Hypoxic Conditions Research Articles

A multifunctional cascade gas-nanoreactor with MnO2 as a gatekeeper to enhance starvation therapy and provoke antitumor immune response

Glucose oxidase (GOx)-mediated starvation therapy is an effective tumor treatment that blocks energy and activates the immune response. However, the insufficient tumor immunogenicity and immunosuppressive tumor microenvironment (TME) limited its therapeutic efficacy. To address this, we have designed a multifunctional cascade gas-nanoreactor with a MnO2 coating, which serves as an out gatekeeper to encapsulate both GOx and a carbon monoxide (CO) donor (denoted as GCM). Due to the protective effect of MnO2 coating, GCM maintains better stability in normal physiological environments, enhancing the catalytic activity of GOx and minimizing toxic side effects. Upon accumulation in the tumor, the degradation of MnO2 coating exposes the GOx enzyme, thereby initiating a cascade catalysis reaction to generate hydrogen peroxide (H2O2) and release CO in the hypoxic conditions. Additionally, the released Mn2+ reacts with H2O2 to generate toxic hydroxyl radical (•OH) as chemodynamic therapy (CDT). The synergistic treatments of starvation therapy, CO gas therapy and CDT effectively kill cancer cells and amplify immunogenic cell death (ICD), maturing DC cells and activating anti-tumor immune response. Furthermore, the released CO increases M1 macrophages infiltration and reduces myeloid-derived suppressor cells (MDSCs) infiltration, thus reversing the immunosuppressive TME. This multifunctional gas-nanoreactor provides a strategy for CO gas generation to trigger a robust anti-tumor immune response and has the potential for clinical application in cancer immunotherapy. Statement of significanceA multifunctional cascade gas-nanoreactor with a MnO2 gatekeeper was developed to perform synergistic treatments involving starvation therapy, CO gas therapy and chemodynamic therapy (CDT) for tumor elimination. The MnO2 gatekeeper enhanced the catalytic activity of GOx within the nanoreactor by generating oxygen, thereby minimizing toxic side effects after intravenous injection. The gas-nanoreactor amplified ICD through synergistic treatments to mature DC cells and activate anti-tumor immune response. Furthermore, the released CO could reverse the immunosuppression of the TME to enhance cancer immunotherapy. The combination strategy utilizing the gas-nanoreactor demonstrates clinical potential for facilitating cancer immunotherapy.

Hypoxic Stress Induces Complement-Mediated Lysis of Mesenchymal Stem Cells by Downregulating Factor H and CD59.

Factor H and membrane inhibitor of reactive lysis (CD59) are key regulators of complement activation. Mesenchymal stem cells (MSCs) secrete Factor H and express CD59 to protect themselves from complement-mediated damage. Severe hypoxia found to decrease the survival chances of MSCs after transplantation; however, little is known about the impact of severe hypoxia on modulating the complement system activity and its effect on MSCs survival. Our study seeks to explore the effect of severe hypoxia on modulating the complement cascade in MSCs. Human adipose tissue-derived MSCs (hAD-MSCs) were cultured under severe hypoxia using 400μM Cobalt Chloride (CoCl2) for 48h. The protein expressions of survival marker; Phosphoinositide 3-kinases (PI3K), and pro-apoptotic marker; Caspase-3 were assessed using western blotting. The level of complement system related factors; Factor H, CD59, C3b, iC3b, C5b, C9, and the complement membrane attack complex (MAC) were analyzed using Elisa assays, western blotting, and immunocytochemistry. Our results showed for the first time that severe hypoxia can significantly impair Factor H secretion and CD59 expression in MSCs. This has been associated with upregulation of MAC complex and increased level of cell lysis and apoptosis marked by downregulation of PI3K and upregulation of Annexin v and Caspase-3. The loss of Factor H and CD59 in hypoxic MSCs can initiate their lysis and apoptosis mediated by activating MAC complex. Preserving the level of Factor H and CD59 in MSCs has significant clinical implication to increase their retention rate in hypoxic conditions and prolong their survival.

Isoflurane preconditioning attenuates OGD/R-induced cardiomyocyte cytotoxicity by regulating the miR-210/BNIP3 axis.

Isoflurane, a commonly used inhaled anesthetic, has been found to have a cardioprotective effect. However, the precise mechanisms have not been fully elucidated. Here, we found that isoflurane preconditioning enhanced OGD/R-induced upregulation of miR-210, a hypoxia-responsive miRNA, in AC16 human myocardial cells. To further test the roles of miR-210 in regulating the effects of isoflurane preconditioning on OGD/R-induced cardiomyocyte injury, AC16 cells were transfected with anti-miR-210 or control anti-miRNA. Results showed that isoflurane preconditioning attenuated OGD/R-induced cardiomyocyte cytotoxicity (as assessed by cell viability, LDH and CK-MB levels), which could be reversed by anti-miR-210. Isoflurane preconditioning also prevented OGD/R-induced increase in apoptotic rate, caspase-3 and caspase-9 activities, and Bax level and decrease in Bcl-2 expression level, while anti-miR-210 blocked these effects. We also found that anti-miR-210 prevented the inhibitory effects of isoflurane preconditioning on OGD/R-induced decrease in adenosine triphosphate content; mitochondrial volume; citrate synthase activity; complex I, II, and IV activities; and p-DRP1 and MFN2 expression. Besides, the expression of BNIP3, a reported direct target of miR-210, was significantly decreased under hypoxia condition and could be regulated by isoflurane preconditioning. In addition, BNIP3 knockdown attenuated the effects of miR-210 silencing on the cytoprotection of isoflurane preconditioning. These findings suggested that isoflurane preconditioning exerted protective effects against OGD/R-induced cardiac cytotoxicity by regulating the miR-210/BNIP3 axis.

Phosphorus fractions and their vertical distribution in seabed sediments of the eastern Baltic Sea

Phosphorus fractions and their vertical distribution in seabed sediments were studied in short cores from four coastal sites of western Estonia (Western Gulf of Finland, Väinameri Sea, Suur Strait, and Gulf of Riga) representing accumulation and erosion/transport settings. As a result of recent large-scale discharges of nutrients into the marine environment, abundant phosphorus has accumulated in the seabed sediments, from where it can, under the expansion of hypoxic or anoxic conditions, be remobilized and released back into the water column. A sequential extraction method with a neutral, a reducing, a basis, and an acidic solution was used to evaluate the distribution of phosphorous in pools of five different carrier fractions. Potentially mobile phosphorus is mostly associated with redox-sensitive iron- and manganese oxyhydroxides, and this fraction is significant in the Western Gulf of Finland and the Gulf of Riga. As oxygen conditions gradually deteriorate, the remobilization of a considerable amount of potentially mobile phosphorus from sediments can affect the entire Baltic Sea ecosystem.

Fibrosis signaling in endometrial cells and endometriosis development

In endometriosis, the tissues similar to the endometrial tissue attaches outside the uterine cavity, causing inflammation and fibrosis. The retrograde menstruation theory is the most plausible mechanism, though the detailed pathogenesis remains unclear. Our observations suggest that endometriosis-like lesions occur more often at sites of ovarian excision causing bleeding in mouse models. Additionally, prostaglandin E2 (PGE2) and thrombin, a protease-activated receptor (PAR) agonist in menstrual blood exacerbate inflammation in these lesions. Focusing on the hypoxic conditions of menstrual blood, we investigated the effects of PGE2/thrombin on inflammation and fibrosis using primary cultured endometrial stromal cells (ESCs) and glandular epithelial cells (EECs) under low oxygen conditions. Chemokine CXCL12 secreted by endometrial stromal cells under hypoxia acts on CXCR4 receptors on glandular epithelial cells, inducing epithelial-mesenchymal transition (EMT), suggesting a possible role in endometriosis progression. RNA-seq analysis of PGE2/thrombin effects on endometrial stromal cells revealed activation of the transforming growth factor (TGF)-β pathway, particularly increased production and secretion of activin A, a member of the TGFβ family. Activin A, via increased connective tissue growth factor (CTGF) expression, promotes differentiation of endometrial stromal cells from fibroblast-like to myofibroblast transdifferentiation (FMT) of ESCs. In conclusion, targeting the CXCL12/CXCR4 and activin A/CTGF signaling pathways holds promise for improving fibrosis in endometriosis lesions.

Inhibiting autophagy does not decrease drug resistance in breast cancer stem-like cells under hypoxic conditions

Inhibiting autophagy does not decrease drug resistance in breast cancer stem-like cells under hypoxic conditions

Exploration of novel 20S proteasome activators featuring anthraquinone structures and their application in hypoxic cardiomyocyte protection

Under hypoxic conditions, the accumulation of misfolded proteins primarily relies on the autonomous activity of 20S proteasome for degradation. The buildup of toxic proteins in cardiomyocyte contribute to various cardiovascular diseases. Therefore, enhancing the 20S proteasome degradation capacity and restoring protein homeostasis in myocardial cells with small molecule activators represent a promising therapeutic strategy for the treatment of ischemic cardiomyopathy. In this study, the lead compound 8016–8398 was identified through virtual screening, and subsequent structure optimization resulted in a series of highly potent 20S proteasome activators. Intracellular protein degradation assessment revealed that these compounds possessed abilities to alleviate endoplasmic reticulum stress, as demonstrated by the luciferase reporter system. Additionally, selected compound B-03 significantly enhanced the survival rate of hypoxic-damaged cardiomyocytes. Mechanistic investigations verified B-03 rescued hypoxic damaged cardiomyocyte through apoptosis inhibition and proliferation promotion.

Netupitant Exhibits Potent Activity on Mycobacterium tuberculosis Persisters.

In Mycobacterium tuberculosis (Mtb), persisters are genotypically drug-sensitive bacteria that nonetheless survive antibiotic treatment. Persisters represent a significant challenge to shortening TB treatment and preventing relapse, underscoring the need for new therapeutic strategies. In this study, we screened 2,336 FDA-approved compounds to identify agents that enhance the sterilizing activity of standard anti-TB drugs and prevent the regrowth of persisters. Netupitant (NTP), an FDA-approved antiemetic, emerged as a promising candidate with bacteriostatic activity on its own. However, in combination with isoniazid (INH) and rifampicin (RIF), NTP eliminated viable Mtb cells within 7 days, achieving a >6-log reduction in colony-forming units (CFUs) compared to the 2.5-log reduction observed with INH-RIF alone. NTP also demonstrated broad-spectrum efficacy, enhancing the activity of multiple TB drugs, including ethambutol, moxifloxacin, amikacin, and bedaquiline. Notably, NTP retained its potency under hypoxic and caseum-mimicking conditions, both of which are known to enrich for non-replicating, drug-tolerant cells. Interestingly, under hypoxic conditions, NTP demonstrated strong tuberculocidal activity, achieving an approximate 4-log CFU reduction, whereas high-dose INH-RIF was ineffective. Transcriptomic analysis revealed that NTP primarily disrupts cellular bioenergetics, with significant downregulation observed in activities associated with the electron transport chain, oxidative phosphorylation, NADH-ubiquinone oxidoreductase, succinate dehydrogenase, and ATP synthesis. While further studies are required to decipher the mechanism of action and resistance profile of NTP, and to assess its in vivo efficacy, these findings underscore its potential as a promising adjunct to existing TB therapies.

Targeting PGK1: A New Frontier in Breast Cancer Therapy Under Hypoxic Conditions.

Breast cancer represents one of the most prevalent malignant neoplasms affecting women, and its pathogenesis has garnered significant scholarly interest. Research indicates that the progression of breast cancer is intricately regulated by glucose metabolism. Under hypoxic conditions within the tumor microenvironment, breast cancer cells generate ATP and essential biosynthetic precursors for growth via the glycolytic pathway. Notably, phosphoglycerate kinase 1 (PGK1) is intimately associated with the regulation of hypoxia-inducible factors in breast cancer and plays a crucial role in modulating glycolytic processes. Further investigation into the role of PGK1 in breast cancer pathogenesis is anticipated to identify novel therapeutic targets and strategies. This review consolidates current research on the regulation of glucose metabolism and the function of PGK1 in breast cancer within hypoxic conditions. It aims to offer a significant theoretical foundation for elucidating the mechanisms underlying breast cancer progression and metastasis, thereby facilitating the development of innovative treatment approaches.

Anti-Cancer Strategy Based on Changes in the Role of Autophagy Depending on the Survival Environment and Tumorigenesis Stages.

Autophagy is a crucial mechanism for recycling intracellular materials, and under normal metabolic conditions, it is maintained at low levels in cells. However, when nutrients are deficient or under hypoxic conditions, the level of autophagy significantly increases. Particularly in cancer cells, which grow more rapidly than normal cells and tend to grow in a three-dimensional manner, cells inside the cell mass often face limited oxygen supply, leading to inherently higher levels of autophagy. Therefore, the initial development of anticancer drugs targeting autophagy was based on a strategy to suppress these high levels of autophagy. However, anticancer drugs that inhibit autophagy have not shown promising results in clinical trials, as it has been revealed that autophagy does not always play a role that favors cancer cell survival. Hence, this review aims to suggest anticancer strategies based on the changes in the role of autophagy according to survival conditions and tumorigenesis stage.

The gut microbiome and the brain.

The importance of the gut microbiome for human health and well-being is generally accepted, and elucidating the signaling pathways between the gut microbiome and the host offers novel mechanistic insight into the (patho)physiology and multifaceted aspects of healthy aging and human brain functions. The gut microbiome is tightly linked with the nervous system, and gut microbiota are increasingly emerging as important regulators of emotional and cognitive performance. They send and receive signals for the bidirectional communication between gut and brain via immunological, neuroanatomical, and humoral pathways. The composition of the gut microbiota and the spectrum of metabolites and neurotransmitters that they release changes with increasing age, nutrition, hypoxia, and other pathological conditions. Changes in gut microbiota (dysbiosis) are associated with critical illnesses such as cancer, cardiovascular, and chronic kidney disease but also neurological, mental, and pain disorders, as well as chemotherapies and antibiotics affecting brain development and function. Dysbiosis and a concomitant imbalance of mediators are increasingly emerging both as causes and consequences of diseases affecting the brain. Understanding the microbiota's role in the pathogenesis of these disorders will have major clinical implications and offer new opportunities for therapeutic interventions.

Salidroside ameliorates hypoxic pulmonary hypertension by regulating the two-pore domain potassium TASK-1 channel

BackgroundHypoxic pulmonary vasoconstriction (HPV) is a reflex constriction of vascular smooth muscle. This study aims to investigate the role of Salidroside (Sal) in pulmonary arterial dilatation and the potential mechanism of Sal regulating hypoxic pulmonary hypertension in vitro and in vivo. MethodsA rat model of hypoxic pulmonary hypertension (HPH) was constructed using hypoxic chamber. The effect of Sal on HPH were evaluated using vascular ring, whole cell patch-clamp, WGA staining, HE staining, and Sirius Scarlet staining assays. ResultsSal treatment alleviated the injury of acute hypoxia on pulmonary circulation in SD rats. Meanwhile, Sal treatment reduced the pulmonary vascular tone of acute hypoxia in a concentration-dependent manner, which was involved in the TWIK-related acid-sensitive potassium channel 1 (TASK-1) mediating diastolic effect. We found that Sal treatment significantly increased the TASK-1 current of pulmonary artery smooth muscle cells (PASMCs) in a concentration-dependent manner, as well as reversed the inhibitory effect of acute hypoxia on the TASK-1 current. Moreover, Sal treatment improved the TASK-1 current density, suppressed the proliferation, and enhanced the apoptosis of PASMCs in SD rats under continuous hypoxic condition. In addition, we found that the electrophysiological remodeling and pulmonary vascular remodeling of PASMCs were improved by the treatment of Sal through the regulation of TASK-1 channel. ConclusionsSal could alleviate HPH by restoring the function of TASK-1 channel, which may provide a novel method for the treatment of HPH.

Over-expression of Transmembrane Protein 158 Predicts Aggressive Tumor Behavior and Poor Prognosis in Lung Cancer.

Transmembrane protein 158 (TMEM158) has emerged as a potential contributor to cancer progression. While TMEM158 has been studied in various cancer types, its role in lung cancer remains unclear. Kaplan-Meier curves were used to evaluate the association between TMEM158 expression and overall survival rates. Gene set enrichment analysis (GSEA) was performed to explore pathways related to TMEM158, and sequence analysis was conducted to identify putative hypoxia-responsive element (HRE) sites in the TMEM158 promoter region. Hypoxic conditions were induced, and TMEM158 expression levels were measured by qPCR. The effect of hypoxia-inducible factor-1α (HIF-1α) depletion on TMEM158 expression was also examined. Additionally, lung cancer cells with either over-expressed or reduced TMEM158 levels were analyzed for epithelial-mesenchymal transition (EMT) and cell migration. Analysis of clinical datasets revealed elevated TMEM158 expression in tumors, particularly in patients with advanced stages. High TMEM158 expression was correlated with lower overall survival. TMEM158 was associated with EMT, hypoxia, and other tumor-promoting pathways. Under hypoxic conditions, TMEM158 expression was at least partially induced in a HIF-1α-dependent manner. Functional studies showed that over-expression of TMEM158 promoted EMT and increased lung cancer cell migration, while depletion of TMEM158 reduced these effects, indicating its role in aggressive tumor behavior. TMEM158 is highly expressed in lung cancer, is associated with hypoxia, and promotes EMT and cell migration. These findings suggest TMEM158 as a potential target for lung cancer therapies.

Hypoxia-driven hybrid phenotypes in Ewing sarcoma: Insights from computational epithelial-mesenchymal transition modeling

Ewing sarcoma (ES) is an extremely aggressive pediatric tumor primarily propelled by the EWS::FLI1 fusion protein. This fusion protein plays a pivotal role in various biological processes within ES, including hypoxia and epithelial-mesenchymal transition (EMT). Hypoxia has been documented to trigger EMT, a process that can stabilize a hybrid cell state, enhancing metastatic potential and resistance to drugs. However, the precise mechanisms that sustain this hybrid phenotype during hypoxia in ES have remained enigmatic. Our study introduces a logical model for EMT in ES, underscoring the potential significance of the EWS::FLI1/miR-145 circuit in inducing hybrid states during hypoxia. Furthermore, our findings underscore the necessity for downregulating EWS::FLI1 to fully activate EMT under hypoxic conditions. This model aligns well with results derived from existing literature. These insights underscore the crucial role of EWS::FLI1 in inducing the hybrid state in ES during hypoxia.

Targeting the undruggable in glioblastoma using nano-based intracellular drug delivery.

Glioblastoma (GBM) is a highly prevalent and aggressive brain tumor in adults with limited treatment response, leading to a 5-year survival rate of less than 5%. Standard therapies, including surgery, radiation, and chemotherapy, often fall short due to the tumor's location, hypoxic conditions, and the challenge of complete removal. Moreover, brain metastases from cancers such as breast and melanoma carry similarly poor prognoses. Recent advancements in nanomedicine offer promising solutions for targeted GBM therapies, with nanoparticles (NPs) capable of delivering chemotherapy drugs or radiation sensitizers across the blood-brain barrier (BBB) to specific tumor sites. Leveraging the enhanced permeability and retention effect, NPs can preferentially accumulate in tumor tissues, where compromised BBB regions enhance delivery efficiency. By modifying NP characteristics such as size, shape, and surface charge, researchers have improved circulation times and cellular uptake, enhancing therapeutic efficacy. Recent studies show that combining photothermal therapy with magnetic hyperthermia using AuNPs and magnetic NPs induces ROS-dependent apoptosis and immunogenic cell death providing dual-targeted, immune-activating approaches. This review discusses the latest NP-based drug delivery strategies, including gene therapy, receptor-mediated transport, and multi-modal approaches like photothermal-magnetic hyperthermia combinations, all aimed at optimizing therapeutic outcomes for GBM.

Commentary: the perspectives of harnessing the power of scattered tubular-like cells for renal repair.

The commentary discusses the regenerative capacity of the kidneys; recent studies reveal that renal cells can regenerate when exposed to certain conditions. A major focus is on scattered tubular-like cells (STCs), which can dedifferentiate and acquire progenitor-like properties in response to injury. These cells exhibit a glycolytic metabolism, making them resilient to hypoxic conditions and capable of repairing damaged renal tissues. Despite their potential, STCs are difficult to isolate and exist in small numbers. Here we highlight the need for more research into STC function, metabolic profiles, mechanisms limiting STC injury repair capacity, and methods of their pharmacological activation. Understanding these mechanisms could lead to novel therapies for kidney diseases.

Chest compression quality decreases in hypoxic conditions simulating an airliner cabin at cruising altitude: a randomized, controlled, double-blind Manikin Study

AbstractAir traveler numbers are predicted to reach 4.0 billion in 2024. Between 1/15,000–50,000 passengers will experience acute medical problems inflight with cardiac arrests requiring cardiopulmonary resuscitation (CPR) accounting for 0.3% of medical emergencies. Hypoxia in airplane cabins could impair oxygenation and physical performance of caregivers. We conducted a randomized controlled, double-blind study to test the hypothesis that hypoxia decreases the effectiveness in performing CPR. We randomized 24 healthcare professionals to two different study arms, each consisting of two conditions: arm (1) ‘hypoxia (FiO2 15%, equivalent to 2400 m altitude)’ versus ‘normoxia’; arm (2) ‘hypoxia + supplemental oxygen’ versus ‘normoxia + supplemental oxygen’. The order of conditions was counterbalanced and a minimum wash-out period of 24 h was granted between conditions. In each condition participants performed a 5-min cardiac compression only CPR (CCO-CPR) using a full-body manikin after one, three and six hours in an altitude chamber. Mixed ANOVAs with post-hoc false-discovery-rate adjusted pairwise comparisons indicated that although compression frequency was maintained, the number of compressions with correct depth was decreased at all times during hypoxia compared to normoxia (all p < 0.002). After 6 h hypoxia exposure, mean compression depth was below the recommended compression depth defined by ERC/AHA guidelines and reduced compared to normoxia (42.4 ± 12.6 mm vs. 54.6 ± 4.3 mm, p < 0.0001). Supplemental oxygen during CCO-CPR in hypoxia prevented the decrease of compression-depth (55.3 ± 3 mm). Extended hypoxia exposure akin to conditions in airplane cabins can reduce quality of chest compressions during CPR. Supplemental oxygen for healthcare providers is an effective countermeasure.

Design, synthesis, molecular dynamics and gene silencing studies of novel therapeutic HIF-1α siRNAs in hypoxic cancer cells

Hypoxia inducible factors (HIFs) are heterodimeric proteins that belong to a small group of transcription factors, which mainly regulates transcription of genes under hypoxic conditions. Particularly, oxygen sensing subunit of HIF-1α is a predominant subtype that heterodimerizes with oxygen-independent HIF-1β subunit, to trigger the transcription of hypoxia responsive genes. Due to poor supply of blood and rapid division of cancerous cells, tumor microenvironment exhibits low oxygen condition and therefore increased levels of HIF-1α. One of the promising therapeutic strategies to cancer is modulation of HIF-1α signaling pathway. Small interfering RNA (siRNA) mediated downregulation of HIF-1α has been reported to prevent growth and progression of various types of cancer and holds great promise in the cancer treatment. In this study, computational approaches were used to design potential siRNAs targeting HIF-1α and investigate their interaction with the human argonaute-2 (hAgo2). Molecular dynamic simulation of HIF-1α siRNAs-hAgo2 complexes revealed key interactions required for the efficient binding of guide strand to hAgo2 protein. Two siRNAs (S2 and S5) exhibiting strong binding with hAgo2 were further considered. Subsequently, we transfected the MCF-7 cell line with both standard HIF-1α and our designed siRNAs (S2 and S5). Following transfection, translation changes in the MCF-7 cells were assessed through western blotting. S2 and S5 efficiently reduced the expression of HIF-1α in hypoxic conditions. The aim of the present study is to understand the siRNA-hAgo2 interaction. It is also focused on the desiging of effective siRNA against HIF-1α.

Impact of Hypoxia and the Levels of Transcription Factor HIF-1α and JMJD1A on Epithelial-Mesenchymal Transition in Head and Neck Squamous Cell Carcinoma Cell Lines.

This study aimed to assess the impact of hypoxia on epithelial-mesenchymal transition (EMT) in head and neck squamous cell carcinoma (HNSCC), focusing on the involvement of transcription factors hypoxia inducible factor 1 (HIF-1α) and Jumonji Domain-Containing Protein 1A (JMJD1A). FaDu and Cal33 cell lines were subjected to hypoxic and normoxic conditions. Cell proliferation was quantified electronically, while PCR and western blot analyses were used to measure mRNA and protein levels of HIF-1α, JMJD1A, and EMT markers. EMT was further characterized through immunofluorescence, migration, and invasion assays. Hypoxic conditions significantly reduced cell proliferation after 48 hours in both cell lines. HIF-1α mRNA levels increased initially during short-term hypoxia but declined thereafter, while JMJD1A mRNA levels showed a sustained increase with prolonged hypoxia. Western blot analysis revealed contrasting trends in protein levels. EMT marker expression varied markedly over time at both the mRNA and protein levels, suggesting EMT induction in hypoxia within 24 hours. Immunofluorescence, migration, and invasion assays supported these findings. The study provides evidence of hypoxia-induced EMT in HNSCC, although conflicting results suggest a complex interplay among molecular regulators involved in this process.

Restoration of autophagy reduces diabetes-induced endothelial dysfunction

Abstract Introduction Diabetes leads to endothelial dysfunction, a main determinant of several cardiovascular diseases. The molecular mechanisms underlying the effects of hyperglycemia in endothelial cells are not fully characterized. Autophagy, the intracellular process by which the cell digests and recycles senescent or damaged cytoplasmic elements, exerts cardiovascular protective effects, limiting cardiac and vascular injury in the presence of stress. However, it is unclear how hyperglycemia modulates autophagy in endothelial cells. Purpose In this study, we elucidated the role of autophagy in vascular damage induced by diabetes. We also tested whether the restoration autophagy attenuates diabetes-induced endothelial damage. Methods We evaluated the effects of high-glucose (HG, 30 mM for 6 and 24 hours) on markers of endothelial function, autophagy, autophagic flux, and mitophagy in human umbilical endothelial cells (HUVEC) in vitro and in mesenteric arteries from wild-type mice (WT) ex vivo. We tested the effects of autophagy reactivation using the natural polyamine spermidine or ATG7 overexpression (ATG7ov) on apoptosis and angiogenesis in HUVEC treated with HG. Vascular reactivity experiments in the presence of autophagy activation were performed in HG-treated mouse mesenteric arteries and human saphenous veins from patients with peripheral artery disease. Finally, we evaluated the level of autophagy in the mammary arteries of newly discovered diabetic patients undergoing coronary artery bypass graft surgery. Results We found that HG reduces autophagy (0.6 fold p<0.05) and mitophagy (1.5 fold p<0.001) in HUVECs. We also demonstrated that endothelial cells undergoing hyperglycemia fail to activate autophagy under hypoxic conditions (0.6 fold p<0.05). Reactivation of autophagy by ATG7ov rescues apoptosis (0.52 fold p<0.05) and angiogenesis (2.3 fold p<0.05) in HUVEC treated with HG. We further observed that HG exacerbates endothelial dysfunction in a mouse model of genetic inhibition (Beclin 1 +/- mice), compared to WT mice (-19.16 % +-4.97 SEM vs -48.39 % +-2.18 SEM p<0.001). Mechanistically, HG increases cellular acetylation status (0.7 fold p<0.05) and activates p300 (1 fold p<0.05), an autophagy inhibitor. ATG7ov or spermidine, a p300 inhibitor, rescue endothelial-dependent relaxation in mesenteric arteries of WT mice treated with HG (ATG7ov -62.48 % +-5.16 SEM; SP -63.01 +-3.22 SEM; HG -40.67 % +-3.82 p<0.001). Finally, we observed reduced levels of autophagy in mammary arteries from diabetic patients and demonstrated that SP improves vascular function in human saphenous veins (-37.6 % +-12.76 SEM vs -12.52 % +-5.6 SEM p<0.001). Conclusion Our results suggest that the impairment of autophagy is a strong contributor of diabetes induced-endothelial dysfunction. Targeting autophagy may represent a valid therapeutic strategy to counteract the cardiovascular consequences of metabolic stress.