So‐Youn Kim

Pancreatic Damage in Ovarian Cancer–Associated Cachexia Is Driven by Activin A Signalling

ABSTRACT Background Cancer‐associated cachexia (CAC) is a severe metabolic disorder characterized by involuntary weight loss, skeletal muscle atrophy and adipose tissue depletion. It is a major contributor to morbidity and mortality in the advanced stages of various cancers. However, the impact of CAC on the pancreas remains largely unexplored. Methods We used mice with constitutively active PI3K in oocytes, generated through a Cre‐inducible Pik3ca* knock‐in allele driven by Gdf9 ‐icre and performed histological and molecular analyses of the pancreas during cachexia development. Additionally, we examined pancreatic changes following ovariectomy and administration of Follistatin 288 (FST288). Results Mice that developed cachexia symptoms associated with granulosa cell tumour (GCT) growth exhibited significant pancreatic atrophy compared to controls (Cre+ vs. Cre− at PD83, p  < 0.0001), including reduced size of individual acinar cells (102.99 ± 12.19 μm 2 vs. 207.94 ± 24.85 μm 2 at PD83, p  < 0.0001) and acinar units (346.41 ± 169.22 μm 2 vs. 1193.59 ± 136.01 μm 2 at PD83, p  < 0.0001), despite comparable food intake between groups. Acinar cells exhibited a decrease in zymogen granules, reduced amylase expression and diminished amylase activity in both serum (0.29 ± 0.08 vs. 1.41 ± 0.40, p  < 0.001) and tissue (0.37 ± 0.14 vs. 1.05 ± 0.29, p  < 0.01). In contrast, pancreatic islets remained intact, as evidenced by histological analysis and preserved insulin expression. The pancreas of PD83 Cre+ mice also developed fibrosis and acinar cell death, characterized by elevated expression of collagen IV and α‐SMA, and TUNEL‐positive signals in acinar cells, respectively. Ovariectomy preserved body weight (2.66 ± 1.30 g for Cre+/OVX vs. 1.60 ± 0.97 g for Cre−) compared to Cre+ mice (−3.66 g) and maintained pancreatic function, suggesting that tumour‐derived factors from GCT contribute to the severity of cachexia. Acinar cells showed high expression of ACVR2B, leading to activation of downstream p‐SMAD3 signalling. Accordingly, activin A directly induced acinar cell atrophy in both ex vivo cultured pancreas (79.27 ± 19.03 μm 2 vs. 171.14 ± 27.01 μm 2 , p  < 0.0001) and 266‐6 acinar cells, as evidenced by reduced acinar cell size and decreased amylase production. Injection of FST288, an activin A inhibitor, rescued pancreatic acinar atrophy (252.95 ± 11.59 μm 2 in Cre+/FST288 vs. 97.25 ± 12.37 μm 2 in Cre+, p  < 0.001) without affecting GCT tumour size. Ex vivo culture of pancreas and 266‐6 acinar cells exposed to activin A confirmed that activin A directly induces pancreatic damage. Conclusions These findings demonstrate pancreatic damage occurs during CAC development and highlight the critical role of activin A in this process. Targeting activin A signalling may represent a promising therapeutic strategy to mitigate cachexia in cancer patients and preserve pancreatic function.

DNA damage response signaling in oocytes from an oncofertility perspective

Abstract The remarkable advances in cancer therapies significantly enhance the survival rates and longevity of cancer patients. Among childhood, adolescent, and young adult female cancer survivors, however, anti-cancer agents frequently cause primary ovarian insufficiency, early menopause, and infertility, primarily due to the depletion of the ovarian reserve. Oocytes, the female germ cells, exhibit a notable susceptibility to DNA damage, given that they remain in meiotic arrest at prophase I for prolonged durations, from months to years, which increases the risks of accumulating DNA damage overtime. To counteract this, a tightly controlled DNA damage response signaling ensures that only oocytes with an intact genome progress to ovulation, fertilization, and next generations. Chemotherapeutic anti-cancer agents, including doxorubicin, cisplatin, cyclophosphamide, along with irradiation, elicit DNA damage via various mechanisms, including DNA crosslinking, single- and double-strand DNA breaks, and oxidative stress. The genotoxic insults activate DDR in the oocytes, which detect and repair DNA damage or initiate apoptosis to eliminate impaired oocytes. Although several protein molecules such as DNA damage-sensing kinases, checkpoint kinases, p53 family transcription factors, and pro-apoptotic molecules have been discovered, the precise mechanisms of DDR in determining the fate of oocytes, particularly how they differ from those in somatic cells and cancer cells, remain poorly understood. From an oncofertility perspective, the current review analyzes the molecular mechanisms of anti-cancer agent-induced DDR in oocytes and discusses knowledge gaps and urgent future research directions for preserving the ovarian reserve, fertility, and endocrine functions of young female cancer patients.

Development of ovarian tumour causes significant loss of muscle and adipose tissue: a novel mouse model for cancer cachexia study

AbstractBackgroundCancer‐associated cachexia (CAC) is a complex syndrome of progressive muscle wasting and adipose loss with metabolic dysfunction, severely increasing the morbidity and mortality risk in cancer patients. However, there are limited studies focused on the underlying mechanisms of the progression of CAC due to the complexity of this syndrome and the lack of preclinical models that mimics its stagewise progression.MethodsWe characterized the initiation and progression of CAC in transgenic female mice with ovarian tumours. We measured proposed CAC biomarkers (activin A, GDF15, IL‐6, IL‐1β, and TNF‐α) in sera (n = 6) of this mouse model. The changes of activin A and GDF15 (n = 6) were correlated with the decline of bodyweight over time. Morphometry and signalling markers of muscle atrophy (n ≥ 6) and adipose tissue wasting (n ≥ 7) were assessed during CAC progression.ResultsCancer‐associated cachexia symptoms of the transgenic mice model used in this study mimic the progression of CAC seen in humans, including drastic body weight loss, skeletal muscle atrophy, and adipose tissue wasting. Serum levels of two cachexia biomarkers, activin A and GDF15, increased significantly during cachexia progression (76‐folds and 10‐folds, respectively). Overactivation of proteolytic activity was detected in skeletal muscle through up‐regulating muscle‐specific E3 ligases Atrogin‐1 and Murf‐1 (16‐folds and 14‐folds, respectively) with decreasing cross‐sectional area of muscle fibres (P < 0.001). Muscle wasting mechanisms related with p‐p38 MAPK, FOXO3, and p‐AMPKα were highly activated in concurrence with an elevation in serum activin A. Dramatic fat loss was also observed in this mouse model with decreased fat mass (n ≥ 6) and white adipocytes sizes (n = 6) (P < 0.0001). The adipose tissue wasting was based on thermogenesis, supported by the up‐regulation of uncoupling protein 1 (UCP1). Fibrosis in adipose tissue was also observed in concurrence with adipose tissue loss (n ≥ 13) (p < 0.0001).ConclusionsOur novel preclinical CAC mouse model mimics human CAC phenotypes and serum biomarkers. The mouse model in this study showed proteolysis in muscle atrophy, browning in adipose tissue wasting, elevation of serum activin A and GDF15, and atrophy of pancreas and liver. This mouse line would be the best preclinical model to aid in clarifying molecular mediators of CAC and dissecting metabolic dysfunction and tissue atrophy during the progression of CAC.