Silencing of integrin subunit α3 inhibits the proliferation, invasion, migration and autophagy of esophageal squamous cell carcinoma cells

ITGA3 participates in the pathogenesis of recurrent spontaneous abortion by downregulating ULK1-mediated autophagy to inhibiting trophoblast function

Recurrent spontaneous abortion (RSA) is a significant challenge encountered by couples of reproductive ages, with inadequate trophoblast invasion identified as a primary factor in RSA pathogenesis. However, the precise molecular mechanisms through which trophoblast cell dysfunction leads to RSA remain incompletely understood. Research has highlighted the critical role of integrins in embryo implantation and development. Although integrin α-3 (ITGA3) is recognized for its promotion of invasion in cancer cells, its involvement in miscarriage remains poorly characterized. This investigation initially assessed ITGA3 expression in villous tissues obtained from patients with RSA and patients with induced abortion. The findings demonstrated a notable reduction in ITGA3 levels in the villous tissues of patients with RSA compared with the control group. Subsequent in vitro analyses indicated that ITGA3 knockdown inhibited the migration, invasion, and proliferation of trophoblast cells. Through RNA sequencing and subsequent experimentation, it was revealed that ITGA3 regulated Unc51-like kinase 1 (ULK1)-mediated autophagy to influence trophoblast cell invasion, migration, and proliferation. Furthermore, utilizing a miscarriage animal model, the diminished expression of ITGA3 and ULK1 in the placentas of RSA mice was confirmed. In conclusion, the study findings suggest that the downregulation of ITGA3 suppresses ULK1 expression, consequently impeding autophagy to initiation and impeding trophoblast cell invasion and migration, thereby contributing to the pathological progression of RSA.NEW & NOTEWORTHY There is a strong correlation between the reduced expression of ITGA3 in villous tissues and RSA. ITGA3 facilitates the expression of ULK1, thereby promoting autophagy formation and elevating autophagy levels in trophoblast cells. Consequently, this enhances the invasion and migration abilities of trophoblast cells.

Integrin α3β1 Is Not Required for Onset of Dysplasia in Genetic Model of Colon Cancer but Promotes Motility of Colon Cancer Cells

BACKGROUND/OBJECTIVES

The progression of colorectal cancer through clinically and histopathologically well-defined stages is driven by specific mutations that activate oncogenes or inactivate tumor-suppressor genes. In addition, pre-cancerous/cancer cells respond to cues from the tissue microenvironment that support tumorigenesis and progression, many of which are transmitted through integrin receptors for the extracellular matrix. Integrin α3β1 has pro-tumorigenic/pro-metastatic roles in many cancers, but it also has suppressive roles in some cancers or at specific stages of progression, indicating that its potential value as a therapeutic target cannot be extrapolated across cancer types or stages. In this study, we investigated roles for α3β1 in colorectal cancer using cellular and genetic models that represent different stages.

METHODS

We generated mice with colon-specific α3 knockout in a tamoxifen-inducible model of KRAS-mutated colorectal cancer to assess the effects of α3β1 ablation on early dysplasia. We also used siRNA to suppress α3β1 in human colorectal cancer cells, then assessed effects on motility and invasion in vitro.

RESULTS

Genetic deletion of α3β1 in the colon did not alter dysplasia in mice predisposed to KRAS-mutated colorectal cancer, and it was accompanied by an increase in the colocalization of α6 integrin with laminin-332 (a matrix ligand for both integrins), suggesting functional compensation. However, suppression of α3β1 caused an approximately 40% to 60% reduction in the motility/invasion of human colorectal cancer cells.

CONCLUSIONS

Our findings that α3β1 is not required for pre-cancerous dysplasia but promotes colorectal cancer cell motility/invasion indicate an important role for pro-migratory functions of this integrin at later stages of progression when cells invade from the primary tumor, suggesting that strategies to target α3β1 in colorectal cancer should be aimed at distinct stages of disease progression.

A prognostic model for anoikis-related genes in pancreatic cancer

Anoikis, a distinct form of programmed cell death, is crucial for both organismal development and maintaining tissue equilibrium. Its role extends to the proliferation and progression of cancer cells. This study aimed to establish an anoikis-related prognostic model to predict the prognosis of pancreatic cancer (PC) patients. Gene expression data and patient clinical profiles were sourced from The Cancer Genome Atlas (TCGA-PAAD: Pancreatic Adenocarcinoma) and the International Cancer Genome Consortium (ICGC-PACA: Pancreatic Ductal Adenocarcinoma). Non-cancerous pancreatic tissue gene expression data were obtained from the Genotype-Tissue Expression (GTEx) project. The R package was used to construct anoikis-related PC prognostic models, which were later validated with the ICGC-PACA database. Survival analyses demonstrated a poorer prognosis for patients in the high-risk group, consistent across both TCGA-PAAD and ICGC-PACA datasets. A nomogram was designed as a predictive tool to estimate patient mortality. The study also analyzed tumor mutations and immune infiltration across various risk groups, uncovering notable differences in tumor mutation patterns and immune landscapes between high- and low-risk groups. In conclusion, this research successfully developed a prognostic model centered on anoikis-related genes, offering a novel tool for predicting the clinical trajectory of PC patients.

Identifying the prognosis implication, immunotherapy response prediction value, and potential targeted compound inhibitors of integrin subunit α3 (ITGA3) in human cancers

The integrin subunit α3 (ITGA3) is a member of the integrin alpha chain protein family, which could promote progression, metastasis, and invasion in some cancers. Still, its function in the tumor microenvironment (TME), cancer prognosis, and immunotherapy remains unclear. A multifaceted analysis of ITGA3 in pan-cancer utilizing various databases and online web tools revealed ITGA3 was aberrantly expressed in tumor tissues and upregulated in most cancers, which may be related to ITGA3 genomic alterations and methylation modification. In addition, ITGA3 was significantly correlated with the poor or better prognosis of cancer patients, immune-related pathways in hallmark, immune infiltration, and immune checkpoints, revealing a biological function of ITGA3 in the tumor progression, tumor microenvironment, and tumor immunity. We also found that ITGA3 could predict the response to tumor immunotherapy based on cytokine-treated samples and immunotherapy cohorts. ITGA3 may participate in shaping and regulating the tumor microenvironment to affect the tumor immune response, which was a promising immunotherapy response predictive biomarker and potential therapeutic target to work synergistically with cancer immunotherapy to boost the response and efficacy. Finally, potential targeted compound inhibitors and sensitive drugs were screened using databases ConnectivityMap (CMap) and CellMiner, and AutoDock Tools was used for molecular docking.

Advanced Bioinformatics Analysis and Genetic Technologies for Targeting Autophagy in Glioblastoma Multiforme

As the most malignant primary brain tumor in adults, a diagnosis of glioblastoma multiforme (GBM) continues to carry a poor prognosis. GBM is characterized by cytoprotective homeostatic processes such as the activation of autophagy, capability to confer therapeutic resistance, evasion of apoptosis, and survival strategy even in the hypoxic and nutrient-deprived tumor microenvironment. The current gold standard of therapy, which involves radiotherapy and concomitant and adjuvant chemotherapy with temozolomide (TMZ), has been a game-changer for patients with GBM, relatively improving both overall survival (OS) and progression-free survival (PFS); however, TMZ is now well-known to upregulate undesirable cytoprotective autophagy, limiting its therapeutic efficacy for induction of apoptosis in GBM cells. The identification of targets utilizing bioinformatics-driven approaches, advancement of modern molecular biology technologies such as clustered regularly interspaced short palindromic repeats (CRISPR)—CRISPR-associated protein (Cas9) or CRISPR-Cas9 genome editing, and usage of microRNA (miRNA)-mediated regulation of gene expression led to the selection of many novel targets for new therapeutic development and the creation of promising combination therapies. This review explores the current state of advanced bioinformatics analysis and genetic technologies and their utilization for synergistic combination with TMZ in the context of inhibition of autophagy for controlling the growth of GBM.