Differential physiological expression of the invertebrate 2Na+/1H+ antiporter in single epithelial cell type suspensions of lobster hepatopancreas

Lobster (Homarus americanus) hepatopancreas is a complex, heterogeneous tissue composed of four epithelial cell types that individually contribute to the overall functional properties of digestion, absorption, secretion, and detoxification. Previous studies, using purified hepatopancreatic brush border membrane vesicles, have described the properties of an electrogenic, 2Na+/1H+ antiporter in this tissue that regulates the absorption and secretion of these cations. These studies were not able to localize this cation exchange phenomenon to specific epithelial cell types. In the present study, sodium/proton exchange by purified, single cell, suspensions of lobster (Homarus americanus) hepatopancreatic epithelium was investigated using a centrifugal elutriation method to cleanly separate the four individual cell types for subsequent physiological characterization. Results indicate that all four hepatopancreatic epithelial cell types possessed the 2Na+/1H+ antiporter as a result of its unique sigmoidal influx properties. Hill Coefficients, measures of transport sigmodicity obtained from kinetic analyses of 22Na+ influx by single cell type suspensions, varied from 1.56 +/- 0.30 (R-cell suspensions) to 2.79 +/- 0.41 (F-cell suspensions), suggesting that different numbers of sodium ions may be accommodated by each cell type. Both calcium and zinc were competitive inhibitors of 22Na+ influx in E-cells (calcium Ki = 105.1+/-5.2 microM; zinc Ki = 46.2 +/- 7.8 microM), but the extent to which these divalent cations inhibited monovalent cation transport by each cell type varied. It is concluded that different isoforms of the electrogenic 2Na+/1H+ antiporter may be present in each hepatopancreatic cell type and thereby contribute in differing degrees to the cation regulatory functions performed by the overall organ.     

Cellular localization of calcium, heavy metals, and metallothionein in lobster (Homarus americanus) hepatopancreas

This investigation combines confocal microscopy with the cation-specific fluorescent dyes Fluo-3 and BTC-5N to localize calcium and heavy metals along the length of intact lobster (Homarus americanus) hepatopancreatic tubules and isolated cells. A metallothionein-specific antibody, developed in mollusks with cross-reactivity in crustaceans, showed the tissue-specific occurrence of this metal-binding protein in several organ systems in lobster and in single cell types isolated from lobster hepatopancreas. Individual lobster hepatopancreatic epithelial cell types were separated into pure single cell type suspensions for confocal and antibody experiments. Intact hepatopancreatic tubules showed high concentrations of both calcium and heavy metals at the distal tips of tubules where mitotic stem cells (E-cells) are localized. In addition, a concentrated distribution of calcium signal within isolated single premolt E-cells in solution was disclosed that might suggest an endoplasmic reticulum compartmentation of this cation within these stem cells. Both E- and R-cells showed significantly (P < 0.05) greater intracellular calcium concentrations in premolt than intermolt, suggesting the accumulation of this cation in these cells prior to the molt. Antibody studies with lobster tissues indicated that the hepatopancreas possessed 5-10 times the metallothionein concentration as other lobster organ systems and that isolated E-cells from the hepatopancreas displayed more than twice the binding protein concentrations of other cells of this organ or those of blood cells. These results suggest that crustacean hepatopancreatic stem cells (E-cells) and R-cells play significant roles in calcium and heavy metal homeostasis in this tissue. Interactions between the four hepatopancreatic cell types in this regulatory activity remain to be elucidated.     

Expression of Na(+) / D-glucose cotransport in Xenopus laevis oocytes by injection of poly(A)(+) RNA isolated from lobster (Homarus americanus) hepatopancreas

Xenopus laevis oocytes were used for expression and characterization of lobster (Homarus americanus) hepatopancreas Na(+)-dependent D-glucose transport activity. Poly(A)(+) RNA from the whole hepatopancreatic tissue was injected and transport activity was assayed by alpha-D-[2-(3)H] glucose. Injection of lobster hepatopancreatic poly(A)(+) RNA resulted in a dose (1-20 ng) and time (1-5 days) dependent increase of Na(+)-dependent D-glucose uptake. Kinetics of Na(+)-dependent glucose transport was a hyperbolic function (K(m)=0.47+/-0.04 mM) of external D-glucose concentration and a sigmoidal function (K(Na)=68.32+/-1.57 mM; Hill coefficient=2.22+/-0.09) of external Na(+) concentration. In addition, Na(+)-dependent D-glucose uptake was significantly inhibited by both (0.1-0.5 mM) phloridzin and (0.1-0.5 mM) methyl-alpha-D-glucopyranoside. After size fractionation through a sucrose density gradient, poly(A)(+) RNA fractions with an average length of 2-4 kb induced a twofold increase in Na(+)-dependent phloridzin-inhibited D-glucose uptake as compared to total poly(A)(+) RNA-induced uptake. The results of this study provide the functional basis to screen lobster hepatopancreatic cDNA libraries for clones encoding putative and still not known crustacean SGLT-type Na(+)/glucose co-transporter(s).     

Lobster hepatopancreatic epithelial single cell suspensions as models for electrogenic sodium-proton exchange

Sodium-proton antiporters, also called Na+/H+ exchangers (NHE), are vital transmembrane proteins involved in multiple cellular functions including transepithelial ion transport and Na+ homeostasis of cells throughout the biological kingdom. Na+/H+ exchange is accelerated by cytosolic acidification and also by osmotically induced cell shrinking, thereby promoting recovery of the physiological pHi and volume. Eight isoforms of Na+/H+ exchangers have been cloned and characterized to date and share the same overall structure, but exhibit differences with respect to cellular localization, kinetic variables and plasma membrane targeting, in polarized epithelial cells. The electrogenic Na+ absorption across tight epithelia from invertebrates follow significantly different principles from the electroneutral Na+/H+ antiporter found in vertebrates. In all invertebrate cells examined, the antiporter displayed a 2Na+/1H+ transport stoichiometry and this transport was markedly inhibited by exogenous calcium and zinc. Na+/H+ exchangers (NHE) are present in crustacean hepatopancreatic cell type suspensions and are believed to function in acid-base regulation by driving the extrusion of protons across the hepatopancreatic epithelium in exchange for Na+ in the sea water. A brief review of current knowledge about Na+/H+ exchangers has been presented. In addition, understanding of hepatopancreatic Na+/H+ exchange is described as obtained after isolation of purified E-, R-, F- and B-cell suspensions from the whole organ by centrifugal elutriation.     

Food digestion by cathepsin L and digestion-related rapid cell differentiation in shrimp hepatopancreas

Cathepsin L (CatL) has been readily localized in the large vacuole and in the apical complex of the digestive B-cell of the shrimp hepatopancreas. Immunogold technique revealed the occurrence of CatL in zymogen granule, digestive body and digestive vacuole of the B-cell in the hepatopancreas of Metapenaeus ensis. Coalescences of zymogen granule with sub-apical vacuole, and of two small digestive bodies were observed. This progressive coalescence of CatL vesicles is direct evidence of involvement of CatL in intracellular digestion. Released CatL vesicles and free CatL were found in the lumen of hepatopancreatic tubule. CatL mRNA existed in F-cell, but not in the mature B-cell. This finding supports the previous suggestion that F-cell is the precursor of B-cell. F-cell is a transient form. Transition from F-cell to B-cell is fast. We define F-cell as the transcribing cell, F/B-cell as the enzyme-synthesizing cell and B-cell as the enzyme-secreting cell. For the first time, we suggest that R-cell is the replacing cell for the leaving B-cell. CatL degrades nutrient intracellularly and extracellularly. The most interesting finding is that CatL is transcribed in one type of cell, and the very cell evolves quickly to a morphologically different cell where the enzyme functions.     

Sodium-coupled sugar and amino acid transport in an acidic microenvironment

1. Nutrient transport mechanisms of lobster hepatopancreatic epithelial brush border membrane vesicles (BBMV) are strongly influenced by the acidic nature of the tubular lumen. 2. Sodium-dependent glucose uptake by BBMV was electrogenic and was stimulated at low pH by reducing sugar transport Ki, without affecting JM. 3. Glutamate was largely transported in zwitterionic form at pH 4.0 by an electrically silent cotransport mechanism with both Na and Cl. 4. Increased H+ concentration tripled the apparent membrane permeability to glutamate as well as the amino acid transport JM. 5. At pH 4.0 leucine was transported as a cation by two dissimilar carrier systems: a Na-independent process shared by polar amino acids, and an electroneutral Na-2Cl-dependent mechanism shared with non-polar amino acids. 6. A model is proposed for hepatopancreatic BBMV at acidic pH which employs ionic chemical gradients and membrane potential as nutrient transport driving forces.     

Identification of proximal tubular transport functions in the established kidney cell line, OK

OK cells, derived from an American opossum kidney, were analyzed for proximal tubular transport functions. In monolayers, L-glutamate, L-proline, L-alanine, and alpha-methyl-glucopyranoside (alpha-methyl D-glucoside) were accumulated through Na+-dependent and Na+-independent transport pathways. D-Glucose and inorganic sulfate were accumulated equally well in the presence or absence of Na+. Influx of inorganic phosphate was only observed in the presence of Na+. Na+/alpha-methyl D-glucoside uptake was preferentially inhibited by phlorizin and D-glucose uptake by cytochalasin B. An amiloride-sensitive Na+-transport was also identified. In isolated apical vesicles (enriched 8-fold in gamma-glutamyltransferase), L-glutamate, L-proline, L-alanine, alpha-methyl D-glucoside and inorganic phosphate transport were stimulated by an inwardly directed Na+-gradient as compared to an inwardly directed K+-gradient. L-Glutamate transport required additionally intravesicular K+. D-Glucose transport was similar in the presence of a Na+- and a K+-gradient. Na+/alpha-methyl D-glucoside uptake was inhibited by phlorizin whereas cytochalasin B had no effect on Na+/D-glucose transport. An amiloride-sensitive Na+/H+ exchange mechanism was also found in the apical vesicle preparation. It is concluded that the apical membrane of OK cells contains Na+-coupled transport systems for amino acids, hexoses, protons and inorganic phosphate. D-Glucose appears a poor substrate for the Na+/hexose transport system.     

Red-cell amino acid transport. Evidence for the presence of system ASC in mature human red blood cells.

The properties of Na+-dependent L-alanine transport in human erythrocytes were investigated using K+ as the Na+ substitute. Initial rates of Na+-dependent L-alanine uptake (0.2 mM extracellular amino acid) for erythrocytes from 22 donors ranged from 40 to 180 mumol/litre of cells per h at 37 degrees C. Amino acid uptake over the concentration range 0.1-8 mM was consistent with a single saturable component of Na+-dependent L-alanine transport. Apparent Km and Vmax. values at 37 and 5 degrees C measured in erythrocytes from the same donor were 0.27 and 0.085 mM respectively, and 270 and 8.5 mumol/litre of cells per h respectively. The transporter responsible for this uptake was identified as system ASC on the basis of cross-inhibition studies with a series of 42 amino acids and amino acid analogues. Apparent Ki values for glycine, L-alpha-amino-n-butyrate, L-serine and L-leucine as inhibitors of Na+-dependent L-alanine uptake at 37 degrees C were 4.2, 0.12, 0.16 and 0.70 mM respectively. Reticulocytes from a patient with inherited pyruvate kinase deficiency were found to have a 10-fold elevated activity of Na+-dependent L-alanine uptake compared with erythrocytes from normal donors. Separation of erythrocytes according to cell density (cell age) established that even the oldest mature erythrocytes retained significant Na+-dependent L-alanine transport activity. Amino acid transport was, however, a more sensitive indicator of cell age than acetylcholinesterase activity. Erythrocytes were found to accumulate L-alanine against its concentration gradient (distribution ratio approx. 1.5 after 4 h incubation), an effect that was abolished in Na+-free media. Na+-dependent L-alanine uptake was shown to be associated with L-alanine-dependent Na+ influx, the measured coupling ratio being 1:1.     

Kinetics of the intestinal brush border proline (Imino) carrier

The kinetics of L-proline transport across intestinal brush borders via the Imino carrier were studied using membrane vesicles. The Imino carrier is defined as the agent responsible for L-alanine insensitive. Na+-dependent uptake of L-proline. Initial rate measurements were made under voltage clamped conditions (pD = 0) to investigate L-proline transport as a function of cis and trans Na+ and proline concentrations. Under zero-trans conditions, increasing cis Na+ activated proline uptake with a Hill coefficient of 1.7 and decreased the apparent Kt with no change in Jimax. The Jimax was approximately 60 pmol mg-1 s-1 and the apparent Kt ranged from 0.25 mM at cis Na = 100 to 1.0 mM at cis Na+ = 30 mM. Trans Na inhibited proline uptake via a reduction in Jimax. Trans proline had no significant effect in the absence of trans Na+, but it relieved the trans Na+ inhibition. Under equilibrium exchange conditions, the Jimax was twice that observed under zero-trans conditions. These kinetics of L-proline transport suggest a model in which uptake occurs by a rapid equilibrium iso-ordered ter ter system. Two Na+ ions bind first to the carrier on the cis face of the membrane to increase the affinity of the carrier for proline. The fully loaded complex then isomerizes to release the substrates to the trans side. The partially loaded Na+-only forms are unable to translocate across the membrane. A rate-limiting step appears to be the isomerization of unloaded carrier from the trans to the cis side of the membrane.     

Na+ -dependent proline transport in isolated membrane vesicles from the L6 muscle cell line. Stimulation of uptake by intravesicular proline

Membrane vesicles of L6 myoblasts were prepared in order to study the amino acid transport system A. The role of the membrane in the adaptive response of transport to amino acid-supplementation was assessed. The membranes, prepared by N2 cavitation, displayed Na+ (but not K+)-dependent L-proline uptake. An overshoot of L-[3H]proline uptake was observed after exposure of the vesicles to an inward Na+ gradient. Isolated membrane vesicles loaded with 50 microM proline displayed countertransport (stimulation of proline uptake). It is concluded that the adaptive decrease of proline uptake observed in amino acid-supplemented cells cannot be accounted for by trans-inhibition of transport.     

Inhibition by glucocorticoids of phosphate transport in primary cultured renal cells

The regulation by glucocorticoids of phosphate transport in primary cultured chick renal cells was examined. Dexamethasone inhibited the Na+-dependent phosphate uptake system. Na+-independent phosphate uptake and Na+-dependent uptakes of alpha-methylglucoside and L-proline were unaffected. The mineralocorticoid aldosterone did not alter phosphate uptake. The inhibition of Na+-dependent phosphate uptake by dexamethasone was concentration-dependent, exhibited an induction period, was blocked by inhibitors of RNA and protein synthesis, and was rapidly reversed when the steroid was removed. Following reversal, the cells could respond a second time to the glucocorticoid. However, this time the response was rapid, could be evoked at least for 24 h after glucocorticoid withdrawal, and might be prevented by actinomycin D and cycloheximide. These findings demonstrate that glucocorticoids act on renal cells to modulate phosphate transport and suggest that the renal cell system provides an attractive model to examine the mechanism by which glucocorticoids control gene expression and regulate plasma membrane transport function.     

Stimulation by thyroid hormone of phosphate transport in primary cultured renal cells

The regulation by thyroid hormone of phosphate transport in primary cultured chick renal cells was examined. The more physiologically active L-analogs of triiodothyronine and thyroxine, but not the D-analogs of the hormones, stimulated the Na+-dependent phosphate uptake system. Na+-independent phosphate uptake and Na+-dependent uptakes of alpha-methylglucoside and L-proline were unaffected. The increase in Na+-dependent phosphate uptake was concentration dependent, exhibited an induction period, and was blocked by inhibitors of RNA and protein synthesis. The stimulation of phosphate uptake by triiodothyronine was due to an increased Vmax rather than to an altered affinity for phosphate. These findings demonstrate that thyroid hormone acts directly on renal cells to modulate phosphate transport and suggest that the renal cell system may serve as a model to examine the mechanism by which thyroid hormone controls gene expression and regulates plasma membrane transport function.     

Altered intestinal transport of amino acids in cirrhotic rats: the effect of insulin-like growth factor-I

The intestine is an important target organ for insulin-like growth factor-I (IGF-I), an anabolic hormone synthesized in the liver upon growth hormone (GH) stimulation. Levels of IGF-I are reduced in cirrhosis, and altered GH/IGF-I axis may contribute to malnutrition in cirrhotic patients. Our aim was to study Na(+)-dependent jejunal transport of amino acids (L-leucine, L-proline, L-glutamic acid, and L-cysteine) in cirrhotic rats and to analyze the effect of IGF-I on this function. IGF-I or saline was administered for 2 wk to rats with CCl(4)-induced cirrhosis and saline was administered to healthy control rats. Transport of amino acids was assessed in brush-border membrane vesicles (BBMV) using (14)C- or (35)S-labeled amino acids, and the kinetic constants V(max) and K(t) were determined. Na(+)-independent uptake of L-leucine, L-proline, L-glutamic acid, and L-cysteine by BBMV was similar in all groups. Na(+)-dependent uptake of all four amino acids was significantly diminished in cirrhotic rats compared with both controls and IGF-I-treated cirrhotic rats. The latter two groups exhibited similar V(max) and K(t), whereas untreated cirrhotic rats had reduced V(max) and increased K(t) compared with normal controls and IGF-I-treated cirrhotic animals. In conclusion, the transport of all four tested amino acids by BBMV is impaired in cirrhotic rats, and low doses of IGF-I can correct this defect.     

D-glucose transport in decapod crustacean hepatopancreas

Physiological mechanisms of gastrointestinal absorption of organic solutes among crustaceans remain severely underinvestigated, in spite of the considerable relevance of characterizing the routes of nutrient absorption for both nutritional purposes and formulation of balanced diets in aquaculture. Several lines of evidence attribute a primary absorptive role to the digestive gland (hepatopancreas) and a secondary role to the midgut (intestine). Among absorbed organic solutes, the importance of D-glucose in crustacean metabolism is paramount. Its plasma levels are finely tuned by hormones (crustacean hyperglycemic hormone, insulin-like peptides and insulin-like growth factors) and the function of certain organs (i.e. brain and muscle) largely depends on a balanced D-glucose supply. In the last few decades, D-glucose absorptive processes of the gastrointestinal tract of crustaceans have been described and transport mechanisms investigated, but not fully disclosed. We briefly review our present knowledge of D-glucose transport processes in the crustacean hepatopancreas. A discussion of previous results from experiments with hepatopancreatic epithelial brush-border membrane vesicles is presented. In addition, recent advances in our understandings of hepatopancreatic D-glucose transport are shown, as obtained (1) after isolation of purified R-, F-, B- and E-cell suspensions from the whole organ by centrifugal elutriation, and (2) by protein expression in hepatopancreatic mRNA-injected Xenopus laevis oocytes. In a perspective, the applicability of these novel methods to the study of hepatopancreatic absorptive function will certainly improve our knowledge of this structurally complex organ.     

Specificity of intestinal brush-border proline transport: cyanine dye studies

The ability of rabbit jejunal brush borders to transport inhibitors of the imino carrier was investigated in membrane vesicles by measuring their ability to depolarize the membrane potential. Membrane potentials were monitored using a voltage-sensitive cyanine dye. Piperidine and pyrrolidine carboxylic acids, which are potent inhibitors of Na+-dependent proline transport (Ki less than 0.5 mM) depolarize the potential in a Na+-dependent, saturable manner indicating transport. On the other hand, N-methylated amino acids, which are fair inhibitors (Ki 2-10 mM), do not depolarize the membrane to any significant extent, but they competitively inhibit the L-proline transport signal. This indicates that these analogs are nontransported inhibitors of the imino carrier. The poor inhibitors niacin and pipolinic acid (Ki greater than 60 mM) depolarize the membrane about twice as much as proline and with low Kf values. This suggests separate carriers for these substrates.     

Functional expression of the rabbit intestinal Na+/L-proline cotransporter (IMINO system) in Xenopus laevis oocytes

Proline absorption across small intestine takes place mainly through a Na+-dependent cotransporter localized at the brush border membrane of the enterocyte named IMINO system. It transports L-proline and 4-OH-proline but not L-alanine, neither cationic nor anionic amino acids. The present work demonstrates the functional expression of this transporter in Xenopus laevis oocytes by mRNA microinjection and radiotracer uptake techniques. Poly (A)+-RNA was isolated from rabbit jejunal mucosa and injected into oocytes. Five days after the injection, results showed 1.5 fold stimulation of 50 microM 3H-proline uptake by the injected oocytes when compared to the non injected oocytes uptake. Poly (A)+-RNA was sized fractionated and fractions were injected again. Increase on Na+-dependent L-proline uptake was obtained with a mRNA fraction between 2,4 and 4,4 kb, which was used to construct a cDNA library. The library was sequentially divided and cRNAs injected into oocytes in order to screen for an increment on the signal. A subdivision containing around 2,000 colonies was found to augment L-proline uptake 25 fold over the non injected oocytes uptake. This cRNA pool was used to further characterize the transporter. Results showed that in the absence of Na+ there was no L-proline uptake, 2 mM 4-OH-L-proline completely inhibited 50 microM proline uptake and there was no 50 microM alanine uptake. In summary, these results demonstrate the expression of the rabbit small intestine IMINO transporter in Xenopus laevis oocytes and support the next steps in the isolation of the clone.     

Both Na+ and Cl- gradients energize NaCl/L-glutamate cotransport in lobster hepatopancreatic brush border membrane vesicles.

Previous work with L-[3H]glutamate transport by lobster (Homarus americanus) hepatopancreatic brush border membrane vesicles (BBMV) indicated that the transport of this amino acid was stimulated by the presence of both Na+ and Cl- ions in the external medium, however, the specific catalytic or energetic role of each monovalent ion in amino acid transfer was not established (Ahearn and Clay (1987) J. Exp. Biol. 130, 175-191). The present study employs a variety of experimental treatments with this membrane preparation to clarify the nature of the ion dependency in the cotransport process. A zero-trans time course experiment using inwardly-directed transmembrane Na+ or Cl- gradients led to similar transient accumulations of the amino acid above equilibrium values in the presence of equilibrated concentrations of the respective counterions. The uptake overshoots observed in the presence of single ion gradients were significantly increased when gradients of both Na+ and Cl- were used simultaneously. When vesicles were pre-equilibrated with L-[3H]glutamate and either of the monovalent ions, an inwardly-directed gradient of each counterion led to the transient accumulation of additional labelled amino acid above its equilibrium concentration, indicating that either ion gradient was capable of energizing the net flow of L-glutamate. A cotransport stoichiometry of 1 Na+/1 Cl-/1 L-glutamate was established using the Static Head analysis where a balance of ion and amino acid driving forces were attained with a 7:1 Na+ or Cl- gradient (o greater than i) against a 7:1 L-glutamate gradient (i greater than o).     

Identification and conformational changes of the intestinal proline carrier

Fluorescein isothiocyanate (FITC) was used to selectively label the rabbit intestinal brush-border imino carrier, identify the binding protein on SDS-polyacrylamide gel electrophoresis, and monitor the effect of ions on fluorescein quenching. FITC inhibits Na+-dependent L-proline transport irreversibly, but transport is protected by physiological concentrations of Na+ and L-proline. About 1 nmol of FITC/mg of protein binds specifically to the transporter, which was identified by SDS-polyacrylamide gel electrophoresis as a 100 +/- 5-kDa peptide. Na+ produced a specific, saturable quench in the fluorescence of FITC bound to the proline carrier. Both transport and FITC quenching are inhibited by n-acetylimidazole, and membranes are protected from acetylation by Na+. We conclude that Na+ binds to the proline carrier (100-kDa peptide) to produce a change in conformation that results in an increase in the affinity of the carrier for proline.     

How many Na+-dependent carriers for L-alanine and L-proline in the eel intestine? Studies with brush-border membrane vesicles

Using brush-border membrane (BBM) vesicles prepared from the intestine of the European eel, the specificity of L-alanine and L-proline Na+-dependent transport was investigated by measuring the uptake of isotopically labelled substrates. In the presence of Na+ ions, cross-inhibition between alanine and proline transports was observed; in addition alpha-(methylamino)isobutyric acid (MeAIB) inhibited proline but had no effect on alanine uptake. These results can be explained by the presence, in eel intestinal BBM vesicles, of at least two distinct agencies for Na+-dependent proline and alanine translocation. The first system is specific for alanine and short-chain neutral amino acids; the second system, specific for imino acids and the N-methylated analogues, is regulated by alanine concentration.     

A comparison of the effects of hyperthermia on cell growth in human T and B lymphoid cells: relationship to alterations in plasma membrane transport properties

Hyperthermic exposure (39-43 degrees C) for 1 or 2 hr impairs growth and Na+-dependent amino acid transport in both a radiosensitive human T (Molt-4) and a radioresistant B (RPMI 1788) lymphoid cell line. The heat damage to Na+-dependent amino acid transport in both cell lines is reversible under the conditions tested. Cell growth, as judged by increases in cell number, is decreased in both cell lines after hyperthermic treatment (43 degrees C, 1-hr exposure). This decrease in growth correlated with the damage to, and recovery of, the Na+-dependent amino acid transport system. However, the sensitivity to heat of both growth and Na+-dependent amino acid transport appears to differ in Molt-4 which is somewhat more sensitive to hyperthermia (T-cell line) vs RPMI-1788 (B-cell line). In the case of Molt-4, the rate of growth is decreased for about 60-80 hr after cells are exposed for 1 hr at 43 degrees C; whereas increases in cell number in the RPMI 1788 is observed within 40 hr after the heat treatment. The differences observed in cell growth and transport in these two lymphoid cell lines are attributed to the manner in which heat affects (i) the transport parameters in Molt-4 vs RPMI 1788 (i.e., the Michaelis-Menten constants Km and Vmax) and (ii) the putative plasma membrane sulfhydryl protein(s) which modulates Na+-dependent amino acid transport.