Metabolic clogging of mannose triggers dNTP loss and genomic instability in human cancer cells

Mannose inhibits PKM2 lactylation to induce pyroptosis in bladder cancer and activate antitumor immune responses

Bladder cancer therapy remains challenging due to poor efficacy and frequent recurrence. Mannose, a naturally occurring monosaccharide, has demonstrated antitumor effects in various cancers, yet its mechanism of action in bladder cancer is unclear. This study explored the inhibitory effects of mannose on bladder cancer. We found mannose significantly inhibited the growth of bladder cancer cells, xenografts, and organoids. Mannose directly binds to PKM2, inhibiting its enzymatic activity and reducing lactate production. This reduction in lactate led to decreased PKM2 lactylation and increased acetylation, causing PKM2 to translocate to the nucleus. Nuclear PKM2 activated the NF-κB pathway, inducing NLRP1/Caspase-1/GSDMD/IL-1β-dependent pyroptosis. Additionally, mannose promoted antitumor immune responses by inducing pyroptosis and enhancing the efficacy of immune checkpoint inhibitors. These findings highlight the use of mannose as a potent antitumor agent and a promising therapeutic strategy for bladder cancer.

Mannose and PMI depletion overcomes radiation resistance in HPV-negative head and neck cancer

Radiotherapy is critical component of multidisciplinary cancer care, used as a primary and adjuvant treatment for patients with head and neck squamous cell carcinoma. This study investigates how mannose, a naturally occurring monosaccharide, combined with phosphomannose isomerase (PMI) depletion, enhances the sensitivity of HPV-negative head and neck tumour models to radiation. Isogenic PMI knockout models were generated by CRISPR/Cas9 gene editing, yielding a 20-fold increase in sensitivity to mannose in vitro, and causing significant tumour growth delay in vivo. This effect is driven by metabolic reprogramming, resulting in potent glycolytic suppression coupled with consistent depletion of ATP and glycolytic intermediates in PMI-depleted models. Functionally, these changes impede DNA damage repair following radiation, resulting in a significant increase in radiation sensitivity. Mannose and PMI ablation supressed both oxygen consumption rate and extracellular acidification, pushing cells towards a state of metabolic quiescence, effects contributing to increased radiation sensitivity under both normoxic and hypoxic conditions. In 3D-tumoursphere models, metabolic suppression by mannose and PMI depletion was shown to elevate intra-tumoursphere oxygen levels, contributing to significant in vitro oxygen-mediated radiosensitisation. These findings position PMI as a promising anti-tumour target, highlighting the potential of mannose as a metabolic radiosensitiser enhancing cancer treatment efficacy.

Manipulating mannose metabolism as a potential anticancer strategy

Cancer cells acquire metabolic advantages over their normal counterparts regarding the use of nutrients for sustained cell proliferation and cell survival in the tumor microenvironment. Notable among the metabolic traits in cancer cells is the Warburg effect, which is a reprogrammed form of glycolysis that favors the rapid generation of ATP from glucose and the production of biological macromolecules by diverting glucose into various metabolic intermediates. Meanwhile, mannose, which is the C-2 epimer of glucose, has the ability to dampen the Warburg effect, resulting in slow-cycling cancer cells that are highly susceptible to chemotherapy. This anticancer effect of mannose appears when its catabolism is compromised in cancer cells. Moreover, de novo synthesis of mannose within cancer cells has also been identified as a potential target for enhancing chemosensitivity through targeting glycosylation pathways. The underlying mechanisms by which alterations in mannose metabolism induce cancer cell vulnerability are just beginning to emerge. This review summarizes the current state of our knowledge of mannose metabolism and provides insights into its manipulation as a potential anticancer strategy.

Spirulina polysaccharides improve postthaw sperm quality in bulls by inhibiting the activation of pathways related to protein kinase A

Sperm cryopreservation is widely used in assisted reproductive technology (ART) and livestock breeding. Although sperm cryopreservation accelerates breeding, the quality of cryopreserved sperm tends to be decreased. Improving the quality of frozen sperm is a hot topic, and spirulina polysaccharide, known for its immunomodulatory and antioxidant properties, is considered a promising natural extract for extensive studies. In this study, a pectic polysaccharide was extracted from spirulina (PSP), and its effects on postthaw bovine sperm viability were evaluated. Phosphoproteomic analysis based on TMT labelling and LC-MS/MS was employed. The results revealed that 10 mg/L PSP had significant protective effects on postthaw sperm viability, plasma membrane integrity, acrosomal integrity, and mitochondrial membrane integrity. Moreover, PSP increased the antioxidant capacity by activating antioxidant enzymes such as SOD, CAT, and GSH-PX and reduced apoptosis, ROS release and MDA levels. In addition, PSP resulted in decreased phosphorylation levels of proteins related to the acrosome, flagellum, metabolism, energy acquisition, and apoptosis. This protective effect of PSP on frozen sperm was achieved by inhibiting the activation of protein kinase A(PKA) protein-related pathways.

Well-Defined Oligo(azobenzene-graft-mannose): Photostimuli Supramolecular Self-Assembly and Immune Effect Regulation

The immune system can recognize and respond to pathogens of various shapes. Synthetic materials that can change their shape have the potential to be used in vaccines and immune regulation. The ability of supramolecular assemblies to undergo reversible transformations in response to environmental stimuli allows for dynamic changes in their shapes and functionalities. A meticulously designed oligo(azobenzene-graft-mannose) was synthesized using a stepwise iterative method and "click" chemistry. This involved integrating hydrophobic and photoresponsive azobenzene units with hydrophilic and bioactive mannose units. The resulting oligomer, with its precise structure, displayed versatile assembly morphologies and chiralities that were responsive to light. These varying assembly morphologies demonstrated distinct capabilities in terms of inhibiting the proliferation of cancer cells and stimulating the maturation of dendritic cells. These discoveries contribute to the theoretical comprehension and advancement of photoswitchable bioactive materials.

Mannose: A Promising Player in Clinical and Biomedical Applications

Mannose, an isomer of glucose, exhibits a distinct molecular structure with the same formula but a different atom arrangement, contributing to its specific biological functions. Widely distributed in body fluids and tissues, particularly in the nervous system, skin, testes, and retinas, mannose plays a crucial role as a direct precursor for glycoprotein synthesis. Glycoproteins, essential for immune regulation and glycosylation processes, underscore the significance of mannose in these physiological activities. The clinical and biomedical applications of mannose are diverse, encompassing its anti-inflammatory properties, potential to inhibit bacterial infections, role in metabolism regulation, and suggested involvement in alleviating diabetes and obesity. Additionally, mannose shows promise in antitumor effects, immune modulation, and the construction of drug carriers, indicating a broad spectrum of therapeutic potential. The article aims to present a comprehensive review of mannose, focusing on its molecular structure, metabolic pathways, and clinical and biomedical applications, and also to emphasize its status as a promising therapeutic agent.

Biological function, regulatory mechanism, and clinical application of mannose in cancer

Studies examining the regulatory roles and clinical applications of monosaccharides other than glucose in cancer have been neglected. Mannose, a common type of monosaccharide found in human body fluids and tissues, primarily functions in protein glycosylation rather than carbohydrate metabolism. Recent research has demonstrated direct anticancer effects of mannose in vitro and in vivo. Simply supplementing cell culture medium or drinking water with mannose achieved these effects. Moreover, mannose enhances the effectiveness of current cancer treatments including chemotherapy, radiotherapy, targeted therapy, and immune therapy. Besides the advancements in basic research on the anticancer effects of mannose, recent studies have reported its application as a biomarker for cancer or in the delivery of anticancer drugs using mannose-modified drug delivery systems. This review discusses the progress made in understanding the regulatory roles of mannose in cancer progression, the mechanisms underlying its anticancer effects, and its current application in cancer diagnosis and treatment.

Metabolic clogging of mannose triggers dNTP loss and genomic instability in human cancer cells

Mannose has anticancer activity that inhibits cell proliferation and enhances the efficacy of chemotherapy. How mannose exerts its anticancer activity, however, remains poorly understood. Here, using genetically engineered human cancer cells that permit the precise control of mannose metabolic flux, we demonstrate that the large influx of mannose exceeding its metabolic capacity induced metabolic remodeling, leading to the generation of slow-cycling cells with limited deoxyribonucleoside triphosphates (dNTPs). This metabolic remodeling impaired dormant origin firing required to rescue stalled forks by cisplatin, thus exacerbating replication stress. Importantly, pharmacological inhibition of de novo dNTP biosynthesis was sufficient to retard cell cycle progression, sensitize cells to cisplatin, and inhibit dormant origin firing, suggesting dNTP loss-induced genomic instability as a central mechanism for the anticancer activity of mannose.