ABSTRACT
Background: Proline dehydrogenase (PRODH) encodes a mitochondrial protein that catalyzes the first step of proline degradation and is related to angiogenesis. Angiogenesis is a critical process in the development and progression of tumors, including lung adenocarcinoma (LUAD), as tumor growth and metastasis are dependent on angiogenesis. The mitochondria and their associated genes thus play a vital role in tumor therapy. However, the specific mechanism of action of PRODH in LUAD is not yet clear. The aim of this study was thus to clarify the specific mechanism of PRODH as a mitochondrial gene in LUAD. Methods: This study identified genes related to mitochondria and angiogenesis in LUAD. Based on the high and low expression of the genes in LUAD, we grouped them and conducted relevant bioinformatics analysis on the differentially expressed genes. Results: We screened genes related to mitochondria and angiogenesis in the differential genes of LUAD, and identified PRODH as a gene of interest. The expression of PRODH was associated with the survival outcome of patients with LUAD. Additionally, PRODH was found to be associated with immune cell infiltration and tumor mutations. Conclusions: Mitochondrial metabolism and angiogenesis may have significant therapeutic ramifications for patients with LUAD. We identified PRODH, a gene exerts a dual role in cancer. PRODH may be a prospective therapeutic target in LUAD and a possible diagnostic and prognostic biomarker associated with immune infiltration and tumor mutational burden.
ABSTRACT
The nano-delivery system with a dual biomimetic effect can penetrate deeper in tumor microenvironments (TMEs) and release sufficient antitumor drugs, which has attracted much attention. In this study, we synthesized erythrocyte-like mesoporous silica nanoparticles (EMSNs) as the core loaded with doxorubicin (DOX) and coated them with calcium phosphate (CaP) and erythrocyte membrane (EM) to obtain DOX/EsPMs. The transmission electron microscopy (TEM), fluorescent co-localization and protein bands of SDS-PAGE were used to confirm the complete fabrication of EsPMs. The EsPMs with erythrocyte-like shape exhibited superior penetration ability in in vitro diffusion and tumor-sphere penetration experiments. Intracellular Ca2+ and ROS detection experiments showed that the CaP membranes of EsPMs with pH-sensitivity could provide Ca2+ continuously to induce reactive oxide species' (ROS) generation in the TME. The EM as a perfect "camouflaged clothing" which could confuse macrophagocytes into prolonging blood circulation. Hemolysis and non-specific protein adsorption tests proved the desirable biocompatibility of EsPMs. An in vivo pharmacodynamics evaluation showed that the DOX/EsPMs group had a satisfactory tumor-inhibition effect. These advantages of the nano-erythrocytes suggest that by modifying the existing materials to construct a nano-delivery system, nanoparticles will achieve a biomimetic effect from both their structure and function with a facilitated and sufficient drug release profile, which is of great significance for antitumor therapy.
ABSTRACT
Temozolomide is a first-line therapeutic drug for glioblastoma (GBM), and it has a low solubility, short biological half-life, and resistance to drug limits in clinical applications. Therefore, it is necessary to find more effective anti-tumor drugs to overcome drug resistance and enhance its anti-glioma activity. We therefore used n-butanol, n-hexanol, n-octanol, 1-dodecanol and 1-hexadecanol to synthesize a series of temozolomide ester compounds (TMZEs) and then investigated their physicochemical properties and anti-glioma efficacy. Our results showed that TMZEs had a higher lipophilicity compared to TMZ and could stably exist in plasma and brain homogenates. TMZEs had significantly increased cytotoxicity and cellular uptake in C6 glioma cells as chain lengths increased. Additionally, the IC50 of TMZ-16E towards TMZ-resistant cells (T98G) was 85.9-fold lower than that of TMZ (p < 0.001), and Western blot results demonstrated that TMZ-16E could significantly reduce the expression of O6-methylguanine-DNA-methyltransferase (MGMT). The in vivo anti-glioma efficacy of TMZ-16E were then investigated in orthotopic and subcutaneous GBM models. TMZ-16E prolonged the survival time to 35 days in orthotopic glioma bearing rats, which was 1.94-fold longer than the survival time of rats treated with TMZ, and TMZ-16E increased tumor cell apoptosis based on TUNEL staining. Moreover, TMZ-16E (50 mg/kg) noticeably slowed the growth of T98G subcutaneous tumors by down-modulating MGMT expression in subcutaneous GBM-bearing mice, indicating that TMZ-16E could effectively reverse drug resistance. In conclusion, TMZEs improved the lipophilicity and stability of these drugs. Especially, TMZ-16E could reverse drug resistance and improve therapeutic effects of TMZ, which has clinical application potential for GBM treatment.
