BACKGROUND:The researches about the effect of retinoic acid on the proliferation of adipose-derived stem cells are rare, and the researches on the testosterone are mainly on the inhibition of cellaging. OBJECTIVE: To study the effects of retinoic acid and testosterone or combination on the cellcycle of adipose derived stem cells. METHODS:Adipose derived stem cells were isolated from adult female Sprague Dawley rats with 2 months age and cultured in vitro til passage 3 adipose derived stem cells, and then the 3rd passage adipose-derived stem cells were performed with adipogenic induction, osteogenic induction and surface marker identification. The cells were divided into six groups:(1) Control group;(2) 10-5 mol/L retinoic acid group;(3) Retinoic acid group;(4) 10-5 mol/L retinoic acid+testosterone group;(5) 10-6 mol/L retinoic acid+testosterone group;(6) Testosterone group. The adipose-derived stem cells in the control group were cultured with Dulbecco’s modified Eagle’s medium+10%fetal bovine serum culture medium, and the adipose-derived stem cells in the other five groups were induced with corresponding dose of retinoic acid and testosterone on the basis of control group. After cultured for 36 hours, the flow cytometry was used to detect the changes of cellcycle. RESULTS AND CONCLUSION:Compared with the control group, cellproportions in phase G 1 of 10-5 mol/L retinoic acid group and 10-6 mol/L retinoic acid group were increased significantly, and the cellproportions in phase S were decreased. Compared with control group, the cellproportion in phase G 1 of testosterone group was significantly reduced, and the cellproportion in phase S was increased. Compared with 10-5 mol/L retinoic acid group and 10-6 mol/L retinoic acid group, cellproportions in phase G 1 of 10-5 mol/L retinoic acid+testosterone group and 10-6 mol/L retinoic acid+testosterone group were reduced significantly and the cellproportions in phase S were increased. Retinoic acid can inhibit the cellcycle of adipose-derived stem cells in phase G 1 , and delay the process of the cellcycle from phase G1 to phase S;while testosterone can promote the cellcycle of adipose-derived stem cells from phase G1 to phase S;the combination induction of retinoic acid and testosterone can accelerate the process of the cellcycle of adipose-derived stem cells from phase G 1 to phase S.

OBJECTIVETo investigate whether adipose-derived stem cells (ADSCs) induced by retinoic acid (RA) in vitro express primordial germ cell marker alkaline phosphatase (ALP) and vasa.

METHODSADSCs were isolated from adult female SD rats and cultured in vitro. The third passage of ADSCs was identified by adipogenic differentiation, osteogenic differentiation and cell surface marker detection. The ADSCs were treated with 1×10(-5), 1×10(-6), or 1×10(-7) mol/L RA for 7 or 14 days, and the cellular expression of ALP was detected. vasa mRNA expression in ADSCs treated with 1×10(-5) mol/L RA for 7 days was detected using RT-PCR.

RESULTSThe OD value of ADSCs treated with 1×10(-5), 1×10(-6), or 1×10(-7) mol/L RA was 0.59∓0.04, 0.27∓0.07, and 0.15∓0.03 after a 7-day treatment, and was 0.42∓0.02, 0.34∓0.01, and 0.19∓0.02 after a 14-day treatment, respectively, demonstrating significantly enhanced ALP expression in RA-treated ADSCs compared with that in the control cells (0.07∓0.01 and 0.07∓0.01 at 7 and 14 days, respectively, P<0.01). The ADSCs showed a negative vasa mRNA expression after 1×10(-5) mol/L RA treatment for 7 days.

CONCLUSIONRA-induced ADSCs express ALP, a marker of primordial germ cells, but does not express the primordial germ cell marker vasa.

Adipose Tissue ; cytology ; Adult Stem Cells ; cytology ; enzymology ; Alkaline Phosphatase ; metabolism ; Animals ; Cell Differentiation ; Cells, Cultured ; Female ; Germ Cells ; cytology ; metabolism ; Rats ; Rats, Sprague-Dawley ; Tretinoin ; pharmacology

OBJECTIVE: To detect variant of EDA gene in a fetus with absence of germ teeth detected by prenatal ultrasonography. METHODS: Clinical data and amniotic fluid and peripheral venous blood samples of the pregnant woman were collected for the analysis. Following extraction of genome DNA, the coding regions of the EDA gene were amplified by PCR and subjected to next-generation sequencing. Candidate variant was verified by Sanger sequencing. RESULTS: The pregnant woman was found to carry a heterozygous c.574G>A variant in the EDA gene, for which the fetus was hemizygous. Bioinformatic analysis suggested the variant to be pathogenic. CONCLUSION Combined ultrasonographic and genetic findings suggested the fetus is affected with X-linked hypohidrotic ectodermal dysplasia due to pathogenic variant of the EDA gene.
Ectodermal Dysplasia 1, Anhidrotic/genetics* ; Ectodysplasins/genetics* ; Female ; Fetus ; Humans ; Mutation ; Pedigree ; Pregnancy ; Prenatal Diagnosis

OBJECTIVE: To explore the genetic basis for a fetus with lissencephaly. METHODS: Genomic DNA was extracted from amniotic fluid sample and subjected to copy number variation (CNV) analysis. RESULTS: The fetus was found to harbor a heterozygous 5.2 Mb deletion at 17p13.3p13.2, which encompassed the whole critical region of Miller-Dieker syndrome (MDS) (chr17: 1-2 588 909). CONCLUSION The fetus was diagnosed with MDS. Deletion of the PAFAH1B1 gene may account for the lissencephaly found in the fetus.
1-Alkyl-2-acetylglycerophosphocholine Esterase/genetics* ; Chromosome Deletion ; Chromosomes, Human, Pair 17/genetics* ; Classical Lissencephalies and Subcortical Band Heterotopias/genetics* ; Female ; Fetus ; Genetic Testing ; Humans ; Microtubule-Associated Proteins/genetics* ; Pregnancy ; Prenatal Diagnosis

OBJECTIVE: To explore the genetic basis for a child affected with Bainbridge-Ropers syndrome. METHODS: Genomic DNA was extracted from peripheral venous blood samples from the patient and his parents. Whole exome sequencing (WES) was carried out to detect genetic variant of the proband. Candidate variant was verified by Sanger sequencing. RESULTS: The 3-year-old boy presented with psychomotor retardation, linguistic difficulties, mental retardation and peculiar craniofacial phenotype. A de novo heterozygous nonsense variant of the ASXL3 gene, c.3106C>T, was identified by WES in the proband, and the same mutation was not found among his parents. Based on the American College of Medical Genetics and Genomics standards and guidelines, the c.3106C>T variant was predicted to be pathogenic (PVS1+PS2+PP4). CONCLUSION The heterozygous variant c.3106C>T of the ASXL3 gene probably underlies the Bainbridge-Ropers syndrome in the patient. Above result has enabled the clinical diagnosis and genetic counseling for the family.
Child ; Child, Preschool ; Heterozygote ; Humans ; Intellectual Disability/genetics* ; Male ; Mutation ; Phenotype ; Transcription Factors/genetics* ; Whole Exome Sequencing

OBJECTIVE: To explore the clinical and genetic characteristics of a child with X-linked hypohidrotic ectodermal dysplasia (XLHED). METHODS: Clinical data of the child was collected. Peripheral blood samples were taken from the child and his parents with informed consent and subjected to copy number variation (CNV) analysis and whole exome sequencing (WES). RESULTS: The male infant manifested sparse hair, anhidrosis, anuresis due to polycystic kidney dysplasia, external genital malformation and anal atresia. WES has revealed a 406 bp hemizygous deletion at Xq13 (68 836 147-68 836 553) in the proband, which encompassed exon 1 of the EDA gene. A heterozygous deletion at the same site was detected in the mother, while no deletion or duplication of the site was detected in the father. CONCLUSION The hemizygous deletion of EDA gene exon 1 probably underlay the ectodermal dysplasia in the proband. Above result has provided a basis for genetic counseling and prenatal diagnosis for the family.
Child ; DNA Copy Number Variations ; Ectodermal Dysplasia/genetics* ; Ectodermal Dysplasia 1, Anhidrotic/genetics* ; Ectodysplasins/genetics* ; Genetic Testing ; Humans ; Infant ; Male ; Pedigree

OBJECTIVE: To explore the genetic basis for a patient with Leydig cell hypoplasia. METHODS: Whole exome sequencing was used to detect genetic variants in the patient. Suspect variants were verified by PCR and Sanger sequencing of the family members. RESULTS: The patient was found to carry two novel variants, namely c.265A>T (p.Ile189Leu) and c.422T>C (p.Val141Ala), of the luteinizing hormone receptor gene (LHCGR), where were respectively inherited from her father and mother. Upon prenatal diagnosis, the fetus was found to be a heterozygous carrier of the c.265A>T (p.Ile189Leu) variant. CONCLUSION The compound heterozygous variants of c.265A>T (p.Ile189Leu) and c.422T>C (p.Val141Ala) of the LHCGR gene probably underlie the Leydig cell hypoplasia in the patient.