BACKGROUND: The liver of the host with cancer requires increased amounts of amino acids to support the synthesis of glucose and key defense proteins. To study the effect of the growing tumor on hepatic amino acid uptake, the authors measured hepatic transport activity in tumor-bearing rats and in rats at various times after tumor resection. METHODS: Fischer-344 rats were implanted subcutaneously with methylcholanthrene-induced fibrosarcoma cells (MCA sarcoma). When the tumors reached 10% of body weight, hepatic amino acid transport activity was assayed or the animals underwent surgical removal of the tumor. In animals that underwent tumor excision, livers were removed at 1, 3, or 5 days post-resection, and hepatic plasma membrane vesicles (HPMVs) were prepared. Nontumor-bearing pair-fed rats undergoing sham implantation or sham resection served as controls. System N (glutamine), System A (MeAIB), and System y+ (arginine) transport activity were assayed, which allowed the authors to compare differences in tumor-induced rates of transport and the influence of resection on transport activity. RESULTS: System A transport activity was unaltered by tumor growth. In contrast, the presence of the growing tumor increased arginine and glutamine uptake by the liver. Hepatic glutamine transport remained elevated for 5 days after tumor resection, although by postoperative day 5 there was a trend toward normalization. In contrast, arginine transport remained increased by twofold onpost-resection day 1 and had normalized by postoperative day 3. The enhanced arginine transport was a result of an increase in maximal transport velocity (Vmax) rather than a change in carrier affinity. CONCLUSIONS: Increases in hepatic amino acid transport normalize within several days of tumor resection, indicating a key role for the tumor in the induction of this response. The observation that hepatic glutamine transport activity remains augmented after tumor resection longer than any other transporter studied suggests a key role for this amino acid in overall hepatic nitrogen metabolism and may partially explain the persistent glutamine depletion that is characteristic of the tumor-bearing host.
BACKGROUND: The liver of the host with cancer requires increased amounts of amino acids to support the synthesis of glucose and key defense proteins. To study the effect of the growing tumor on hepatic amino acid uptake, the authors measured hepatic transport activity in tumor-bearing rats and in rats at various times after tumor resection. METHODS: Fischer-344 rats were implanted subcutaneously with methylcholanthrene-induced fibrosarcoma cells (MCA sarcoma). When the tumors reached 10% of body weight, hepatic amino acid transport activity was assayed or the animals underwent surgical removal of the tumor. In animals that underwent tumor excision, livers were removed at 1, 3, or 5 days post-resection, and hepatic plasma membrane vesicles (HPMVs) were prepared. Nontumor-bearing pair-fed rats undergoing sham implantation or sham resection served as controls. System N (glutamine), System A (MeAIB), and System y+ (arginine) transport activity were assayed, which allowed the authors to compare differences in tumor-induced rates of transport and the influence of resection on transport activity. RESULTS: System A transport activity was unaltered by tumor growth. In contrast, the presence of the growing tumor increased arginine and glutamine uptake by the liver. Hepatic glutamine transport remained elevated for 5 days after tumor resection, although by postoperative day 5 there was a trend toward normalization. In contrast, arginine transport remained increased by twofold onpost-resection day 1 and had normalized by postoperative day 3. The enhanced arginine transport was a result of an increase in maximal transport velocity (Vmax) rather than a change in carrier affinity. CONCLUSIONS: Increases in hepatic amino acid transport normalize within several days of tumor resection, indicating a key role for the tumor in the induction of this response. The observation that hepatic glutamine transport activity remains augmented after tumor resection longer than any other transporter studied suggests a key role for this amino acid in overall hepatic nitrogen metabolism and may partially explain the persistent glutamine depletion that is characteristic of the tumor-bearing host.