Barrie P. Bode

Glutamine as a regulator of DNA and protein biosynthesis in human solid tumor cell lines.

OBJECTIVE The transport of glutamine by six different human solid tumor-derived cell lines (e.g., breast, colon, liver) was characterized and the impact of glutamine deprivation on rates of tumor cell proliferation and DNA and protein synthesis was assayed. SUMMARY BACKGROUND DATA Glutamine is added routinely to cell culture media and its importance for cellular growth has been established. However, carrier-mediated glutamine transport by solid tumors has not been studied extensively, and the mechanisms by which glutamine contributes to cell growth regulation require further investigation. METHODS In a panel of different human solid tumor-derived cells, sodium-dependent glutamine transport was characterized in vitro and rates of cell proliferation, protein and DNA synthesis, as well as thymidine transport, were correlated with glutamine concentrations in the culture media. RESULTS In all cells, regardless of tissue origin, sodium-dependent glutamine transport was mediated almost exclusively by a single carrier. There was a range of Michaelis constants (Km) and maximal transport velocities (Vmax) for the glutamine transporter in each cell type, but the amino acid inhibition profiles were nearly identical, consistent with uptake by the System ASC family of transporters. Rates of cell growth, DNA and protein synthesis, and thymidine transport correlated with the glutamine concentration in the culture media, indicating the central role of this amino acid in regulating cellular proliferation. CONCLUSIONS These data indicate that glutamine transport by all solid tumors is mediated by the System ASC family of transporters. The variation in Km values suggests that some cancers may be better suited to survive in a low glutamine environment than others. The mechanism by which glutamine supports cell proliferation and regulates cell cycle kinetics involves its modulation of DNA and protein biosynthetic rates.

Rat liver endothelial cell glutamine transporter and glutaminase expression contrast with parenchymal cells

Despite the central role of the liver in glutamine homeostasis in health and disease, little is known about the mechanism by which this amino acid is transported into sinusoidal endothelial cells, the second most abundant hepatic cell type. To address this issue, the transport ofl-glutamine was functionally characterized in hepatic endothelial cells isolated from male rats. On the basis of functional analyses, including kinetics, cation substitution, and amino acid inhibition, it was determined that a Na+-dependent carrier distinct from system N in parenchymal cells, with properties of system ASC or B0, mediated the majority of glutamine transport in hepatic endothelial cells. These results were supported by Northern blot analyses that showed expression of the ATB0 transporter gene in endothelial but not parenchymal cells. Concurrently, it was determined that, whereas both cell types express glutamine synthetase, hepatic endothelial cells express the kidney-type glutaminase isozyme in contrast to the liver-type isozyme in parenchymal cells. This represents the first report of ATB0 and kidney-type glutaminase isozyme expression in the liver, observations that have implications for roles of specific cell types in hepatic glutamine homeostasis in health and disease.Despite the central role of the liver in glutamine homeostasis in health and disease, little is known about the mechanism by which this amino acid is transported into sinusoidal endothelial cells, the second most abundant hepatic cell type. To address this issue, the transport of L-glutamine was functionally characterized in hepatic endothelial cells isolated from male rats. On the basis of functional analyses, including kinetics, cation substitution, and amino acid inhibition, it was determined that a Na+-dependent carrier distinct from system N in parenchymal cells, with properties of system ASC or B0, mediated the majority of glutamine transport in hepatic endothelial cells. These results were supported by Northern blot analyses that showed expression of the ATB0 transporter gene in endothelial but not parenchymal cells. Concurrently, it was determined that, whereas both cell types express glutamine synthetase, hepatic endothelial cells express the kidney-type glutaminase isozyme in contrast to the liver-type isozyme in parenchymal cells. This represents the first report of ATB0 and kidney-type glutaminase isozyme expression in the liver, observations that have implications for roles of specific cell types in hepatic glutamine homeostasis in health and disease.

Protein kinase C regulates nutrient uptake and growth in hepatoma cells

BACKGROUND Human hepatoma cells extract glutamine at rates severalfold greater than normal hepatocytes through a high-affinity transporter encoded by the ATB0 gene, which contains two putative phosphorylation sites for protein kinase C (PKC). The studies presented here were undertaken to determine whether System B0-mediated glutamine uptake regulates hepatoma growth and whether PKC regulates the activity of this transporter. METHODS SK-Hep cells were treated with the PKC activator phorbol 12-myristate 13-acetate (PMA) and the initial-rate transport of glutamine and other nutrients measured at specific times thereafter. Growth rates were monitored during culture +/- PMA or an excess of system B0 substrates relative to glutamine. RESULTS PMA treatment exerted a rapid (half-life approximately 15 minutes) concentration-dependent inhibition of glutamine uptake rates to 50% of control values via a posttranslational mechanism that decreased transporter maximum velocity. This effect persisted after 24 hours and was abrogated by the PKC inhibitor staurosporine. PMA also significantly decreased amino acid transport System y+ and System L activities but no System A. Chronic treatment with PMA (PKC depletion) inhibited SK-Hep growth, as did attenuation of System B0-mediated glutamine uptake with other B0 substrates. CONCLUSIONS System B0-mediated glutamine uptake regulates hepatoma cell growth, whereas PKC influences both processes.

Adaptive regulation of amino acid transport in nutrient-deprived human hepatomas

BACKGROUND Malignant cells require increased amounts of amino acids, in particular glutamine and leucine, to support DNA and protein biosynthesis. Although plasma concentrations in the center of solid tumors can be much lower than normal circulating levels, it is still unknown how tumor cells can survive despite low amino acid levels. We examined the effects of glutamine or leucine deprivation on cell growth and amino acid transport activity in two human hepatoma cell lines, SK-Hep and HepG2. METHODS We studied the transport of glutamine, leucine, alanine, and arginine. The carrier-mediated uptake of 3H-amino acids was determined in cells cultured in normal and amino acid-deprived media. RESULTS The growth of both cell lines was dependent on the concentration of glutamine and leucine. In SK-Hep, there was a significant increase in initial rate glutamine transport activity in the glutamine-deprived group, attributable to an increase in transporter affinity (Km; 0.6 mmol/L [control], 385 +/- 43 mumol/L; 0.1 mmol/L, 221 +/- 11 mumol/L; P < 0.01). At low glutamine concentration, the saturable Na(+)-independent uptake of leucine and arginine as well as the Na(+)-dependent uptake of alanine increased significantly in both SK-Hep and HepG2. Similarly, in leucine-deprived SK-Hep cells, leucine uptake increased twofold, but the change was attributable to an enhanced transporter capacity (Vmax; 0.2 mmol/L [control], 38,900 +/- 700; 0.0 mmol/L, 75,900 +/- 4,900 pmol/mg protein per minute; P < 0.001). CONCLUSIONS Adaptive increases in initial rate amino acid transport activities were elicited by glutamine and leucine deprivation in these two human hepatoma cell lines. Decreased extracellular amino acid levels encountered by tumors in vivo may elicit similar adaptive responses that contribute to the maintenance of cytoplasmic levels of amino acids essential for growth.

Stimulation of rat hepatic amino acid transport by burn injury

Burn injury accelerates hepatic amino acid metabolism, but the role of transmembrane substrate delivery in this response has not been investigated. We therefore studied the effects of cutaneous scald injury on the Na+-dependent transport of glutamine and alanine in isolated rat liver plasma membrane vesicles. Scald injury resulted in liver damage and a 1.4- to 2.3-fold and 1.5- to 2.8-fold stimulation of hepatic transport rates for glutamine and alanine, respectively, proportional to the total burned surface area (TBSA) after 24 hours. Enhanced uptake of glutamine and alanine was attributable to increases in the maximum velocity (Vmax) of system N and system A activities, respectively. Hepatic amino acid transport activity remained elevated in vesicles from burned animals after 72 hours, but the degree of stimulation (1.3- to 1.7-fold for glutamine and 1.3- to 1.6-fold for alanine) was less than that observed 24 hours after thermal injury. Liver function tests returned to control values after 72 hours as well, indicating rectification of hepatic damage. In contrast to the induction of hepatic system A and system N activity in catabolic states such as cancer and endotoxemia, further studies showed that tumor necrosis factor (TNF) failed to play a significant role in burn-stimulated amino acid transport rates. When combined with plasma liver enzyme profiles, early transient hepatic amino acid transporter stimulation may support amino acid-dependent pathways involved in the repair of burn-dependent hepatic damage.

Induction of glutamine synthetase expression after major burn injury is tissue specific and temporally variable

BACKGROUND Major burn injury results in a translocation of amino acids from peripheral tissues to the abdominal viscera. Glutamine is a major participant in this event. Thermal injury causes a depletion of plasma and muscle glutamine pools as well as activation of proteolysis and release of glutamine from skeletal muscle. De novo synthesis of glutamine is regulated by the expression of the enzyme glutamine synthetase (GS). We studied the tissue-specific regulation of GS expression after thermal injury. METHODS Burn injury of rats was produced by scalding of 25 or 40% of skin surface. In normal rats, four organs, including lung, muscle, kidney, and liver were assayed for relative GS messenger RNA content by Northern blotting 8 and 24 hours after 40% area burn. The effect of adrenalectomy on GS mRNA induction in muscle was assessed 24 hours after 25% area burn injury. RESULTS GS mRNA levels were increased 2.3-fold in lung at 8 hours and 7.3-fold in muscle at 24 hours after burn injury. No appreciable increase in GS mRNA level was observed in kidney or liver. Muscle GS mRNA levels were lower than sham-operated controls in both burned and unburned adrenalectomized rats. However, adrenalectomy did not attenuate relative GS mRNA induction in muscle at 24 hours after burn injury. CONCLUSIONS Burn injury causes an induction in GS mRNA levels in a tissue-specific fashion. Adrenalectomy greatly reduced GS mRNA levels, but did not completely block the induction of GS express in muscle after burn injury. This finding suggests that glucocorticoid hormones together with a unknown factor of nonadrenal origin influence this metabolic response to burn injury.

Characterization of l-leucine transport system in brush border membranes from human and rabbit small intestine☆

The branched-chain amino acids (BCAAs) leucine, isoleucine, and valine are beneficial to catabolic patients by improving hepatic protein synthesis and nitrogen economy, yet their transport from the intestinal lumen is not well-defined. The leucine transport system in human and rabbit small intestine was characterized using a brush border membrane vesicle (BBMV) model. Sodium and pH dependence and transport activity along the longitudinal axis of the small bowel were determined. Transport kinetics and inhibition profiles were defined. Although previous studies in other tissues show leucine transport to be mostly a Na+-independent process, our studies show that leucine transport is a predominantly Na+-dependent process occurring mainly via a single saturable pH-independent transporter resembling system B0 in the intestine. This system B0 transporter demonstrates stereoisomeric specificity. There is also a minor Na+-independent transport component (<6% in rabbits). Leucine uptake in both rabbits and humans is significantly greater than the uptake of other clinically relevant nutrients such as glutamine. In the rabbit, ileal leucine transport is significantly greater than jejunal uptake. While the affinities of the human and rabbit transporters are similar, the rabbit transporter has greater carrier capacity (maximal transport velocity [Vmax]). These findings suggest that the transport of leucine in the gut mucosa is significantly different from the transport in other tissues.

Asparagine uptake in rat hepatocytes: resolution of a paradox and insights into substrate-dependent transporter regulation.

Summary. Extracellular asparagine has previously been shown to markedly stimulate both ornithine decarboxylase and System N-mediated glutamine transport activities in hepatocytes by a transport-dependent mechanism. However, as a weak substrate of its inferred transporter System N, the specific route of asparagine uptake has remained enigmatic. In this study, asparagine transport was studied in detail and shown to be Na+-dependent, Li+-tolerant, stereospecific, and inhibited profoundly by glutamine and histidine. Coupled with competitive inhibition by glutamine (Ki = 2.63 ± 1.11 mM), the data indicated that asparagine was indeed slowly transported by System N in rat hepatocytes, albeit at rates an order of magnitude less than for glutamine. The differential substrate transport velocities were shown to be attributable to a low transporter asparagine affinity (Km = 9.3 − 17.5 mM) compared to glutamine (Km∼ 1 mM). Consistent with its slow uptake, asparagine accumulated to a fivefold lesser degree than glutamine after 60 min, yet stimulated System N activity to the same extent as glutamine. The transaminase inhibitor aminooxyacetate and starvation of the donor animal each enhanced asparagine uptake twofold and augmented subsequent transporter activation. Conversely, asparagine-dependent System N stimulation was abrogated by hyperosmotic media and blunted 30%–40% by phosphatidylinositol 3-kinase (PI3K) inhibitors wortmannin and LY294002. Collectively, the data suggest that System N-mediated asparagine uptake serves an autostimulatory role, mediated by cellular swelling and in part by a PI3K-dependent signal transduction pathway.

Amino acid metabolism and the vascular endothelium: Regulation and disease implications

Amino acid metabolism by the vascular endothelium is a complex process that often begins with the carrier-mediated uptake of circulating amino acids into the endothelial cytoplasm. Amino acids are essential for maintaining intact endothelial functions, which include cell proliferation, regulation of blood flow and vascular tone, coagulation and fibrinolysis, and metabolism of a variety of macromolecules. The disturbances in endothelial amino acid transport and metabolism that occur during infection and inflammation are due, in part, to changes in substrate availability and to the local and/or systemic elaboration of specific mediators. An improved understanding of endothelial amino acid metabolism will not only provide new knowledge regarding disease mechanisms and regulation, but may also lead to new treatment strategies that may include the clinical use of specific nutritional formulas.

Novel control of the position-dependent expression of genes in hepatocytes: the Glut-1 transporter.

The purpose of this study was to elucidate the mechanisms responsible for the restricted position-dependent expression of the Glut-1 glucose transporter in the plasma membrane to a small population of parenchymal cells in rat liver. On the basis of earlier studies in which the erythroid/brain (Glut-1) glucose transporter isoform was detected by immunofluorescence only in the last two hepatocytes surrounding the terminal hepatic venule,1 investigators in Jorge Gumucios laboratory at the University of Michigan sought to determine the molecular basis for the observation. To study the expression of this transporter in individual hepatocyte populations (periportal vs perivenous), the authors used the digitonin/collagenase cell isolation method. Their conclusions rest on two assumptions: (1) the modified digitonin/collagenase method of hepatocyte isolation used in the studies adequately separates periportal and perivenous cells, and (2) the Glut-1 protein distribution in isolated hepatocyte populations reflect...