Increased dietary fatty acids determine the fatty-acid profiles of human pancreatic cancer cells and their carrier’s plasma, pancreas and liver

Primary contents of dietary fat are three or four types of fatty acids, namely saturated fatty acid (SFA), monounsaturated fatty acid (MUFA), n6-polyunsaturated fatty acid (n6PUFA) and, to less extent, n3-polyunsaturated fatty acid (n3PUFA). Previous studies suggest that increased SFA, MUFA, and n6P...

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Veröffentlicht in:	Endocrine Journal 2019, Vol.67(4), pp.387-395
Hauptverfasser:	Qiu, Shuai, Wang, Feng, Hu, Jiacai, Yang, Yong, Li, Dihua, Tian, Wencong, Yuan, Xiangfei, Lv, Yuanshan, Yu, Ming
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Sprache:	eng
Schlagworte:	Animals Cell Line, Tumor Diet, High-Fat Dietary Fats - metabolism Fatty acids Fatty Acids - blood Fatty Acids - metabolism Fatty Acids, Monounsaturated - blood Fatty Acids, Monounsaturated - metabolism Fatty Acids, Omega-3 - blood Fatty Acids, Omega-3 - metabolism Fatty Acids, Omega-6 - blood Fatty Acids, Omega-6 - metabolism Fatty-acid profile Gas chromatography High fat diet Humans Liver Liver - metabolism Liver cancer Metastases Mice Mice, Nude Neoplasm Transplantation Palmitic acid Pancreas Pancreas - metabolism Pancreatic cancer Pancreatic cancer cells Pancreatic islet transplantation Pancreatic Neoplasms - metabolism Plasma Polyunsaturated fatty acids Stearic acid
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creator	Qiu, Shuai Wang, Feng Hu, Jiacai Yang, Yong Li, Dihua Tian, Wencong Yuan, Xiangfei Lv, Yuanshan Yu, Ming
description	Primary contents of dietary fat are three or four types of fatty acids, namely saturated fatty acid (SFA), monounsaturated fatty acid (MUFA), n6-polyunsaturated fatty acid (n6PUFA) and, to less extent, n3-polyunsaturated fatty acid (n3PUFA). Previous studies suggest that increased SFA, MUFA, and n6PUFA in high fat diets (HFDs) stimulate the origination, growth, and liver metastasis of pancreatic cancer cells, whereas increased n3PUFA has the opposite effects. It is unclear whether the fatty acid-induced effects are based on changed fatty-acid composition of involved cells. Here, we investigated whether increased SFA, MUFA, n6PUFA, and n3PUFA in different HFDs determine the FA profiles of pancreatic cancer cells and their carrier’s plasma, pancreas, and liver. We transplanted MiaPaCa2 human pancreatic cancer cells in athymic mice and fed them normal diet or four HFDs enriched with SFA, MUFA, n6PUFA, and n3PUFA, respectively. After 7 weeks, fatty acids were profiled in tumor, plasma, pancreas, and liver, using gas chromatography. When tumor carriers were fed four HFDs, the fatty acids that were increased dietarily were also increased in the plasma. When tumor carriers were fed MUFA-, n6PUFA-, and n3PUFA-enriched HFDs, the dietarily increased fatty acids were also increased in tumor, pancreas, and liver. When tumor-carriers were fed the SFA-enriched HFD featuring lauric and myristic acids (C12:0 and C14:0), tumor, pancreas, and liver showed an increase not in the same SFAs but palmitic acid (C16:0) and/or stearic acid (C18:0). In conclusion, predominant fatty acids in HFDs determine the fatty-acid profiles of pancreatic cancer cells and their murine carriers.
doi_str_mv	10.1507/endocrj.EJ19-0429
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Previous studies suggest that increased SFA, MUFA, and n6PUFA in high fat diets (HFDs) stimulate the origination, growth, and liver metastasis of pancreatic cancer cells, whereas increased n3PUFA has the opposite effects. It is unclear whether the fatty acid-induced effects are based on changed fatty-acid composition of involved cells. Here, we investigated whether increased SFA, MUFA, n6PUFA, and n3PUFA in different HFDs determine the FA profiles of pancreatic cancer cells and their carrier’s plasma, pancreas, and liver. We transplanted MiaPaCa2 human pancreatic cancer cells in athymic mice and fed them normal diet or four HFDs enriched with SFA, MUFA, n6PUFA, and n3PUFA, respectively. After 7 weeks, fatty acids were profiled in tumor, plasma, pancreas, and liver, using gas chromatography. When tumor carriers were fed four HFDs, the fatty acids that were increased dietarily were also increased in the plasma. When tumor carriers were fed MUFA-, n6PUFA-, and n3PUFA-enriched HFDs, the dietarily increased fatty acids were also increased in tumor, pancreas, and liver. When tumor-carriers were fed the SFA-enriched HFD featuring lauric and myristic acids (C12:0 and C14:0), tumor, pancreas, and liver showed an increase not in the same SFAs but palmitic acid (C16:0) and/or stearic acid (C18:0). 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Previous studies suggest that increased SFA, MUFA, and n6PUFA in high fat diets (HFDs) stimulate the origination, growth, and liver metastasis of pancreatic cancer cells, whereas increased n3PUFA has the opposite effects. It is unclear whether the fatty acid-induced effects are based on changed fatty-acid composition of involved cells. Here, we investigated whether increased SFA, MUFA, n6PUFA, and n3PUFA in different HFDs determine the FA profiles of pancreatic cancer cells and their carrier’s plasma, pancreas, and liver. We transplanted MiaPaCa2 human pancreatic cancer cells in athymic mice and fed them normal diet or four HFDs enriched with SFA, MUFA, n6PUFA, and n3PUFA, respectively. After 7 weeks, fatty acids were profiled in tumor, plasma, pancreas, and liver, using gas chromatography. When tumor carriers were fed four HFDs, the fatty acids that were increased dietarily were also increased in the plasma. When tumor carriers were fed MUFA-, n6PUFA-, and n3PUFA-enriched HFDs, the dietarily increased fatty acids were also increased in tumor, pancreas, and liver. When tumor-carriers were fed the SFA-enriched HFD featuring lauric and myristic acids (C12:0 and C14:0), tumor, pancreas, and liver showed an increase not in the same SFAs but palmitic acid (C16:0) and/or stearic acid (C18:0). 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Previous studies suggest that increased SFA, MUFA, and n6PUFA in high fat diets (HFDs) stimulate the origination, growth, and liver metastasis of pancreatic cancer cells, whereas increased n3PUFA has the opposite effects. It is unclear whether the fatty acid-induced effects are based on changed fatty-acid composition of involved cells. Here, we investigated whether increased SFA, MUFA, n6PUFA, and n3PUFA in different HFDs determine the FA profiles of pancreatic cancer cells and their carrier’s plasma, pancreas, and liver. We transplanted MiaPaCa2 human pancreatic cancer cells in athymic mice and fed them normal diet or four HFDs enriched with SFA, MUFA, n6PUFA, and n3PUFA, respectively. After 7 weeks, fatty acids were profiled in tumor, plasma, pancreas, and liver, using gas chromatography. When tumor carriers were fed four HFDs, the fatty acids that were increased dietarily were also increased in the plasma. When tumor carriers were fed MUFA-, n6PUFA-, and n3PUFA-enriched HFDs, the dietarily increased fatty acids were also increased in tumor, pancreas, and liver. When tumor-carriers were fed the SFA-enriched HFD featuring lauric and myristic acids (C12:0 and C14:0), tumor, pancreas, and liver showed an increase not in the same SFAs but palmitic acid (C16:0) and/or stearic acid (C18:0). In conclusion, predominant fatty acids in HFDs determine the fatty-acid profiles of pancreatic cancer cells and their murine carriers.</abstract><cop>Japan</cop><pub>The Japan Endocrine Society</pub><pmid>31827053</pmid><doi>10.1507/endocrj.EJ19-0429</doi><tpages>9</tpages><oa>free_for_read</oa></addata></record>
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subjects	Animals Cell Line, Tumor Diet, High-Fat Dietary Fats - metabolism Fatty acids Fatty Acids - blood Fatty Acids - metabolism Fatty Acids, Monounsaturated - blood Fatty Acids, Monounsaturated - metabolism Fatty Acids, Omega-3 - blood Fatty Acids, Omega-3 - metabolism Fatty Acids, Omega-6 - blood Fatty Acids, Omega-6 - metabolism Fatty-acid profile Gas chromatography High fat diet Humans Liver Liver - metabolism Liver cancer Metastases Mice Mice, Nude Neoplasm Transplantation Palmitic acid Pancreas Pancreas - metabolism Pancreatic cancer Pancreatic cancer cells Pancreatic islet transplantation Pancreatic Neoplasms - metabolism Plasma Polyunsaturated fatty acids Stearic acid
title	Increased dietary fatty acids determine the fatty-acid profiles of human pancreatic cancer cells and their carrier’s plasma, pancreas and liver
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