Development and validation of real-time recombinase polymerase amplification-based assays for detecting HPV16 and HPV18 DNA.

IMPORTANCE: HPV DNA screening is an effective approach for the prevention of cervical cancer. The novel real-time recombinase polymerase amplification-based HPV detection systems we developed constitute an improvement over the HPV detection methods currently used in clinical practice and should help to extend cervical cancer screening in the future, particularly in point-of-care test settings.

Development and Characterization of Recombinase-Based Isothermal Amplification Assays (RPA/RAA) for the Rapid Detection of Monkeypox Virus.

Monkeypox is a zoonotic disease caused by monkeypox virus (MPXV), in which outbreaks mainly occurred in West and Central Africa, with only sporadic spillovers to countries outside Africa due to international travel or close contact with wildlife. During May 2022, multiple countries in Europe, North and South America, Australia, Asia, and Africa reported near-simultaneous outbreaks of MPXV, the first time that patient clusters were reported over such a large geographical area. Cases have no known epidemiological links to MPXV-endemic countries in West or Central Africa. Real-time PCR is currently the gold standard for MPXV diagnostics, but it requires trained laboratory personnel and specialized equipment, and results can only be obtained after several hours. A rapid and simple-to-operate point-of-care diagnostic test for MPXV is crucial for limiting its spread and controlling outbreaks. Here, three recombinase-based isothermal amplification assays (RPA/RAA) for the rapid detection of MPXV isolates were developed. These three assays target the MPXV G2R gene, and the limit of detection for these systems is approximately 100 copies of DNA per reaction. The assays were found to be specific and non-cross reactive against other pox viruses, such as vaccinia virus, and the results can be visualized within 20-30 min. The assays were validated with DNA extracted from 19 clinical samples from suspected or confirmed MPXV patients from Central Africa, and found to be consistent with findings from traditional qPCR. These results provide a solid platform for the early diagnosis of potential MPXV cases, and will help with the control and prevention of current and future outbreaks.

Circadian clock protein CRY1 prevents paclitaxel­induced senescence of bladder cancer cells by promoting p53 degradation.

Bladder cancer is a common tumor type of the urinary system, which has high levels of morbidity and mortality. The first­line treatment is cisplatin­based combination chemotherapy, but a significant proportion of patients relapse due to the development of drug resistance. Therapy­induced senescence can act as a 'back­up' response to chemotherapy in cancer types that are resistant to apoptosis­based anticancer therapies. The circadian clock serves an important role in drug resistance and cellular senescence. The aim of the present study was to investigate the regulatory effect of the circadian clock on paclitaxel (PTX)­induced senescence in cisplatin­resistant bladder cancer cells. Cisplatin­resistant bladder cancer cells were established via long­term cisplatin incubation. PTX induced apparent senescence in bladder cancer cells as demonstrated via SA­ß­Gal staining, but this was not observed in the cisplatin­resistant cells. The cisplatin­resistant cells entered into a quiescent state with prolonged circadian rhythm under acute PTX stress. It was identified that the circadian protein cryptochrome1 (CRY1) accumulated in these quiescent cisplatin­resistant cells, and that CRY1 knockdown restored PTX­induced senescence. Mechanistically, CRY1 promoted p53 degradation via increasing the binding of p53 with its ubiquitin E3 ligase MDM2 proto­oncogene. These data suggested that the accumulated CRY1 in cisplatin­resistant cells could prevent PTX­induced senescence by promoting p53 degradation.