High performance of a novel antigen detection test on nasopharyngeal specimens for diagnosing SARS-CoV-2 infection.

The severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) pandemic has become a major public health issue worldwide. Developing and evaluating rapid and easy-to-perform diagnostic tests is a high priority. The current study was designed to assess the diagnostic performance of an antigen-based rapid detection test (COVID-VIRO®) in a real-life setting. Two nasopharyngeal specimens of symptomatic or asymptomatic adult patients hospitalized in the Infectious Diseases Department or voluntarily accessing the COVID-19 Screening Department of the Regional Hospital of Orléans, France, were concurrently collected. The diagnostic specificity and sensitivity of COVID VIRO® results were compared to those of real-time reverse-transcriptase quantitative polymerase chain reaction (RT-qPCR) results. A subset of patients underwent an additional oropharyngeal and/or saliva swab for rapid testing. A total of 121 patients confirmed to be infected and 127 patients having no evidence of recent or ongoing infection were enrolled for a total of 248 nasopharyngeal swab specimens. Overall, the COVID-VIRO® sensitivity was 96.7% (CI, 93.5%-99.9%). In asymptomatic patients, symptomatic patients having symptoms for more than 4 days and those with an RT-qPCR cycle threshold value ≥ 32, the sensitivities were 100%, 95.8%, and 91.9%, respectively. The concordance between RT-qPCR and COVID VIRO® rapid test results was 100% for the 127 patients with no SARS-CoV-2 infection. The COVID-VIRO® test had 100% specificity and sensitivity greater than 95%, which are better than the recommendations set forth by the WHO (specificity ≥ 97%-100%, sensitivity ≥ 80%). These rapid tests may be particularly useful for large-scale screening in emergency departments, low-resource settings, and airports.

Rescue of preimplantatory egg development and embryo implantation in prolactin receptor-deficient mice after progesterone administration.

PRL, a hormone secreted essentially by the pituitary and other extrapituitary sources such as decidua, has been attributed regulatory roles in reproduction and cell growth in mammals. These effects are mediated by a membrane PRL receptor belonging to the cytokine receptor superfamily. Null mutation of the PRL receptor gene leads to female sterility due to a severely compromised preimplantation development and a complete failure of the implantation of the few embryos reaching the blastocyst stage, strongly implicating PRL in the maternal control of implantation. We measured the hormonal status of -/- mice, which confirmed that the corpus luteum is unable to produce progesterone. Progesterone administration to -/- mice completely rescued the development of preimplantatory eggs and embryo implantation. Pregnancy could be maintained to 19.5 days postcoitum, with about 22% of resulting embryos reaching adulthood. Although progesterone and perhaps PRL appear to facilitate mouse preembryo development throughout the preimplantation stages, other factors as well as a possible direct effect of PRL on the uterus are probably necessary to fully maintain pregnancy. Finally, reduced ductal side-branching in the mammary gland can be rescued by progesterone treatment, but females exhibit reduced alveolar formation. Our model establishes the PRL receptor as a key regulator of reproduction and provides novel insights into the function of lactogenic hormones and their receptor.

From the molecular biology of prolactin and its receptor to the lessons learned from knockout mice models.

Prolactin (PRL), a polypeptide hormone secreted mainly by the pituitary and, to a lesser extent, by peripheral tissues, affects more physiological processes than all other pituitary hormones combined since it is involved in > 300 separate functions in vertebrates. Its main actions are related to lactation and reproduction. The initial step of PRL action is the binding to a specific membrane receptor, the PRLR, which belongs to the class 1 cytokine receptor superfamily. PRL-binding sites have been identified in a number of tissues and cell types in adult animals. Signal transduction by this receptor is mediated, at least in part, by two families of signaling molecules: Janus tyrosine kinases and signal transducers and activators of transcription (STATs). Disruption of the PRLR gene has provided a new mouse model with which to identify actions directly associated with PRL or any other PRLR ligands, such as placental lactogens. To date, several different phenotypes have been analyzed and are briefly described in this review. Coupled with the SAGE technique, this PRLR knockout model is being used to qualitatively and quantitatively evaluate the expression pattern of hepatic genes in two physiological situations: transcriptomes corresponding to livers from both wild type and PRLR KO mice are being compared, and following statistical analyses, candidate genes presenting a differential profile will be further characterized. Such a new approach will undoubtedly open future avenues of research for PRL targets. To date, no pathology linked to any mutation in the genes encoding PRL or its receptor have been identified. The development of genetic models provides new opportunities to understand how PRL can participate to the development of pathologies throughout life, as for example the initiation and progression of breast cancer.

Mouse prolactin receptor gene: genomic organization reveals alternative promoter usage and generation of isoforms via alternative 3'-exon splicing.

In rodents, the prolactin receptor is expressed as multiple isoforms with identical extracellular and membrane-proximal region sequences but with different 3' sequences, encoding different cytoplasmic regions, and different 5' untranslated region (UTR) sequences. These divergent sequences could be the result of multiple prolactin receptor genes or of a single gene which displays alternative promoter usage and 3'-exon splicing. To investigate the molecular basis for these observations, we have cloned and determined the organization of the mouse prolactin receptor gene. Genomic DNA cloning allowed the arrangement of promoters 1A, 1B, and 1C to be determined. 5'-RACE-PCR from mouse liver identified two novel 5' prolactin receptor sequences, indicating that the gene has at least five different promoters, four of which are active in liver. The remaining nonvariable 5' UTR is encoded by a separate exon (exon 2), while a further 11 coding exons follow, the last 4 of which are alternatively spliced to produce the four isoforms of the receptor. Functional units were found to be exon specific. Thus, the multiple prolactin receptor isoforms are the product of a single gene of >120 kb which displays multiple promoter usage and 3'-exon splicing.