Exploration of the pathogenesis for a SRY-negative male with 46,XX disorder of sex development / 中华医学遗传学杂志

OBJECTIVE@#To explore the pathogenesis for a SRY-negative male with 46,XX disorder of sex development (DSD).@*METHODS@#Peripheral blood samples of the patient and his family members were subjected to chromosomal karyotyping, routine PCR, real-time fluorescence quantitative PCR, whole exome sequencing and whole genome sequencing. The data was analyzed with NextGENe software.@*RESULTS@#Both the proband and his brother presented a 46,XX karyotype with negative SRY gene, while their father presented normal phenotype and karyotype with positive SRY gene. No pathogenic variant associated with sex development was detected by whole exome sequencing, while a 243 kb duplication was detected by whole genome sequencing in the 5' upstream region of the SOX9 gene in the proband, his brother and father. The same duplication was not found in his sister and mother.@*CONCLUSION@#The 243 kb duplication at the 5' upstream of the SOX9 gene may predispose to the 46,XX DSD in this family. It is speculated that there exist an unknown core regulatory element in the upstream of the SOX9, and its duplication may trigger expression of SOX9 and initiate testicular differentiation in the absence of SRY gene.

Parsing regulatory DNA: general tasks, techniques, and the PhyloGibbs approach.

In this review, we discuss the general problem of understanding transcriptional regulation from DNA sequence and prior information. The main tasks we discuss are predicting local regions of DNA, cis-regulatory modules (CRMs) that contain binding sites for transcription factors (TFs), and predicting individual binding sites. We review various existing methods, and then describe the approach taken by PhyloGibbs, a recent motif-finding algorithm that we developed to predict TF binding sites, and PhyloGibbs-MP, an extension to PhyloGibbs that tackles other tasks in regulatory genomics, particularly prediction of CRMs.

Molecular mechanics simulation of the interaction of estrogen receptor with estrogen regulatory element.

A model for the interaction of 31 amino acid fragment (protein) from DNA binding domain of human estrogen receptor (hER) with a five base pair DNA sequence 5'GGTCA 3' from estrogen regulatory element (ERE) has been obtained using a step-wise procedure based on structural data on model peptides, DNA binding domain of hER, steric constrains imposed by tetrahedral coordination of the Cys sulphurs with zinc ion and classical secondary structural elements. Structure of the protein as well as its complex with DNA is obtained by energy minimization followed by refinement by molecular mechanics. The complex is stabilized by H-bonds between Lys22, Lys26 and Arg27 with DNA bases G2, T3 and T6. Lys22 also made H-bond with the backbone of G2. The backbone of Cys18 H-bonded with N7 of G1. DNA was in distorted B form and showed evidence of protein-induced conformational changes.