Renal CO2 production from glutamine and lactate as a function of arterial perfusion pressure in dog

Localization of members of MCT monocarboxylate transporter family Slc16 in the kidney and regulation during metabolic acidosis

The monocarboxylate transporter family (MCT) comprises 14 members with distinct transport properties and tissue distribution. The kidney expresses several members of the MCT family, but only little is known about their exact distribution and function. Here, we investigated selected members of the MCT family in the mouse kidney. MCT1, MCT2, MCT7, and MCT8 localized to basolateral membranes of the epithelial cells lining the nephron. MCT1 and MCT8 were detected in proximal tubule cells whereas MCT7 and MCT2 were located in the thick ascending limb and the distal tubule. CD147, a β-subunit of MCT1 and MCT4, showed partially overlapping expression with MCT1 and MCT2. However, CD147 was also found in intercalated cells. We also detected SMCT1 and SMCT2, two Na+-dependent monocarboxylate cotransporters, on the luminal membrane of type A intercalated cells. Moreover, mice were given an acid load for 2 and 7 days. Acidotic animals showed a marked but transient increase in urinary lactate excretion. During acidosis, a downregulation of MCT1, MCT8, and SMCT2 was observed at the mRNA level, whereas MCT7 and SMCT1 showed increased mRNA abundance. Only MCT7 showed lower protein abundance whereas all other transporters remained unchanged. In summary, we describe for the first time the localization of various MCT transporters in mammalian kidney and demonstrate that metabolic acidosis induces a transient increase in urinary lactate excretion paralleled by lower MCT7 protein expression.

Glutamate transporters in kidney and brain

Glutamate transporters play important roles in the termination of excitatory neurotransmission and in providing cells with glutamate for metabolic purposes. In the kidney, glutamate transporters are involved in reabsorption of filtered acidic amino acids, regulation of ammonia and bicarbonate production, and protection of cells against osmotic stress.

Glucocorticoid and acid-base homeostasis: effects on glutamine metabolism and transport

The amino acid glutamine serves as a major fuel, powering tubular transport processes and base generation in the kidneys of acidotic animals. Removing the adrenals limits the kidneys' response to an exogenous acid load and impairs the removal rate of glutamine from the blood. Administering glucocorticoid to adrenalectomized (ADX) rats reverses a small net release of glutamine to uptake; similarly, administering an exogenous acid load to ADX rats restores the kidneys to organs of net extraction. Glucocorticoid-induced uptake is substantially less than the filtered glutamine load in contrast to uptake across both the luminal and basolateral surfaces when filtered HCO3- is reduced. Furthermore, mitochondrial glutamine oxidation is glucocorticoid dependent with a distinct impairment exhibited by the ADX acidotic rat kidney. However, combining the effect of reduced filtered HCO3- with glucocorticoid supplementation results in a marked potentiation of glutamine uptake coupled to oxidation. These results are consistent with a proposed proximal tubule cell model in which basolateral glutamine uptake is inversely related to basolateral HCO3- efflux and coupled, in the presence of glucocorticoid, to mitochondrial oxidation. This model of glucocorticoid-induced ammoniagenesis predicts an increased renal work capacity when basolateral transport of a major metabolic fuel, glutamine, is closely coupled to its oxidative metabolism.

Isolation of tumor-secreted products from human carcinoma cells maintained in a defined protein-free medium

A protein-free synthetic cell-growth medium has been defined that permits long-term survival (greater than 120 days) of an established human colon tumor cell line, HT-29. Viability is dependent upon both the concentration of L-glutamine in the medium and the cell density at the time of initial transfer into it. Cell proliferation is minimal, thus obviating the necessity for subculturing. HT-29 adenocarcinoma cells maintained in large-scale culture with this medium continue to secrete the established colon tumor marker carcinoembryonic antigen as well as growth factors and lysozyme. These and, potentially, other important tumor-derived products can therefore be generated continuously in such cultures so that they can be isolated from a conditioned medium free of contaminating serum and protein supplements.