Project description:Cancer cachexia is a metabolic multifactorial syndrome that causes up to 20% of cancer-related deaths. Muscle atrophy, the hallmark of cancer cachexia, strongly impairs the quality of life of cancer patients; however, the underlying pathological process is still poorly understood. In our study, the transcriptome of cachectic gastrocnemius muscle in the C26 xenograft model was comparied with normal control. The key pathways involving this diseases was discovered according to the different expressed genes.

Project description:Cancer-associated cachexia (CAC) is a wasting syndrome caused by malignant tumors. Fat loss plays a significant role in the pathophysiology of cancer-associated cachexia. The mechanism of fat loss in CAC includes enhancement of lipolysis, inhibition of lipogenesis and browning of white adipose tissue. In order to discover potentially functional genes in white adipose tissue of CAC, we used transcriptome sequencing technology to find research-valuable genes in white adipose tissue (WAT) of CAC rodent model. C57/bl6 mice with LLC tumors were used as the in vivo model for CAC, while normal mice subcutaneously injected with phosphate buffer solution were used as the control group. Overall, our data revealed genes that were differentially expressed in the white adipose tissue of LLC tumor-bearing mice, providing a molecular framework for the investigation into CAC fat loss.

Project description:Cachexia is a devastating muscle wasting syndrome that occurs in patients suffering from chronic diseases, most commonly observed in 80% of advanced cancer patients. One of the primary causes of cachexia-associated morbidity and mortality is involuntary muscle wasting. And while many cachexia patients show hypermetabolism, its causative role in muscles had remained unclear. To understand the molecular basis of this muscle wasting, accurate models of cachexia are necessary. Using transcriptomics and cytokine profiling of human muscle stem cell-based models and human cancer-induced cachexia models in mice, we found that cachectic cancer cells secreted many inflammatory factors which rapidly led to higher levels of fatty acid metabolism and the activation of a p38 stress response signature, before the cachectic muscle wasting is manifested. Metabolomics profiling revealed that factors secreted by cachectic cancer cells rapidly induce excessive fatty acid oxidation in human myotubes, leading to oxidative stress, p38 activation, and impaired muscle growth. Pharmacological blockade of fatty acid oxidation not only rescued human myotubes, but also significantly improved muscle mass and total weight in cancer cachexia models in vivo. Therefore, fatty acid-induced oxidative stress could be targeted to prevent cancer cachexia.

Project description:Cachexia is a devastating muscle wasting syndrome that occurs in patients suffering from chronic diseases, most commonly observed in 80% of advanced cancer patients. One of the primary causes of cachexia-associated morbidity and mortality is involuntary muscle wasting. And while many cachexia patients show hypermetabolism, its causative role in muscles had remained unclear. To understand the molecular basis of this muscle wasting, accurate models of cachexia are necessary. Using transcriptomics and cytokine profiling of human muscle stem cell-based models and human cancer-induced cachexia models in mice, we found that cachectic cancer cells secreted many inflammatory factors which rapidly led to higher levels of fatty acid metabolism and the activation of a p38 stress response signature, before the cachectic muscle wasting is manifested. Metabolomics profiling revealed that factors secreted by cachectic cancer cells rapidly induce excessive fatty acid oxidation in human myotubes, leading to oxidative stress, p38 activation, and impaired muscle growth. Pharmacological blockade of fatty acid oxidation not only rescued human myotubes, but also significantly improved muscle mass and total weight in cancer cachexia models in vivo. Therefore, fatty acid-induced oxidative stress could be targeted to prevent cancer cachexia.

Project description:Background. Pancreatic Ductal AdenoCarcinoma (PDAC), the most frequent pancreatic cancer, is a deadly cancer since often diagnosed late and resistant to current therapies. A high proportion of PDAC patients are affected by cachexia induced by the tumor. This cachexia, characterized by loss of muscle mass and strength, contributes to patient frailty and poor therapeutic response. We showed that mitochondrial metabolism is reprogrammed in PDAC tumor cell and constitutes a vulnerability, opening novel therapeutic avenues. The objective of the present work was to investigate the molecular mechanisms underlying mitochondrial remodeling in PDAC cachectic skeletal muscle. Methods. Our study focused on the gastrocnemius muscle of genetically-engineered mice developing spontaneously a PDAC associated with cachexia (KIC GEMM). We compared KIC mice developing a pancreatic tumor in 9-10 weeks to control littermates. We did an integrative study combining in vivo functional analyses by non-invasive Magnetic Resonance, and ex-vivo histology, Seahorse, RNA-sequencing, and proteomic mass spectrometry and western blotting analyses. Results. The cachectic KIC PDAC mice show a severe sarcopenia with loss of muscle mass and strength associated with a diminution in muscle fiber’s size and induction of protein degradation processes. Mitochondria in PDAC atrophic muscles show decreased respiratory capacities and structural alterations (“hyperfused” mitochondria), associated with deregulation of oxidative phosphorylation and mitochondrial dynamics pathways at the molecular level. Increased expression of multiple reactive oxygen species (ROS) defense genes suggests oxidative stress prone to affect mitochondrial macromolecules and homeostasis. Interestingly, multiple genes and proteins involved in DNA metabolism pathways, such as DNA damage, degradation of DNA, nucleotide synthesis, and folate pathway were found altered in sarcopenic mitochondria. While the number of mitochondria was not changed, the mitochondrial mass was decreased by a factor of 2 and the mitochondrial DNA by a factor of 3, suggesting a defect in mitochondrial genome homeostasis. Conclusions. We unveiled that mitochondrial alterations in skeletal muscle play a central role in PDAC-induced cachexia. Muscle atrophy is associated with strong mitochondrial metabolic defects that are not limited to carbohydrates and protein, but concern also lipids, ROS and nucleic acids. Our data provide a frame to guide towards the most relevant molecular markers that would be affected at the start of tumor development and could be targets in the clinic to limit PDAC-induced cachexia at early stages of the pathology.

Project description:Pancreatic Ductal AdenoCarcinoma (PDAC), the most common pancreatic cancer, is a deadly cancer since it is often diagnosed late and resistant to current therapies. A large proportion of PDAC patients are affected by tumor-induced cachexia. This cachexia, characterized by a loss of muscle mass and strength (sarcopenia), contributes to patient frailty and poor therapeutic response. We have shown that mitochondrial metabolism is reprogrammed in PDAC tumors and constitutes a vulnerability, opening new therapeutic avenues. The objective of this work was to study the molecular mechanisms underlying mitochondrial remodeling in PDAC cachectic skeletal muscle. Our study focused on the gastrocnemius muscle of genetically-engineered mice spontaneously developing an autochthonous pancreatic tumor and cachexia (KIC GEMM). We compared KIC mice developing a pancreatic tumor in 9-11 weeks to control littermates. We performed an integrative study combining in vivo functional analyses by non-invasive Magnetic Resonance, and ex-vivo histology, Seahorse, RNA-sequencing, and proteomic mass spectrometry and Western blotting analyses. KIC cachectic PDAC mice exhibit severe sarcopenia with loss of muscle mass and strength associated with reduced muscle fiber’s size and induction of protein degradation processes. Mitochondrial alterations in skeletal muscle play a central role in PDAC-induced cachexia. Muscle atrophy is associated with strong mitochondrial metabolic defects that are not limited to carbohydrates and protein metabolism, but concern also lipids, ROS and nucleic acids. Our data provide a framework to guide towards the most relevant molecular markers that would be affected early in tumor development and could be targeted in the clinic to limit PDAC-induced cachexia at early stages of the pathology.

Project description:No approved therapy exists for cancer-associated cachexia. The colon-26 mouse model of cancer cachexia mimics recent late stage clinical failures of anabolic anti-cachexia therapy, and was unresponsive to anabolic doses of diverse androgens, including the selective androgen receptor modulator (SARM) GTx-024. The histone deacetylase inhibitor (HDACi) AR-42 exhibited anti-cachectic activity in this model. We explored combined SARM/AR-42 therapy as an improved anti-cachectic treatment paradigm. A reduced dose of AR-42 provided limited anti-cachectic benefits, but, in combination with GTx-024, significantly improved body weight, hind limb muscle mass, and grip strength versus controls. AR-42 suppressed the IL-6/GP130/STAT3 signaling axis in muscle without impacting circulating cytokines. GTx-024-mediated β-catenin target gene regulation was apparent in cachectic mice only when combined with AR-42. Our data suggest cachectic signaling in this model involves catabolic signaling insensitive to anabolic GTx-024 therapy and a blockade of GTx-024-mediated anabolic signaling. AR-42 mitigates catabolic gene activation and restores anabolic responsiveness to GTx-024. Combining GTx-024, a clinically established anabolic therapy, with AR-42, a clinically evaluated HDACi, represents a promising approach to improve anabolic response in cachectic patients.

Project description:Cancer cachexia is a disorder characterized by both involuntary weight loss and impaired physical performance. Decline in physical performance of patients with cachexia is associated with poor quality of life, and currently there are no effective pharmacological interventions that restore physical performance. Here we examined the effect of GDF15 neutralization in a mouse model of cancer-induced cachexia (TOV21G) that manifested weight loss and muscle function impairments. With comprehensive assessments, our results demonstrated that cachectic mice treated with the anti-GDF15 antibody mAB2 exhibited body weight gain with near-complete restoration of muscle mass and markedly improved muscle function and physical performance. Mechanistically, the improvements induced by GDF15 neutralization were primarily attributed to increased caloric intake, while altered gene expressions in cachectic muscles were restored in both caloric intake-dependent and -independent manners. The findings implicate the potential of GDF15 neutralization as an effective therapy to enhance physical performance of patients with cachexia.

Project description:Cancer cachexia and the associated skeletal muscle wasting are considered poor prognostic factors, although effective treatment has not yet been established. Recent studies have indicated that the pathogenesis of skeletal muscle loss may involve dysbiosis of the gut microbiota and the accompanying chronic inflammation or altered metabolism. In this study, we evaluated the possible effects of modifying the gut microenvironment with partially hydrolyzed guar gum (PHGG), a soluble dietary fiber, on cancer-related muscle wasting and its mechanism using a colon-26 murine cachexia model. Compared to a fiber-free (FF) diet, PHGG contained fiber-rich (FR) diet attenuated skeletal muscle loss in cachectic mice by suppressing the elevation of the major muscle-specific ubiquitin ligases Atrogin-1 and MuRF1, as well as the autophagy markers LC3 and Bnip3. Although tight junction markers were partially reduced in both FR and FF diet-fed cachectic mice, the abundance of Bifidobacterium, Akkermansia, and unclassified S24-7 family increased by FR diet, contributing to the retention of the colonic mucus layer. The reinforcement of the gut barrier function resulted in the controlled entry of pathogens into the host system and reduced circulating levels of lipopolysaccharide-binding protein (LBP) and IL-6, which in turn led to the suppression of proteolysis by downregulating the ubiquitin-proteasome system and autophagy pathway. These results suggest that dietary fiber may have the potential to alleviate skeletal muscle loss in cancer cachexia, providing new insights for developing effective strategies in the future.

Project description:Cancer cachexia is a metabolic syndrome with alterations in gene expression profile that consequently lead to skeletal muscle wasting. Here, we used RNA sequencing to analyze the microRNA expression profile in the tibialis anterior muscles of the Lewis lung carcinoma (LLC) model of cancer cachexia.