wnt, and GnRH signaling pathway, and so on. A number of the sex-biased miRNAs target genes associated with sex determination/differentiation, such as IAG, Dsx, Dmrt1, and Fem1, while others target the genes related to gonadal development, such as P450s, Wnt, Ef1, and Tra-2c. Dual-luciferase reporter assay in vitro further confirmed that miR-34 and let-7b can downregulate IAG expression, miR-9-5p, let-7d, let-7b, and miR-8915 can downregulate Dsx. Taken together, these data strongly suggest a potential role for the sex-biased miRNAs in sex determination/differentiation and gonadal development in the crab.

[Radiologic Features of Nuclear Protein of the Testis Midline Carcinoma of the Nasal Cavity and Paranasal Sinuses:Report of One Case].

Nuclear protein of the testis midline carcinoma (NMC) is a rare malignant tumor that is mostly located in the upper trachea,mediastinal midline,and paravertebral midline,and few literature has described the imaging features of NMC in the nasal cavity and paranasal sinuses. In this article we summarize the clinical,radiologic,and pathologic data of one case of pathologically confirmed NMC in the nasal cavity and paranasal sinus by focusing on its CT and magnetic resonance imaging features.

17ß-Hydroxysteroid dehydrogenases and neurosteroid metabolism in the central nervous system.

17ß-Hydroxysteroid dehydrogenases are indispensable for downstream enzyme steps of the neurosteroidogenesis. Neurosteroids are synthesized de novo in neurons and glia from cholesterol transported into mitochondria, or by conversion from proneurosteroids, e. g. dehydroepiandrosterone (DHEA) and pregnenolone, through the same metabolic pathway as revealed in the de novo neurosteroidogenesis. Hormonal steroids generated from endocrine glands are transported into brain from the circulation to exert neuronal activity via genomic pathway, whereas neurosteroids produced in brain cells without genomic targets identified could bind to cell surface targets, e.g., GABAA or NMDA receptors and elicit antidepressant, anxiolytic, anticonvulsant and anesthetic effects by regulating neuroexcitability. In a broad sense, neurosteroids include hormonal steroids in brain, and they are irrespective of origin playing important roles in brain development including neuroprotection, neurogenesis and neural plasticity. They are also a critical element in cognitive and memory functions. Mitochondrial 17ß-HSD10, encoded by the HSD17B10 gene mapping to Xp11.2, is found in various brain regions, essential for the maintenance of neurosteroid homeostasis. Mutations identified in this gene resulted in two distinct brain diseases, namely HSD10 deficiency and MRXS10, of which clinical presentations and pathogenetic mechanisms are quite different. Since elevated levels of 17ß-HSD10 was found in brains of Alzheimer's disease patients and AD mouse model, it may also act as an adverse factor in the AD pathogenesis due to an imbalance of neurosteroid metabolism.

Roles of Mitochondrial 17ß-Hydroxysteroid Dehydrogenase Type 10 in Alzheimer's Disease.

17ß-Hydroxysteroid dehydrogenase type 10 is a multifunctional, homotetrameric, mitochondrial protein encoded by the HSD17B10 gene at Xp 11.2. This protein, 17ß-HSD10, is overexpressed in brain cells of Alzheimer's disease (AD) patients. It was reported to be involved in AD pathogenesis as the endoplasmic reticulum-associated amyloid-ß binding protein (ERAB) and as amyloid-ß binding alcohol dehydrogenase (ABAD). However, the exaggerated catalytic efficiencies for ERAB/ABAD in these reports necessitated the re-characterization of the catalytic functions of this brain enzyme. In addition to isoleucine metabolism, 17ß-HSD10 is also responsible for the mitochondrial metabolism of neurosteroids such as 5α-androstane-3α,17ß-diol and 17ß-estradiol. These neurosteroids are inactivated by the oxidation catalyzed by 17ß-HSD10. Since neurosteroid homeostasis is presumably essential for cognitive function, analysis of the impact of 17ß-HSD10 and its inhibitor, amyloid-ß peptide (Aß), on the metabolism of neuroactive steroids offers a new approach to AD pathogenesis.

Roles of 17ß-hydroxysteroid dehydrogenase type 10 in neurodegenerative disorders.

17ß-Hydroxysteroid dehydrogenase type 10 (17ß-HSD10) is encoded by the HSD17B10 gene mapping at Xp11.2. This homotetrameric mitochondrial multifunctional enzyme catalyzes the oxidation of neuroactive steroids and the degradation of isoleucine. This enzyme is capable of binding to other peptides, such as estrogen receptor α, amyloid-ß, and tRNA methyltransferase 10C. Missense mutations of the HSD17B10 gene result in 17ß-HSD10 deficiency, an infantile neurodegeneration characterized by progressive psychomotor regression and alteration of mitochondria morphology. 17ß-HSD10 exhibits only a negligible alcohol dehydrogenase activity, and is not localized in the endoplasmic reticulum or plasma membrane. Its alternate name - Aß binding alcohol dehydrogenase (ABAD) - is a misnomer predicated on the mistaken belief that this enzyme is an alcohol dehydrogenase. Misconceptions about the localization and function of 17ß-HSD10 abound. 17ß-HSD10's proven location and function must be accurately identified to properly assess this enzyme's important role in brain metabolism, especially the metabolism of allopregnanolone. The brains of individuals with Alzheimer's disease (AD) and of animals in an AD mouse model exhibit abnormally elevated levels of 17ß-HSD10. Abnormal expression, as well as mutations of the HSD17B10 gene leads to impairment of the structure, function, and dynamics of mitochondria. This may underlie the pathogenesis of the synaptic and neuronal deficiency exhibited in 17ß-HSD10 related diseases, including 17ß-HSD10 deficiency and AD. Restoration of steroid homeostasis could be achieved by the supplementation of neuroactive steroids with a proper dosing and treatment regimen or by the adjustment of 17ß-HSD10 activity to protect neurons. The discovery of this enzyme's true function has opened a new therapeutic avenue for treating AD.

Transcription start sites and epigenetic analysis of the HSD17B10 proximal promoter.

BACKGROUND: Hydroxysteroid (17beta) dehydrogenase X (HSD10) is a multifunctional protein encoded by the HSD17B10 gene at Xp11.2. In response to stress or hypoxia-ischemia its levels increase rapidly. Expression of this gene is also elevated significantly in colonic mucosa of the inactive ulcerative colitis patients. However, accurate information about its several transcripts is still lacking, and additional evidence for its escape from X-chromosome inactivation remains to be obtained in order to help settle a debate (He XY, Dobkin C, Yang SY: Does the HSD17B10 gene escape from X-inactivation? Eur J Hum Genet 2011, 19: 123-124). RESULTS: Two major HSD17B10 transcription start sites were identified by primer extension at -37 and -6 as well as a minor start site at -12 nucleotides from the initiation codon ATG. Epigenetic analysis of the 5'-flanking region of the HSD17B10 gene showed that there was little 5-methylcytosine (< 3%) in a normal male, and that none of CpG dinucleotides in the CpG island approached 50% methylation in females. CONCLUSION: The actual length of first exon of the HSD17B10 gene was found to be about a quarter larger than that originally reported. Its transcripts result from a slippery transcription complex. The hypomethylation of the CpG island provides additional evidence for the variable escape of the HSD17B10 gene from X-chromosome inactivation which could influence the range of severity of HSD10 deficiency, an inherited error in isoleucine metabolism, in heterozygous females.

A 5-methylcytosine hotspot responsible for the prevalent HSD17B10 mutation.

Approximately half of the cases of hydroxysteroid (17ß) dehydrogenase X (HSD10) deficiency are due to a missense C>T mutation in exon 4 of the HSD17B10 gene. The resulting HSD10 (p.R130C) loses most or all catalytic functions, and the males with this mutation have a much more severe clinical phenotype than those carrying p.V65A, p.L122V, or p.E249Q mutations. We found that the mutated cytosine which is +2259 nucleotide from the ATG of the gene, is >90% methylated in both the active and inactive X chromosomes in two normal females as well as in the X chromosome of a normal male. Since 5-methylcytosine is prone to conversion to thymine by deamination, the methylation of this cytosine in normal X chromosomes provides an explanation for the prevalence of the p.R130C mutation among patients with HSD10 deficiency. The substitution of arginine for cysteine eliminates several hydrogen bonds and reduces the van der Waals interaction between HSD10 subunits. The resulting disruption of protein structure impairs some if not all of the catalytic and non-enzymatic functions of HSD10. A meta-analysis of residual HSD10 activity in eight patients with the p.R130C mutation showed an average 2-methyl-3-hydroxybutyryl-CoA dehydrogenase (MHBD) activity of only 6 (±5) % of the normal control level. This is significantly lower than in cells of patients with other, clinically milder mutations and suggests that the loss of HSD10/MHBD activity is a marker for the disorder.

A novel mutation in the HSD17B10 gene of a 10-year-old boy with refractory epilepsy, choreoathetosis and learning disability.

Hydroxysteroid (17beta) dehydrogenase 10 (HSD10) is a mitochondrial multifunctional enzyme encoded by the HSD17B10 gene. Missense mutations in this gene result in HSD10 deficiency, whereas a silent mutation results in mental retardation, X-linked, syndromic 10 (MRXS10). Here we report a novel missense mutation found in the HSD17B10 gene, namely c.194T>C transition (rs104886492), brought about by the loss of two forked methyl groups of valine 65 in the HSD10 active site. The affected boy, who possesses mutant HSD10 (p.V65A), has a neurological syndrome with metabolic derangements, choreoathetosis, refractory epilepsy and learning disability. He has no history of acute decompensation or metabolic acidosis whereas his urine organic acid profile, showing elevated levels of 2-methyl-3-hydroxybutyrate and tiglylglycine, is characteristic of HSD10 deficiency. His HSD10 activity was much lower than the normal control level, with normal ß-ketothiolase activity. The c.194T>C mutation in HSD17B10 can be identified by the restriction fragment polymorphism analysis, thereby facilitating the screening of this novel mutation in individuals with intellectual disability of unknown etiology and their family members much easier. The patient's mother is an asymptomatic carrier, and has a mixed ancestry (Hawaiian, Japanese and Chinese). This demonstrates that HSD10 deficiency patients are not confined to a particular ethnicity although previously reported cases were either Spanish or German descendants.

Hydroxysteroid (17ß) dehydrogenase X in human health and disease.

Hydroxysteroid (17ß) dehydrogenase 10 (HSD10), the HSD17B10 gene product, is a mitochondrial NAD(+)-dependent dehydrogenase. There are two outstanding features of this vital enzyme: (a) the versatility of its catalytic endowment is attributed to the flexibility of its active site to accommodate diverse substrates such as steroids, fatty acids, bile acid, and xenobiotics; (b) its capacity to bind other proteins and peptides. For example, it tightly binds with three identical subunits to compose a homotetramer. The homotetramer then binds with two other proteins, namely, RNA (guanine-9-)methyl-transferase domain containing-1 and KIAA0391, to form mitochondrial RNase P. Furthermore, various HSD10 functions are inhibited when the enzyme is bound by amyloid-ß peptide or estrogen receptor alpha. Missense mutations of HSD10 may cause neurodegeneration related to HSD10 deficiency, whereas a silent mutation of HSD10 results in mental retardation, choreoathetosis and abnormal behavior (MRXS10). The clinical condition of some HSD10 patients mimics mitochondrial disorders. Since normal HSD10 function is essential for brain cognitive activity, elevated levels of HSD10 found in brains of Alzheimer disease (AD) patients and mouse AD model might counterbalance the inhibition of HSD10 by amyloid-ß peptide. The investigation of HSD10 may lead to a better understanding of AD pathogenesis.

Mental retardation linked to mutations in the HSD17B10 gene interfering with neurosteroid and isoleucine metabolism.

Mutations in the HSD17B10 gene were identified in two previously described mentally retarded males. A point mutation c.776G>C was found from a survivor (SV), whereas a potent mutation, c.419C>T, was identified in another deceased case (SF) with undetectable hydroxysteroid (17beta) dehydrogenase 10 (HSD10) activity. Protein levels of mutant HSD10(R130C) in patient SF and HSD10(E249Q) in patient SV were about half that of HSD10 in normal controls. The E249Q mutation appears to affect HSD10 subunit interactions, resulting in an allosteric regulatory enzyme. For catalyzing the oxidation of allopregnanolone by NAD+ the Hill coefficient of the mutant enzyme is approximately 1.3. HSD10(E249Q) was unable to catalyze the dehydrogenation of 2-methyl-3-hydroxybutyryl-CoA and the oxidation of allopregnanolone, a positive modulator of the gamma-aminobutyric acid type A receptor, at low substrate concentrations. Neurosteroid homeostasis is critical for normal cognitive development, and there is increasing evidence that a blockade of isoleucine catabolism alone does not commonly cause developmental disabilities. The results support the theory that an imbalance in neurosteroid metabolism could be a major cause of the neurological handicap associated with hydroxysteroid (17beta) dehydrogenase 10 deficiency.

Polyethylene glycol conjugated bovine hemoglobin containing 15% MetHb plays approving effect in exchange transfusion rabbit model.

PEG-bHb was developed by Kaizheng Biotech (Beijing, China), and pre-clinical research was completed. The objective of this study was to investigate the safe concentration of MetHb in PEG-bHb. The study was accomplished by examining the effects of PEG-bHb containing 5%, 8%, 15%, and 25% methemoglobin (MetHb), respectively, on cardiovascular system, blood chemistry, pathology of liver and kidney in rabbits following a 50% exchange transfusion. The results showed that PEG-bHb containing 5%, 8%, 15%, and 25% MetHb could keep four groups of experimental rabbits (5/5) alive until the 8th day after 50% exchange infusion as autologous whole blood did, and were superior to dextran 40 (2/5). MetHb concentration in PEG-bHb, no more than 25%, did not affect the PEG-bHb function on resuscitation of hemorrhaged rabbits by physiological measurements and blood chemistry assays. Histology study using optic and electron microscopy showed that there were slight pathological changes in hepatocytes and renal tubule epithelia in rabbits, which were infused by PEG-bHb containing 5%, 8%, and 15% MetHb. Partial organelles collapse was observed in rabbits resuscitated by PEG-bHb containing 25% MetHb. In conclusion, PEG-bHb is safe and effective when the MetHb concentration is at or below 15%.