Objective To investigate the expressions of glycolysis-related factors and changes in Notch1 signaling in endometrial tissues of adenomyosis(AM)and Ishikawa cells to explore the pathogenesis of AM.Methods Eutopic endometrial tissues were collected from 8 patients with AM and 8 patients with uterine fibroids matched for clinical characteristics(control group).The expressions of Notch1 signaling proteins and glycolysis-related factors in the collected tissues were detected using qRT-PCR and Western blotting,and the levels of glucose and lactic acid were determined.An Ishikawa cell model with lentivirus-mediated stable Notch1 overexpression was established for assessing cell survival rate with CCK-8 assay,cell migration and invasion abilities with Transwell migration and invasion assays,and glycolytic capacity by determining the extracellular acidification rate.Results Compared with those in the control group,the endometrial tissues in AM group showed significantly increased expression level of carbohydrate antigen 125(CA125),increased mRNA expression levels of Notch1,HK2 and PDHA and protein expressions of Notch1,GLUT1,HK2,PKM and PDHA,lowered glucose level and increased lactate level.The Ishikawa cell models with stable Notch1 overexpression exhibited significantly increased cell survival rate with attenuated cell migration and invasion abilities and decreased glycolysis capacity and reserve.Conclusion The Notch1 signaling pathway participates in the pathogenesis of AM possibly by regulating the proliferation,migration,invasion and glycolysis of endometrial cells.

Objective To investigate the expressions of glycolysis-related factors and changes in Notch1 signaling in endometrial tissues of adenomyosis(AM)and Ishikawa cells to explore the pathogenesis of AM.Methods Eutopic endometrial tissues were collected from 8 patients with AM and 8 patients with uterine fibroids matched for clinical characteristics(control group).The expressions of Notch1 signaling proteins and glycolysis-related factors in the collected tissues were detected using qRT-PCR and Western blotting,and the levels of glucose and lactic acid were determined.An Ishikawa cell model with lentivirus-mediated stable Notch1 overexpression was established for assessing cell survival rate with CCK-8 assay,cell migration and invasion abilities with Transwell migration and invasion assays,and glycolytic capacity by determining the extracellular acidification rate.Results Compared with those in the control group,the endometrial tissues in AM group showed significantly increased expression level of carbohydrate antigen 125(CA125),increased mRNA expression levels of Notch1,HK2 and PDHA and protein expressions of Notch1,GLUT1,HK2,PKM and PDHA,lowered glucose level and increased lactate level.The Ishikawa cell models with stable Notch1 overexpression exhibited significantly increased cell survival rate with attenuated cell migration and invasion abilities and decreased glycolysis capacity and reserve.Conclusion The Notch1 signaling pathway participates in the pathogenesis of AM possibly by regulating the proliferation,migration,invasion and glycolysis of endometrial cells.

Objective:To explore the genetic basis for a child with congenital disorder of glycosylation type 1y (CDG-1y) in conjunct with congenital dysplasia of external auditory canal.Methods:Trio-whole exome sequencing (trio-WES) was carried out for the family. Candidate variant was verified by Sanger sequencing. Pathogenicity of the variant was predicted with a variety of bioinformatic tools.Results:The proband, a 10-years-old boy, presented with mental retardation, microcephaly and dysplasia of external auditory canal. Trio-WES revealed that he has harbored a de novo frameshift variant c. 302dupC (p.Y102Lfs*2) in exon 4 of SSR4 gene, which was unreported previously (PS2). The variant was absent in major allele frequency databases (PM2) and was predicted to be pathogenic by multiple bioinformatic tools (PP3). UCSF chimera software suggested that the c. 302dupC (p.Y102Lfs*2) variant can induce significant alteration to the structure of SSR4 protein, resulting loss of function (PVS1+ PM1). Based on the guidelines from the American College of Medical Genetics and Genomics, the variant was classified as pathogenic (PVS1+ PS2+ PM1+ PM2+ PP3) Conclusion:The de novo frameshift variant c. 302dupC (p.Y102Lfs*2) of the SSR4 gene probably underlay the child′s condition. Above finding has enriched the spectrum of SSR4 mutations and the phenotypic spectrum of CDG-1y.

OBJECTIVE: To explore the genetic basis for a child suspected for Say-Barber-Biesecker-Young-Simpson syndrome. METHODS: Genomic DNA was extracted from peripheral blood samples of the child and her parents. Whole exome sequencing was carried out for the proband. Suspected variants were validated by Sanger sequencing. The impact of the variants was predicted by bioinformatic analysis. RESULTS: The child was found to harbor a de novo missense variant c.2623C>T (p.Asp875Tyr) in exon 13 of the KAT6B gene. The variant was previously unreported, and was not recorded in the major allele frequency database and predicted to be pathogenic based on PolyPhen-2, MutationTaster and PROVEAN analysis. As predicted by UCSF chimera and CASTp software, the variant can severely impact the substrate-binding pocket of histone acetyltransferase, resulting in loss of its enzymatic activity. Based on standards and guidelines by the American College of Medical Genetics and Genomics, the variant was classified to be likely pathogenic (PS2+PM2+PP3). CONCLUSION The child's condition may be attributed to the de novo missense c.2623C>T (p.Asp875Tyr) variant of the KAT6B gene.
Blepharophimosis ; Child ; Congenital Hypothyroidism ; Facies ; Female ; Heart Defects, Congenital ; Histone Acetyltransferases/genetics* ; Humans ; Intellectual Disability ; Joint Instability ; Mutation ; Phenotype

OBJECTIVE: To analyze a pathogenic variant of MEFV gene in a family with autosomal dominant-familial Mediterranean fever (AD-FMF). METHODS: A 5-year-old boy presented with recurrent aseptic meningitis and his major symptoms included recurrent fever with headache and vomiting. His family members including his mother, sister and brother also had recurrent fever. A genetic disease was considered. DNAs were extracted from patient and all his family members' blood samples. Whole exome sequencing was performed to identify putative pathogenic variants that can explain this family's condition and Sanger sequencing was conducted. The impact of detected variants were predicted and validated by bioinformatics. RESULTS: A missense variant c.2229C>G (p.Phe743Leu) in MEFV gene was identified in the proband and his family members including his mother, sister and brother. This variant had not been reported in China previously, but the locus of it had already been reported in Arabic patient with AD-FMF (PS1). This variant was absent in major allele frequency databases (PM2) and had been predicted to be pathogenic based on Mutationtaster, PROVEAN and PolyPhen-2. In addition, the change of amino acid, locating in 743 locus of pyrin protein, encoding by MEFV gene, was found to cause SPRY_PRY_TRIM20 and SPRY_superfamily domain destroyed and finally influenced the fuction of pyrin protein. On the other hand, using UCSF chimera software, we find the variant c.2229C>G (p.Phe743Leu) can induce serious influence to the spatial structure of pyrin protein and loss of protein fuction (PP3). According to the ACMG variant classification guideline, the variant c.2229C>G (p.Phe743Leu) in MEFV gene was classified as likely pathogenic (PS1+PM2+PP3). CONCLUSION The condition of this AD-FMF family may be attributed to the missense variant c.2229C>G (p.Phe743Leu) in MEFV gene. The recurrent aseptic meningitis was a very rare manifestation in AD-FMF patients and had not been reported in China previously. The clinical and genetic findings of the present study are helpful for the further understanding of AD-FMF.
Child, Preschool ; Familial Mediterranean Fever/genetics* ; Gene Frequency ; Genetic Testing ; Humans ; Male ; Mutation ; Pyrin/genetics* ; Whole Exome Sequencing

OBJECTIVE: To explore the genetic basis for a child featuring X-linked intellectual disability. METHODS: The 1-year-and-6-month-old child presented with growth retardation, intellectual disability and bilateral alternating squint. With DNA extracted from the child and his parents' peripheral venous blood samples, whole exome sequencing was carried out to identify potential variants that can explain his condition. Suspected variants were validated by Sanger sequencing. The impact of variants was predicted by bioinformatic tools. RESULTS: The child was found to harbor a de novo nonsense c.3163C>T (p.Arg1055*) variant of the IQSEC2 gene. The variant, unreported previously, was predicted to be pathogenic based on MutationTaster, PROVEAN and SIFT. Analysis using a HomoloGene system suggested Arg1055 in IQSEC2 residues to be highly conserved evolutionarily, and that replacement of Arg1055 may cause destroy of the PH domain (AA 951-1085) and serious damage to the function of IQSEC2 protein. Analysis with UCSF chimera software suggested that the c.3163C>T (p.Arg1055*) variant can induce serious damages to the secondary structures of IQSEC2 protein, causing loss of its function. CONCLUSION The patient's condition may be attributed to the de novo nonsense variant c.3163C>T (p.Arg1055*) of the IQSEC2 gene.

OBJECTIVE: To explore the molecular basis for a child featuring with Floating-Harbor syndrome. METHODS: The 2-year-and-8-month-old child presented with retarded growth and language development. Genomic DNA was extracted from peripheral blood samples from the child and his parents with informed consent and subjected to whole exome sequencing. Suspected variants were verified by Sanger sequencing. Pathogenecity of the variants were predicted by using bioinformatic tools. RESULTS: The child was found to carry a de novo frameshift variant c.7273dupA (p. Thr2425Asnfs*18) in the SRCAP gene. The variant was unreported previously and predicted to be pathogenic by MutationTaster. Analysis using HomoloGene system and MEGA software indicated position 2425 of the SRCAP protein to be highly conserved. Substitution of amino acid (Thr) at this position may cause destruction of three AT-hook domains (Amino acid 2857-2869, 2936-2948 and 3004-3016) and serious damage to the function of SRCAP protein. CONCLUSION The patient's condition may be attributed to the de novo frameshift variant c.7273dupA (p. Thr2425Asnfs*18) of the SRCAP gene. Above finding can facilitate diagnosis of Floating-Harbor syndrome among Chinese population.

OBJECTIVE: To identify potential mutation of PMM2 gene in an infant with congenital disorders of glycosylation type 1a (CDG-1a). METHODS: Genomic DNA was extracted from peripheral blood sample of the patient. All coding exons (exons 1-8) and splicing sites of the PMM2 gene were amplified with PCR. Potential variants were detected by direct sequencing of the PCR products and comparing the results against the ESP and SNP human gene databases. A protein BLAST system was employed to analyze cross-species conservation of the variants amino acid. A PubMed BLAST CD-search system was employed to identify functional domains damaged by variants of the PMM2 gene. Impact of potential variants was analyzed using software including PolyPhen-2 SIFT and Mutation Taster. Whole exome sequencing was used to identify additional variants of the PMM2 gene which may explain the condition of the patient. RESULTS: The child was found to carry compound heterozygous variants (c.458_462delTAAGA and c.395T>C) of the PMM2 gene, which were inherited respectively from his father and mother. The c.458_462delTAAGA has not been reported previously and may result in disruption of 10 functional domains within the PMM2 protein. The c.395T>C mutation has been recorded by a SNP database with frequency unknown. Both mutations were predicted as "probably damaging". Whole exome sequencing has identified no additional disease-causing variant which can explain the patient's condition. CONCLUSION The patient's condition may be attributed to the compound heterozygous variants c.458_462delTAAGA and c.395T>C of the PMM2 gene. Above results has facilitated molecular diagnosis for the patient.
Congenital Disorders of Glycosylation ; genetics ; Exons ; Humans ; Infant ; Mutation ; Phosphotransferases (Phosphomutases) ; genetics

OBJECTIVE: To detect potential mutations of HEXB gene in an infant with Sandhoff disease (SD). METHODS: Genomic DNA was extracted from peripheral blood sample of the infant. All coding exons (exons 1 to 14) and splicing sites of the HEXB gene were subjected to PCR amplification and direct sequencing.PubMed Protein BLAST system was employed to analyze cross-species conservation of the mutant amino acid. PubMed BLAST CD-search was performed to identify functional domains destroyed by thecandidate mutations. Impact of the mutations was analyzed with software including PolyPhen-2, Mutation Taster and SIFT. Whole-exome sequencing was carried out to identify additional mutations. RESULTS: The infant was found to carry compound heterozygous mutations c.1652G>A(p.Cys551Tyr) and c.1389C>G (p.Tyr463*) of the HEXB gene. The c.1389C>G (p.Tyr463*) mutation may lead to destruction of two functional domains in β subunit of the Hex protein. The c.1652G>A(p.Cys551Tyr) mutation, unreported previously,was predicted to be probably damaging by Bioinformatic analysis. CONCLUSION Compound heterozygous mutations c.1652G>A(p.Cys551Tyr) and c.1389C>G (p.Tyr463*) in the HEXB gene probably underlie the disease in this patient.
DNA Mutational Analysis ; Exons ; Heterozygote ; Humans ; Infant ; Mutation ; Polymerase Chain Reaction ; Sandhoff Disease ; genetics ; beta-Hexosaminidase beta Chain ; genetics

Objective: To detect potential mutations of HEXB gene in an infant with Sandhoff disease (SD). Methods: Genomic DNA was extracted from peripheral blood sample of the infant. All coding exons (exons 1 to 14) and splicing sites of the HEXB gene were subjected to PCR amplification and direct sequencing.PubMed Protein BLAST system was employed to analyze cross-species conservation of the mutant amino acid. PubMed BLAST CD-search was performed to identify functional domains destroyed by thecandidate mutations. Impact of the mutations was analyzed with software including PolyPhen-2, Mutation Taster and SIFT. Whole-exome sequencing was carried out to identify additional mutations. Results: The infant was found to carry compound heterozygous mutations c. 1652G>A(p.Cys551Tyr) and c. 1389C>G (p.Tyr463*) of the HEXB gene. The c. 1389C>G (p.Tyr463*) mutation may lead to destruction of two functional domains in β subunit of the Hex protein. The c. 1652G>A(p.Cys551Tyr)mutation, unreported previously, was predicted to be probably damaging by Bioinformatic analysis. Conclusion Compound heterozygous mutations c. 1652G>A(p.Cys551Tyr) and c. 1389C>G (p.Tyr463*) in the HEXB gene probably underlie the disease in this patient.