Regulation of adipocyte differentiation is an important process in the control of adipose tissue development. So far, adipogenesis has been investigated through the use of various experimental models. In this work, we used human mesenchymal stem cells (hMSCs) obtained from amniotic fluid (AF) as an alternative model more representative of what naturally happens in vivo. In our opinion, these hMSCs are still not influenced by differentiation stimuli and could act in a way more correspondent to the physiological process of adipogenesis, representing also an ethically acceptable alternative to totipotent human embryonic stem cells (ES). Adipocyte differentiation was monitorated following the expressions of key genes. We measured the expression levels of PPARgamma2, PPARgamma-C1alpha, UCP-1, adipsin, and leptin genes using quantitative real-time PCR. We tested our experimental model with two different media. Understanding in vivo adipogenesis mechanisms will shed light on the pathophysiology of many diseases.
Low-risk pregnancies that developed early-onset FGR had lower cfDNA fetal fractions than did the matched controls. This result is consistent with the placental dysfunction typical of early-onset FGR. For possible clinical use, the cfDNA fetal fraction would yield a better predictive value if adjusted for maternal weight, since maternal weight affects both cfDNA fetal fraction and the occurrence of FGR.
These data represent a step forward in the screening of CHDs. Additional studies are needed to detect more mRNAs with discriminant ability and to move the first trimester screening.
The chloride channel 2 (CLCN2) gene codes for a protein organized in N- and C-terminal regions with regulatory functions and a transmembrane region which forms the ring of the pore. Mutations in the gene have previously been described in patients with idiopathic familial epilepsy. In this study we looked for new isoforms of CLCN2 and we estimated expression levels by real time PCR in brain tissue containing epileptic foci. Samples used in this study were first analyzed and selected to exclude mutations in the coding region of the gene. Four isoforms (skipping exons 3, 16, 22 and 6/7) were identified and quantified by Real Time PCR and compared with total expression of the gene. Expression of the region common to all CLCN2 isoforms was 50% less in epilepsy-associated brain tissue than in controls. The ratio of the various isoforms was slightly greater in epileptic than control tissue. The greatest difference was recorded in the temporal lobe for the isoform with skipped exon 22. Analysis of these isoforms in brain tissue containing epileptic foci suggests that CLCN2 could be implicated in epilepsy, even in the absence of mutations.
Genetic testing availability in the health care system is rapidly increasing, along with the diffusion of next-generation sequencing (NGS) into diagnostics. These issues make imperative the knowledge-drive optimization of testing in the clinical setting. Time estimations of wet laboratory procedure in Italian molecular laboratories offering genetic diagnosis were evaluated to provide data suitable to adjust efficiency and optimize health policies and costs. A survey was undertaken by the Italian Society of Human Genetics (SIGU). Forty-two laboratories participated. For most molecular techniques, the most time-consuming steps are those requiring an intensive manual intervention or in which the human bias can affect the global process time-performances. For NGS, for which the study surveyed also the interpretation time, the latter represented the step that requiring longer times. We report the first survey describing the hands-on times requested for different molecular diagnostics procedures, including NGS. The analysis of this survey suggests the need of some improvements to optimize some analytical processes, such as the implementation of laboratory information management systems to minimize manual procedures in pre-analytical steps which may affect accuracy that represents the major challenge to be faced in the future setting of molecular genetics laboratory.
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