Levels of the Autophagy-Related 5 Protein Affect Progression and Metastasis of Pancreatic Tumors in Mice

[Background and Aims]: Cells in pancreatic ductal adenocarcinoma (PDAC) undergo autophagy, but its effects vary with tumor stage and genetic factors. We investigated the consequences of varying levels of the autophagy related 5 (Atg5) protein on pancreatic tumor formation and progression. [Methods]: We generated mice that express oncogenic Kras in primary pancreatic cancer cells and have homozygous disruption of Atg5 (A5;Kras) or heterozygous disruption of Atg5 (A5+/–;Kras), and compared them with mice with only oncogenic Kras (controls). Pancreata were analyzed by histology and immunohistochemistry. Primary tumor cells were isolated and used to perform transcriptome, metabolome, intracellular calcium, extracellular cathepsin activity, and cell migration and invasion analyses. The cells were injected into wild-type littermates, and orthotopic tumor growth and metastasis were monitored. Atg5 was knocked down in pancreatic cancer cell lines using small hairpin RNAs; cell migration and invasion were measured, and cells were injected into wild-type littermates. PDAC samples were obtained from independent cohorts of patients and protein levels were measured on immunoblot and immunohistochemistry; we tested the correlation of protein levels with metastasis and patient survival times. [Results]: A5+/–;Kras mice, with reduced Atg5 levels, developed more tumors and metastases, than control mice, whereas A5;Kras mice did not develop any tumors. Cultured A5+/–;Kras primary tumor cells were resistant to induction and inhibition of autophagy, had altered mitochondrial morphology, compromised mitochondrial function, changes in intracellular Ca2+ oscillations, and increased activity of extracellular cathepsin L and D. The tumors that formed in A5+/–;Kras mice contained greater numbers of type 2 macrophages than control mice, and primary A5+/–;Kras tumor cells had up-regulated expression of cytokines that regulate macrophage chemoattraction and differentiation into M2 macrophage. Knockdown of Atg5 in pancreatic cancer cell lines increased their migratory and invasive capabilities, and formation of metastases following injection into mice. In human PDAC samples, lower levels of ATG5 associated with tumor metastasis and shorter survival time. [Conclusions]: In mice that express oncogenic Kras in pancreatic cells, heterozygous disruption of Atg5 and reduced protein levels promotes tumor development, whereas homozygous disruption of Atg5 blocks tumorigenesis. Therapeutic strategies to alter autophagy in PDAC should consider the effects of ATG5 levels to avoid the expansion of resistant and highly aggressive cells.This study was supported in part by the Mildred-Scheel-Professur der Deutschen Krebshilfe 111464, DFG AL 1174/6-1 to H.A., DFG DI 2299/1-1 to K.N.D., DFG SFB1321 (S01) to K.S. and W.W., and the German Federal Ministry of Education and Research to the German Center for Diabetes Research (DZD e.V.) to J.A

Physiological and pathological intracellular calcium release in human and murine pancreatic acinar cells

Sustained, toxic elevations of pancreatic acinar cell cytosolic free calcium ion concentration ([Ca2+]C), such as those observed with supramaximal secretagogue stimulation (CCK) are implicated in acute pancreatitis. However, Cholecystokinin (CCK) has been thought to act only indirectly on human pancreatic acinar cells via vagal nerve stimulation, rather than by direct CCK receptor activation as observed in rodent pancreatic acinar cells. However, in the series of experiments presented here using human pancreatic acinar cells, CCK at physiological concentrations (1-20 pM) elicited rapid, robust, oscillatory rises of the cytosolic Ca2+ ion concentration ([Ca2+]C), showing apical to basal progression in acinar cells, in the presence of atropine and tetrodotoxin. The [Ca2+]C rises were followed by increases in mitochondrial ATP production and secretion, concluding that CCK acts directly on acinar cells in the human pancreas. The earliest pathological mechanisms, such as sustained, toxic elevations of the acinar cytosolic free calcium ion concentration ([Ca2+]C), incriminated in experimental pancreatitis have been previously demonstrated by non-oxidative metabolites of ethanol (FAEE’s), as well as bile salts, at supramaximal concentrations. However, in the clinical situation such hyperstimulation is unlikely to occur. To simulate a more clinically relevant stimulus, pancreatic acinar cells were stimulated with lower doses of FAEE’s and/or bile salts in combination with physiological doses of secretagogues - a process which may precipitate pancreatitis clinically. Illustrated here, the toxic transformation of secretagogue induced physiological Ca2+ signalling occurs with the perfusion of low doses of TLCS and POAEE resulting in cell injury. The intracellular second messengers implicated are IP3, cADPR and NAADP with the IP3 receptor channel pivotal with both toxins. However, as previously demonstrated with supramaximal concentrations of POAEE, if supplementary ATP is added to the intracellular milieu, cellular injury is avoided with continued extrusion of large quantities of Ca2+ from the cytosol indicating functional Ca2+ ATPase pumps. This is not observed in cells which do not receive supplementary ATP. The toxic sustained Ca2+ elevation is also be prevented by the removal of external Ca2+ or blockade of IP3 receptor using caffeine and cell injury is again avoided. Therefore, it may be concluded, that it is the large, sustained toxic [Ca2+]c load which impairs mitochondrial function and ATP production leading to Ca2+ATPase pump failure and ultimately cell death. Lowering sustained intracellular [Ca2+]c by blockade of IP3 receptor channels may reduce cell injury in clinical acute pancreatitis.EThOS - Electronic Theses Online ServiceGBUnited Kingdo