Familial advanced sleep phase syndrome (FASPS) is an autosomal dominant circadian rhythm variant; affected individuals are “morning larks” with a 4-hour advance of the sleep, temperature, and melatonin rhythms. Here we report localization of the FASPS gene near the telomere of chromosome 2q. A strong candidate gene (h Per2 ), a human homolog of the period gene in Drosophila , maps to the same locus. Affected individuals have a serine to glycine mutation within the casein kinase I ɛ (CKI ɛ ) binding region of hPER2, which causes hypophosphorylation by CKI ɛ in vitro. Thus, a variant in human sleep behavior can be attributed to a missense mutation in a clock component, hPER2, which alters the circadian period.
Introduction Chimeric Antigen Receptor T cells (CAR-T) therapy, e.g. B Cell Maturation Antigen (BCMA)-directed CAR-T has provided an encouraging modality for relapsed and refractory management of multiple myeloma (MM). However, a significant portion of patients still relapse with progressive disease after monospecific anti-BCMA CAR-T treatment. It has been demonstrated that CD19-directed CAR-T was effective in certain MM patients, likely due to CD19 expression on subsets of MM cells, and/or undetectable level of CD19 on MM cells. In addition, it has been reported that CD19 could express on the myeloma progenitor cells. To further improve the efficacy and to reduce relapse, we have designed a bispecific CAR-T targeting both BCMA and CD19. In addition to the conventionally-manufactured BCMA-CD19 CAR-T, the bispecific CAR-T was also successfully manufactured in our newly developed FasT CAR-T platform, which shortened the production time to one day. Here we report the results from pre-clinical studies and early results from the first-in-human clinical study. Methods The BCMA-CD19 bispecific CAR was constructed by linking BCMA and CD19 scFv, joined by a CD8 hinge, transmembrane domain, co-stimulatory domain and CD3. CAR-T cells were produced using either the conventional process (GC012) or the FasT CAR-T platform (GC012F). Peripheral blood (PB) mononuclear cells were obtained by leukapheresis either from healthy donors for the pre-clinical study or from patients for the clinical trial. T cells were isolated and used for CAR-T manufacturing. A xenograft mouse model was used to determine the efficacy in vivo. From March 2019 to July 2019, 5 adult relapsed/refractory MM patients (Age 50-59), who had previously received multiple lines of therapies, were enrolled (Table). Among them, 2 had extramedullary diseases. One patient did not receive lymphodepletion, and all other 4 patients received i.v. fludarabine and cyclophosphamide for 3 days. All patients received a single infusion of CAR-T cells, either at dose 1x106/Kg (DL1) (2 patients) or at dose 2x106/Kg (DL2) (3 patients), and the dose escalation is still ongoing. The endpoints of the exploratory trial were to evaluate the safety, feasibility, PK, and clinical efficacy of BCMA-CD19 bispecific CAR-T. Results In pre-clinical study, BCMA-CD19 bispecific CAR-T were very effective in killing CD19+ and/or BCMA + target cells including MM cell lines RPMI8226 and MM.1s (Fig 1). Increased IFN production and CD107a up-regulation were also observed. We demonstrated that BCMA-CD19 CAR-T completely eliminated BCMA+ MM cell line RPMI8226, MM.1s, and CD19+ ALL cell line Nalm6 in in vivo xenograft models. Additionally BCMA-CD19 CAR-T cells were shown to be more cytotoxic than single CAR-T both in vitro and in vivo. BCMA-CD19 CAR-T manufactured in the FasT CAR-T platform was more effective in eliminating MM in a xenograft model (Fig. 1). In the clinical study, the median observation time was 68 days (27-144 days up to 2019/7/30). Five patients were evaluated between 15-59 days post CAR-T infusion. Despite the relatively short disease evaluation time, all 5 patients responded to the treatment: 1 patient achieved sCR, 3 achieved VGPR and 1 achieved PR. Notably, although patient KM001 did not receive any pre-conditioning, however, the patient achieved sCR status on Day 15 and has maintained sCR up to now (129 days). CAR-T PK in the PB was monitored by qPCR and flow cytometry. The CAR-T proliferation peak was reached on Day 10 (D7-D14), and the median peak copy number was 34,039 (12,897-128,775) copies /ug DNA (Fig. 2). Remarkably, despite the encouraging clinical response to the CAR-T treatment, no severe adverse events were encountered during the observation period. Three patients experienced only grade 1 cytokine release syndrome (CRS) and no subject suffered from neurotoxicity of any level (Table). Conclusion Pre-clinical data demonstrated BCMA-CD19 CAR-T cells are effective in eliminating MM tumor cells both in vitro and in vivo. The first-in-human clinical trial also showed extraordinary safety profile and efficacy of BCMA-CD19 bispecific CAR-T in treating R/R MM. The long-term benefit and effect on relapse are being further studied. Bispecific CAR-T manufacturing on the FasT CAR-T platform is successful and has been shown to be more potent. A clinical study to evaluate safety and efficacy of FasT BCMA-CD19 CAR-T is ongoing. Disclosures No relevant conflicts of interest to declare.
Our objective was to dynamically observe changes in peripheral blood Th17, Treg cells, and interleukin (IL)-17 levels in HIV-1/AIDS patients before and after highly active antiretroviral therapy (HAART). The study design consisted of a randomized case-controlled study. A total of 33 HIV-1/AIDS patients were chosen to receive a HAART regimen and 30 healthy volunteers were assigned as controls. Peripheral blood Th17 and Treg cells were measured by flow cytometry before or 6 and 12 months after HAART therapy. The plasma IL-17 level was determined by ELISA. The percentage of Th17 cells to total CD4
HCV is capable of infecting and replicating in PBMCs, and HCVNS5 protein was expressed in PBMCs. The patients with minus strand HCV RNA in PBMCs showed a significantly lower 6-month sustained response to IFN, suggesting that minus-strand HCV RNA in PBMCs may be one of the factors influencing response to IFN therapy.
The aim of the present study was to investigate the association between cell-free DNA (cf-DNA) levels and clinicopathological characteristics of patients with ovarian cancer using a branched DNA (bDNA) technique, and to determine the value of quantitative cf-DNA detection in assisting with the diagnosis of ovarian cancer. Serum specimens were collected from 36 patients with ovarian cancer on days 1, 3 and 7 following surgery, and additional serum samples were also collected from 22 benign ovarian tumor cases, and 19 healthy, non-cancerous ovaries. bDNA techniques were used to detect serum cf-DNA concentrations. All data were analyzed using SPSS version 18.0. The cf-DNA levels were significantly increased in the ovarian cancer group compared with those of the benign ovarian tumor group and healthy ovarian group (P<0.01). Furthermore, cf-DNA levels were significantly increased in stage III and IV ovarian cancer compared with those of stages I and II (P<0.01). In addition, cf-DNA levels were significantly increased on the first day post-surgery (P<0.01), and subsequently demonstrated a gradual decrease. In the ovarian cancer group, the area under the receiver operating characteristic curve of cf-DNA and the sensitivity were 0.917 and 88.9%, respectively, which was higher than those of cancer antigen 125 (0.724, 75%) and human epididymis protein 4 (0.743, 80.6%). There was a correlation between the levels of serum cf-DNA and the occurrence and development of ovarian cancer in the patients evaluated. bDNA techniques possessed higher sensitivity and specificity than other methods for the detection of serum cf-DNA in patients exhibiting ovarian cancer, and bDNA techniques are more useful for detecting cf-DNA than other factors. Thus, the present study demonstrated the potential value for the use of bDNA as an adjuvant diagnostic method for ovarian cancer.
Since cyclin‑dependent kinases 4/6 (CDK4/6) play pivotal roles in cell cycle regulation and are overexpressed in human skin cancers, CDK4/6 inhibitors are potentially effective drugs for skin cancer. In the present study, we present a mixed computational and experimental study attempting to repurpose approved small‑molecule drugs as dual CDK4/6 inhibitors for skin cancer treatment. We performed structure‑based virtual screening using the docking software idock, targeting an ensemble of CDK4/6 structures. We identified and selected nine compounds with significant predicted scores, and evaluated their cytotoxic effects in vitro in A375 and A431 human skin cancer cell lines. Rafoxanide was found to exhibit the highest cytotoxic effects (IC50: 1.09 µM for A375 and 1.31 µM for A431 cells). Consistent with the expected properties of CDK4/6 inhibitors, rafoxanide significantly increased the G1 phase population. Notably, we revealed that rafoxanide specifically decreased the expression of CDK4/6, cyclin D, retinoblastoma protein (Rb) and the phosphorylation of CDK4/6 and Rb. Furthermore, the anticancer effect of rafoxanide was demonstrated in vivo in BALB/C nude mice subcutaneously xenografted with human skin cancer A375 cells. Rafoxanide (40 mg/kg, i.p.) exhibited significant antitumor activity, comparable to that of oxaliplatin (5 mg/kg, i.p.). The combined administration of rafoxanide and oxaliplatin produced a synergistic therapeutic effect. To the best of our knowledge, the present study is the first to indicate that rafoxanide inhibits CDK4/6 activity and is a potential candidate drug for the treatment of human skin cancer.
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