Leilei Zhang

Cubosomes, a product of nanobioengineering, are self-structured lipid nanoparticles that act like drug-loaded theranostic probes. Here, we describe a simple method for the preparation of combinatorial drug-loaded cubosomes with, proof-of-principle, therapeutic effect against cancer cells, along with diagnostic capabilities. Anticancer drugs cisplatin and paclitaxel were loaded in the cubosomes in combination. The cubosomes were coated with a layer of poly-Ɛ-lysine, which helped avoid the initial burst release of drug and allowed for a slow and sustained release for better efficacy. Cubosomes were imaged by transmission electron microscope, and their dispersion analyzed in vitro by differential scanning calorimetric and X-ray diffractogram studies. The microscopic images depicted spherical polyangular structures, which are easily distinguishable. The analyses revealed that the drug is uniformly dispersed all through the cubosomes. Further characterization was carried out by zeta-potential measurement, in vitro release, and entrapment efficiency studies. The in vitro studies established that the coating of cubosomes successfully reduced the burst release of drugs initially and confirmed a slow, sustained release over increased time. Comparative cytotoxicity of coated, uncoated, and blank cubosomes was evaluated, using human hepatoma HepG2 cell line, and the formulations were found to be entirely nontoxic, similar to the blank ones. The therapeutic efficiency of the cubosomes against HeLa cells was confirmed by the impedance measurement and fluorescent imaging. Furthermore, the reduction in impedance in cells treated with coated combinatorial cubosomes proved the impairment of HeLa cells, as confirmed by fluorescence microscopy.

Exosomes from human umbilical cord mesenchymal stem cells (hucMSC-Ex) have been suggested as novel nanomaterials for regenerative medicine. Here we explored the roles of hucMSC-Ex through regulating Yes-associated protein (YAP) in renal injury repair by using rat unilateral ureteral obstruction (UUO) models. Our study identified mechanical stress induced YAP nucleus expression and stimulated collagen deposition and interstitial fibrosis in the kidney. Then, infusion with hucMSC-Ex promoted YAP nuclear cytoplasmic shuttling and ameliorated renal fibrosis in UUO model. Interestingly, hucMSC-Ex delivered casein kinase 1δ (CK1δ) and E3 ubiquitin ligase β-TRCP to boost YAP ubiquitination and degradation. Knockdown of CK1δ and β-TRCP in hucMSC decreased the repairing effects of hucMSC-Ex on renal fibrosis. Our results suggest that hucMSC-Ex attenuates renal fibrosis through CK1δ/β-TRCP inhibited YAP activity, unveiling a new mechanism for the therapeutic effects of hucMSC-Ex on tissue injury and offering a potential approach for renal fibrosis treatment.

BACKGROUND: Long non-coding RNAs (lncRNAs) have been identified as important epigenetic regulators that play critical roles in human cancers. However, the regulatory functions of lncRNAs in tumorigenesis remains to be elucidated. Here, we aimed to investigate the molecular mechanisms and potential clinical application of a novel lncRNA, retinoblastoma associated transcript-1 (RBAT1), in tumorigenesis. METHODS: RBAT1 expression was determined by real-time PCR in both retinoblastoma (Rb) and bladder cancer (BCa) cell lines and clinical tissues. Chromatin isolation using RNA purification (ChIRP) assays were performed to identify RBAT1-interacting proteins. Patient-derived xenograft (PDX) retinoblastoma models were established to test the therapeutic potential of RBAT1-targeting GapmeRs. RESULTS: Here, we found that RBAT1 expression was significantly higher in Rb and BCa tissues than that in adjacent tissues. Functional assays revealed that RBAT1 accelerated tumorigenesis both in vitro and in vivo. Mechanistically, RBAT1 recruited HNRNPL protein to E2F3 promoter, thereby activating E2F3 transcription. Therapeutically, GapmeR-mediated RBAT1 silencing significantly inhibited tumorigenesis in orthotopic xenograft retinoblastoma models derived from Rb cell lines and Rb primary cells. CONCLUSIONS: RBAT1 overexpression upregulates a known oncogene, E2F3, via directly recruiting HNPNPL to its promoter and cis-activating its expression. Our finding provides a novel mechanism of lncRNA biology and provides potential targets for diagnosis and treatment of Rb and BCa.

Osteoporosis, caused by a relative increase of bone resorption over bone formation, is characterized by decreased bone mass and bone strength, resulting in an increased incidence of bone fractures, which often leads to further disability and early mortality in the elderly due to impaired bone healing ability. The majority of therapeutics currently used in clinics for the treatment of osteoporosis are antiresorptive agents that exert their clinical effect by decreasing the rate of bone resorption. However, strategies solely aimed at antiresorption have limited therapeutic efficacy in restoring bone remodeling balance and enhancing osteoporotic fracture healing. Here, we report that miR-26a plays a critical role in modulating bone formation during osteoporosis. We found that miR-26a treatment could effectively improve the osteogenic differentiation capability of mesenchymal stem cells isolated from littermate-derived ovariectomized osteoporotic mice both in vitro and in vivo. MiR-26a exerts its effect by directly targeting Tob1, the negative regulator of BMP/Smad signaling pathway by binding to the 3′-untranslated region and thus repressing Tob1 protein expression. Our findings indicate that miR-26a may be a promising therapeutic candidate to enhance bone formation in treatment of osteoporosis and to promote bone regeneration in osteoporotic fracture healing. Osteoporosis, caused by a relative increase of bone resorption over bone formation, is characterized by decreased bone mass and bone strength, resulting in an increased incidence of bone fractures, which often leads to further disability and early mortality in the elderly due to impaired bone healing ability. The majority of therapeutics currently used in clinics for the treatment of osteoporosis are antiresorptive agents that exert their clinical effect by decreasing the rate of bone resorption. However, strategies solely aimed at antiresorption have limited therapeutic efficacy in restoring bone remodeling balance and enhancing osteoporotic fracture healing. Here, we report that miR-26a plays a critical role in modulating bone formation during osteoporosis. We found that miR-26a treatment could effectively improve the osteogenic differentiation capability of mesenchymal stem cells isolated from littermate-derived ovariectomized osteoporotic mice both in vitro and in vivo. MiR-26a exerts its effect by directly targeting Tob1, the negative regulator of BMP/Smad signaling pathway by binding to the 3′-untranslated region and thus repressing Tob1 protein expression. Our findings indicate that miR-26a may be a promising therapeutic candidate to enhance bone formation in treatment of osteoporosis and to promote bone regeneration in osteoporotic fracture healing.