Tendinosis develops from age‐ and oxygen tension‐dependent modulation of Rac1 activity

Age‐related tendon degeneration (tendinosis) is characterized by a phenotypic change in which tenocytes display characteristics of fibrochondrocytes and mineralized fibrochondrocytes. As tendon degeneration has been noted in vivo in areas of decreased tendon vascularity, we hypothesized that hypoxia is responsible for the development of the tendinosis phenotype, and that these effects are more pronounced in aged tenocytes. Hypoxic (1% O₂) culture of aged, tendinotic, and young human tenocytes resulted in a mineralized fibrochondrocyte phenotype in aged tenocytes, and a fibrochondrocyte phenotype in young and tendinotic tenocytes. Investigation of the molecular mechanism responsible for this phenotype change revealed that the fibrochondrocyte phenotype in aged tenocytes occurs with decreased Rac1 activity in response to hypoxia. In young hypoxic tenocytes, however, the fibrochondrocyte phenotype occurs with concomitant decreased Rac1 activity coupled with increased RhoA activity. Using pharmacologic and adenoviral manipulation, we confirmed that these hypoxic effects on the tenocyte phenotype are linked directly to the activity of RhoA/Rac1 GTPase in in vitro human cell culture and tendon explants. These results demonstrate that hypoxia drives tenocyte phenotypic changes, and provide a molecular insight into the development of human tendinosis that occurs with aging.     

Performance of the eclipse monitor unit objective tool utilizing volumetric modulated arc therapy for rectal cancer

AimTo assess the performance of the monitor unit (MU) Objective tool in Eclipse treatment planning system (TPS) utilizing volumetric modulated arc therapy (VMAT) for rectal cancer.BackgroundEclipse VMAT planning module includes a tool to control the number of MUs delivered: the MU Objective tool. This tool could be utilized to reduce the total number of MUs in rectal cancer treatments.Materials and methods20 rectal cancer patients were retrospectively studied using VMAT and the MU Objective tool. The baseline plan for each patient was selected as the one with no usage of the MU Objective tool. The number of MUs of this plan was set to be the reference number of MUs (MU_ref). Five plans were re-optimized for each patient only varying the Max MU parameter. The selected values were 30%, 60%, 90%, 120% and 150% of MU_ref for each patient. Differences with respect to the baseline plan were evaluated regarding MU number and parameters for PTVs coverage evaluation, PTVs homogeneity and OARs doses assessment. A two-tailed, paired-samples t-test was used to quantify these differences.ResultsAverage relative differences in MU number obtained was 10% for Max MU values of 30% and 60% of MU_ref, respectively (p < 0.03). PTVs coverage and homogeneity were not compromised and discrepancies obtained with respect to baseline plans were not significant. Furthermore, maximum OARs doses deviations were also not significant.ConclusionsA 10% reduction in the MU number could be obtained without an alteration of PTV coverage and OARs doses for rectal cancer.     

Bad company: Microenvironmentally mediated resistance to targeted therapy in melanoma

This review will focus on the role of the tumor microenvironment (TME) in the development of drug resistance in melanoma. Resistance to mitogen‐activated protein kinase inhibitors (MAPKi) in melanoma is observed months after treatment, a phenomenon that is often attributed to the incredible plasticity of melanoma cells but may also depend on the TME. The TME is unique in its cellular composition—it contains fibroblasts, immune cells, endothelial cells, adipocytes, and among others. In addition, the TME provides “non‐homeostatic” levels of oxygen, nutrients (hypoxia and metabolic stress), and extracellular matrix proteins, creating a pro‐tumorigenic niche that drives resistance to MAPKi treatment. In this review, we will focus on how changes in the tumor microenvironment regulate MAPKi resistance.     

Polytherapy with hERG-blocking antiepileptic drugs: increased risk for embryonic cardiac arrhythmia and teratogenicity

BACKGROUND: The antiepileptic drugs (AEDs) phenytoin, phenobarbital, dimethadione, and carbamazepine cause a similar pattern of malformations in humans, with an increased risk after polytherapy. The teratogenicity has been linked to cardiac rhythm disturbances and hypoxic damage as a consequence of their common potential to inhibit a specific potassium ion current (IKr). The IKr is of major importance for embryonic cardiac repolarization and rhythm regulation. This study investigated whether these AEDs cause irregular rhythm and if various combinations of AEDs result in higher arrhythmia risk than exposure to a single AED. METHODS: The effects on heart rhythm of a single AED (monotherapy), and of various combinations (polytherapy) of AEDs, in gestational day 10 C57BL mouse embryos in culture were analyzed and graphically illustrated during a 25 s recording with a digitalization technique. RESULTS: All of the studied AEDs caused increased intervals between heartbeats (resulting in bradycardia) and large variations in the interval between heartbeats (resulting in irregular rhythm) in a concentration-dependent manner in cultured mouse embryos. Dimethadione caused irregular rhythm at concentrations within and phenytoin slightly above the therapeutic ranges. Polytherapy resulted in more substantial prolongation of the mean interval between heartbeats (>60 ms) than monotherapy at clinically relevant concentrations. CONCLUSIONS: The results suggest that polytherapy more than monotherapy causes substantial prolongation of the cardiac repolarization, a marker associated with high risk of developing irregular rhythm during longer exposure periods (days to months). This supports the idea that the increased risk for malformations following polytherapy is linked to an increased risk for cardiac rhythm disturbances.     

低氧促进肺腺癌A549细胞迁移的机制*

目的: 探讨低氧促进肺腺癌A549细胞迁移的机制。方法: 培养肺腺癌A549细胞,转染慢病毒获得稳定敲低ACC1的A549细胞株,转染si-RNA获得敲低SREBP-1的A549细胞。分别以低氧(5％ O₂)联合低氧诱导因子1α(HIF-1α)抑制剂PX-478(25 μmol)处理A549细胞,低氧联合亚油酸(LA)(20 μmol)处理敲低ACC1的A549细胞,低氧处理敲低胆固醇调节原件结合蛋白1(SREBP-1)的A549细胞。Transwell实验检测细胞迁移,蛋白质印迹法检测HIF-1α、ACC1及上皮-间质转化(EMT)相关波形蛋白(Vimentin)及E-钙黏蛋白(E-Cadherin)的表达与SREBP-1的表达,实时荧光定量聚合酶链反应(RT-qPCR)检测低氧联合HIF-1α抑制剂PX-478(25 μmol)处理A549细胞后ACC1及SREBP-1 mRNA水平变化。每项实验重复三次。结果: 与常氧组相比,低氧组A549细胞迁移数增加,ACC1与HIF-1α表达上调(P均＜0.01),SREBP-1表达上调(P＜0.05);与低氧对照组相比,PX-478(25 μmol)抑制A549细胞迁移,SREBP-1表达下调(P＜0.05);低氧处理A549细胞后ACC1 mRNA上升(P＜0.05),SREBP-1 mRNA水平上升(P＜0.01);低氧并使用PX-478(25 μmol)处理A549细胞24 h,ACC1 mRNA水平下降(P＜0.05),SREBP-1 mRNA 水平下降(P＜0.01);转染si-RNA获得敲低SREBP-1的A549细胞,Transwell 实验显示si-SREBP-1组细胞迁移数较常氧对照组减少(P＜0.01);低氧处理si-SREBP-1组与si-NC组,与对照组相比si-SREBP-1组细胞迁移数减少(P＜0.01)但与常氧组相比差异无统计学意义(P＞0.05);Western blot检测到si-SREBP-1组ACC1表达较对照组下降(P＜0.01);低氧处理si-SREBP-1组,ACC1表达较对照组下降(P＜0.01);敲低ACC1抑制A549细胞迁移(P＜0.05),敲低ACC1后A549细胞在常氧和5％ O₂条件下细胞迁移数目差异无统计学意义(P＞ 0.05);低氧处理敲低ACC1的A549细胞并给予LA(25 μmol)促进A549细胞迁移(P＜0.05)。结论: 低氧通过HIF-1α/SREBP-1/ACC1途径调节脂肪酸代谢进而促进肺腺癌A549细胞迁移。     

Recovery from hypoxia-induced internalization of cardiac Na+/H + exchanger 1 requires an adequate intracellular store of antioxidants

The heart is highly active metabolically but relatively underperfused and, therefore, vulnerable to ischemia. In addition to acidosis, a key component of ischemia is hypoxia that can modulate gene expression and protein function as part of an adaptive or even maladaptive response. Here, using cardiac-derived HL-1 cells, we investigate the effect of various hypoxic stimuli on the expression and activity of Na⁺/H ⁺ exchanger 1 (NHE1), a principal regulator of intracellular pH. Acute (10 min) anoxia produced a reversible decrease in the sarcolemmal NHE1 activity attributable to NHE1 internalization. Treatment with either 1% O ₂ or dimethyloxaloylglycine (DMOG; 1 mM) for 48-hr stabilized hypoxia-inducible factor 1 and reduced the sarcolemmal NHE1 activity by internalization, but without a change in total NHE1 immunoreactivity or message levels of the coding gene ( SLC9A1) determined in whole-cell lysates. Unlike the effect of DMOG, which was rapidly reversed on washout, reoxygenation after a prolonged period of hypoxia did not reverse the effects on NHE1, unless media were also supplemented with a membrane-permeant derivative of glutathione (GSH). Without a prior hypoxic episode, GSH supplementation had no effect on the NHE1 activity. Thus, posthypoxic NHE1 reinsertion can only take place if cells have a sufficient reservoir of a reducing agent. We propose that oxidative stress under prolonged hypoxia depletes intracellular GSH to an extent that curtails NHE1 reinsertion once the hypoxic stimulus is withdrawn. This effect may be cardioprotective, as rapid postischaemic restoration of the NHE1 activity is known to trigger reperfusion injury by producing an intracellular Na ⁺-overload, which is proarrhythmogenic.