ABSTRACT
OBJECTIVE: We describe the clinical and genetic characteristics of fetuses and infants diagnosed with tuberous sclerosis complex (TSC) in our centre, prenatally or neonatally, for a better understanding of the benefits of early screening. METHODS: In this retrospective study, we analysed the data on one fetus and nine infants with a definitive TSC diagnosis by genetic criteria (five patients carrying TSC1 variants and 5 patients carrying TSC2 variants). We explored the differences between phenotypes of patients carrying TSC1 and TSC2 pathogenic variants. RESULTS: The most common initial presenting features of TSC were cardiac rhabdomyomas (CRs) that were observed in nine out of ten patients. The most common postnatal features, besides CR, were presented with subependymal nodules-in five patients, and hypomelanotic macules-in four patients. In total, 10 variants causing TSC were detected in this study, including 5 novel variants. We demonstrated that patients with TSC2 variants had earlier onset and more severe clinical manifestations compared with patients carrying TSC1 variants. CONCLUSION: Early diagnosis of TSC improves genetic counselling and perinatal management.
ABSTRACT
OBJECTIVES: The aim of this study was to establish maternal contribution to false positive noninvasive prenatal DNA screening (NIPS) results and develop the method to distinguish maternal and fetal origin of high-risk monosomy X NIPS calls including mosaic maternal cases. METHOD: A total of 906 women carrying singleton pregnancies have been recruited. Maternal plasma DNA semiconductor massive parallel sequencing was performed to detect common aneuploidies. For the case of high monosomy X risk call, analysis method to distinguish fetal and maternal monosomy X has been additionally applied. RESULTS: According to NIPS results, 18 patients had a high risk of fetal monosomy X. In 11 (61%) cases, fetal aneuploidy was confirmed by karyotyping. Other 7 cases were false positives. In 3 out of 7 cases, additional analysis based on in silico size selection was allowed to assume maternal monosomy X. In these cases, fluorescence in situ hybridization analysis confirmed mosaic monosomy X in maternal blood cells. CONCLUSION: The prevalence of mosaic monosomy X karyotype is 0.3% (3/906)-10 times higher than published before. Additional in silico size-selection and data analysis increases PPV for monosomy X from 61% to 73% for studied population.
Subject(s)
Maternal Serum Screening Tests/methods , Mosaicism , Turner Syndrome/diagnosis , Adult , Computer Simulation , False Positive Reactions , Female , Humans , Pregnancy , Sequence Analysis, DNAABSTRACT
We have developed a plasmid test system to study recombination in vitro and in mammalian cells in vivo, and to analyze the possible role of DNA topoisomerase II. The system is based on a plasmid construct containing an inducible marker gene ccdB ("killer" (KIL) gene) whose product is lethal for bacterial cells, flanked by two different potentially recombinogenic elements. The plasmids were subjected to recombinogenic conditions in vitro or in vivo after transient transfection into COS-1 cells, and subsequently transformed into E. coli which was then grown in the presence of the ccdB gene inducer. Hence, all viable colonies contained recombinant plasmids since only recombination between the flanking regions could remove the KIL gene. Thus, it was possible to detect recombination events and to estimate their frequency. We found that the frequency of topoisomerase II-mediated recombination in vivo is significantly higher than in a minimal in vitro system. The presence of VM-26, an inhibitor of the religation step of the topoisomerase II reaction, increased the recombination frequency by 60%. We propose that cleavable complexes of topoisomerase II are either not religated, triggering error-prone repair of the DNA breaks, or are incorrectly religated resulting in strand exchange. We also studied the influence of sequences known to contain preferential breakpoints for recombination in vivo after chemotherapy with topoisomerase II-targeting drugs, but no preferential stimulation of recombination by these sequences was detected in this non-chromosomal context.
Subject(s)
Recombination, Genetic , Topoisomerase II Inhibitors , Animals , Bacterial Proteins/genetics , Bacterial Toxins/genetics , Base Sequence , COS Cells , Chlorocebus aethiops , DNA Replication , DNA Topoisomerases, Type II/metabolism , Escherichia coli/genetics , Gene Rearrangement , Genes, Bacterial , Humans , In Vitro Techniques , Models, Genetic , Nucleosomes/metabolism , Plasmids/genetics , Transformation, GeneticABSTRACT
Chromosomal rearrangements are common causes of cancer. In the majority of cases, the malignancy is induced via an altered transcription factor. The breakpoints of such translocations are often mysteriously tightly clustered in the genome. Even more surprisingly, such breakpoint clusters often contain specific genomic elements, such as topoisomerase II consensus sites, nuclear matrix attachment regions, etc. In this review, we discuss the common idea of breakpoints being induced by chromatin structure. We also touch on the question of whether the structure of corresponding proteins is related to the positions of breakpoints. Finally, we refer to recent works on chromosome territories and their distribution in the interphase nucleus.