Galactose and glucose metabolism in galactokinase deficient, galactose-1-P-uridyl transferase deficient and normal human fibroblasts.

Despite the genetic interruption of the Leloir pathway both galactosemic patients and galactosemic fibroblasts can convert galactose to CO2 and TCA precipitable products, although at less than the normal rate. These observations stimulated investigations into the identity of the alternative metabolic routes which allows for galactose metabolism in the absence of in vitro galactose-1-P-uridyl transferase. Four lines of galactosemic cells, each without detectable gal-transferase, produced 14CO2 from [1-14C]-galactose (0.094 mumoles in 20 cc of medium) at approximately 39% +/- 16% the rate of transferase positive cells over a 48-hour period. However, galactokinase deficient fibroblasts produced 14CO2 and TCA precipitable products from [1-14C]-galactose or [U-14C]-galactose at only 3% to 9% the rate of normal fibroblasts. Therefore it seems likely that gal-transferase deficient fibroblasts must first synthesize galactose-1-P for further metabolism of galactose.     

Early explorations of the pathways of uridine diphosphate galactose in man and in microorganisms

Thirty years ago, a number of human inborn errors in carbohydrate metabolism were explored with specific enzymatic tests on blood samples (hemolysates). Hereditary galactosemia was the first example. When the inoperative step in galactose metabolism was specified, the basis for the diet therapy used on the galactosemic infants, namely galactose-free diet, could be shown to be securely founded. As far as galactose metabolism is concerned, the cells of the infant are faced with two problems: (i) the conversion of dietary lactose (galactosyl glucose) to glucose and its catabolites involved in energy metabolism, and (ii) the conversion of dietary glucose or lactose to galactosyl units of glycolipids and glycoprotein cell structures. Subsequent studies on microorganisms revealed several types of hereditary defect in galactose metabolism. One type which permits the bacteria to develop a normal carbohydrate pattern in their cell walls includes an enzyme defect, like that described in the cells of the galactosemic infant. Two other types, with the inability to synthesize UDPGlc or UDPGal from glucose, do not permit the bacteria to build the fabric of the normal bacterial cell wall. This is the subject for discussion.     

Synthesis and degradation of tyrosinase in cultured melanoma cells

The tyrosinase (EC 1.14.18.1) activity of cultured B-16 mouse melanoma cells (C2M) in the stationary phase depends greatly on whether the culture medium contains glucose or galactose. The activity in medium containing galactose was about ten times that in medium containing glucose at pH 7.2. This difference in tyrosinase activity was concluded to be due to a shift of balance between synthesis and degradation of the enzyme. Experiments were conducted with stationary phase cultures in the presence of cycloheximide. The melanoma cells did not synthesize tyrosinase in medium containing glucose in the stationary phase. But when they were cultured under identical conditions, except that glucose was replaced by galactose, they continued to synthesize tyrosinase. The rate of synthesis in medium containing galactose at pH 6.3 was one third of that in the same medium at about pH 7, in which the increase in specific activity of tyrosinase per day was about 30 nmoles/mg cell protein per hr. The rate of degradation of the enzyme was practically the same in medium containing glucose as in medium containing galactose, and largely depended on the pH of the culture medium. At pH 6.3, the half-life was about one third of that at pH 7.2, where it was about 1.8 days. The degradation at acidic pH values was much reduced by ammonium salt and was strongly inhibited by the protease inhibitor, leupeptin.     

Effects of pH and type of sugar in the medium on tyrosinase activity in cultured melanoma cells.

The tyrosinase (EC 1.14.18.1) activity of cultured mouse melanoma cells B16 in the stationary phase of growth, depends greatly on the pH of the medium and the kind of sugar present. The enzyme activity of a homogenate of cells grown at pH 7.2 in Eagles's MEM supplemented with 10% new born calf serum and con taining galactose in place of glucose, was about ten times that of a homogenate of cells cultured at pH 6.3 in the same medium. The tyrosinase activity changed reversibly on changing the pH of the culture medium. When cultured at a constant pH of 7.2, cells grown with 1 mM galactose had about five times higher tyrosinase activity than cells grown with 1 mM glucose. Only a small amount of lactate accumulated in cultures with glucose and it had little effect on the enzyme activity. These two findings explain the very low tyrosinase activity of cells cultured in medium with 5 mM glucose: the low activity is due to the presence of glucose and to the low pH resulting from conversion of glucose to lactic acid.     

Characterization of a novel biochemical abnormality in galactosemia: deficiency of glycolipids containing galactose or N-acetylgalactosamine and accumulation of precursors in brain and lymphocytes

Classic galactosemia, an inborn error of human galactose metabolism, is characterized by a deficiency of the enzyme galactose-1-phosphate uridyltransferase (GALT). The current model for the pathophysiology of this disease ascribes most of its symptoms to the toxicity of intracellular galactose-1-phosphate (Gal-1-P), one of the substrates of GALT which accumulates in the untreated disease state. Recently, a reduction in the intracellular concentration of UDP-Gal (uridine diphosphogalactose), one of the products of GALT, has been described in treated galactosemic patients. We investigated whether galactosemic patients might also have reduced amounts of those macromolecules that depend on UDP-Gal for their biosynthesis. We report a reduction in glycolipids that contain either galactose or its derivative N-acetylgalactosamine and an accumulation of the precursors to these compounds in the brain of a neonate with galactosemia. We also found an imbalance in glycolipids in galactosemic lymphoblasts. This novel biochemical abnormality observed in galactosemic patients is not addressed by dietary galactose-restriction therapy and could explain some of the chronic neurologic and other complications of galactosemia.     

Metabolic cooperation in cocultures of fibroblasts from patients with various abnormalities of galactose metabolism

14C galactose incorporation into the TCA-precipitable material of cultures of fibroblasts deficient in galactokinase (GALK-) was nil. In cultures of fibroblasts deficient in uridyltransferase (GALT-), it was 30 to 75% of control incorporation. In cocultures of GALK and GALT-deficient fibroblasts, 14C incorporation was restored to near-normal levels. This restoration produced in the presence of close cellular contacts was not increased by polyethyleneglycol somatic hybridization. Our results indicate that metabolic cooperation occurred involving the transfer of galactose 1-phosphate from the GALT-deficient to the GALK-deficient cells via intercellular connections.     

Comparative studies of glucose-fed and glucose-starved hamster cell cultures: responses in galactose metabolism.

The metabolic flow of trace amounts of D-[14C]-galactose was followed in cultures of transformed and untransformed hamster cells over a period ranging from five minutes to two hours. The results of chromatographic and enzymatic analyses of the soluble pools are described. Non-glycolytic cells(previously deprived of sugar periods of up to 24 hours) convert D-galactose to galactose-1-phosphate and uridine diphosphoglucuronic acid in 10 to 20 minutes. In the same short assay time, glycolytic cells which have been maintained for 24 hours in media containing glucose or galactose convert D-galactose to uridine diphsphogalactose and uridine diphosphoglucose (ratio 1.4:1). Long term diprivation of sugar also results in 3- to 4-fold increases in the uptake of galactose. In addition, the incorporation of galactose label into chloroformethanol soluble material appears to be influenced by the culture conditions of the untransformed cells while incorporation in the transformed cells appears unaffected. When cycloheximide is included in the maintenance medium for extended periods, the non-glycolytic cells also show increases in galactose uptake rates but the glucose-fed, glycolytic cells llose uptake ability. UDPhexose is the main galactose metabolic peak in the soluble pools of the cycloheximide-treated, glycolytic and the cycloheximide-treated, non-glycolytic cells. The results of these experiments suggests that uptake of galactose and its subsequent metabolism are under separate control.     

Comparative metabolic analysis of lactate for CHO cells in glucose and galactose

t-PA producing CHO cells have been shown to undergo a metabolic shift when the culture medium is supplemented with a mixture of glucose and galactose. This metabolic change is characterized by the reincorporation of lactate and its use as an additional carbon source. The aim of this work is to understand lactate metabolism. To do so, Chinese hamster ovary cells were grown in batch cultures in four different conditions consisting in different combinations of glucose and galactose. In experiments supplemented with glucose, only lactate production was observed. Cultures with glucose and galactose consumed glucose first and produced lactate at the same time, after glucose depletion galactose consumption began and lactate uptake was observed. Comparison of the metabolic state of cells with and without the shift by metabolic flux analysis show that the metabolic fluxes distribution changes mostly in the reactions involving pyruvate metabolism. When not enough pyruvate is being produced for cells to support their energy requirements, lactate dehydrogenase complex changes the direction of the reaction yielding pyruvate to feed the TCA cycle. The slow change from high fluxes during glucose consumption to low fluxes in galactose consumption generates intracellular conditions that allow the influx of lactate. Lactate consumption is possible in cell cultures supplemented with glucose and galactose due to the low rates at which galactose is consumed. Evidence suggests that an excessive production and accumulation of pyruvate during glucose consumption leads to lactate production and accumulation inside the cell. Other internal conditions such as a decrease in internal pH, forces the flow of lactate outside the cell. After metabolic shift the intracellular pool of pyruvate, lactate and H⁺ drops permitting the reversal of the monocarboxylate transporter direction, therefore leading to lactate uptake. Metabolic analysis comparing glucose and galactose consumption indicates that after metabolic shift not enough pyruvate is produced to supply energy metabolism and lactate is used for pyruvate synthesis. In addition, MFA indicates that most carbon consumed during low carbon flux is directed towards maintaining energy metabolism.     

Turnover of sulfated glycosaminoglycans in fibroblasts derived from patients with Werner''s syndrome

Fibroblasts derived from patients with Werner's syndrome (WS) were incubated with radioactive sulfate to study the incorporation of 35S into glycosaminoglycans (GAGs). The accumulation of cell-associated 35S radioactivity in the GAGs of WS fibroblasts was consistently higher than parallel accumulation in normal human fibroblasts, but was substantially less than in fibroblasts derived from patients with Hurler's syndrome (HS). However, when fibroblasts were labeled with 35SO4(2-), trypsinized to remove extracellular and pericellular radioactive GAGs, replated, and chased to follow the fate of the intracellular radioactivity, both WS and normal cells showed a rapid release of the intracellular 35S, while HS cells showed little or no loss of intracellular radioactivity. The radioactivity released from WS and normal cells was of low molecular weight (LMW), eluting from gel filtration columns at the same position as free sulfate. These results establish that WS cells degrade intracellular sulfated GAGs and argue against the hypothesis that a defect in GAG degradation pathways is the basis for the increased level of cell-associated GAGs. Other possible explanations for the increased cell-associated [35S]GAGs in WS cells as compared with normal cells were also considered: increased GAG sulfation; an increase in GAG chain length; an increased rate of GAG synthesis; and a decreased rate of shedding of cell surface proteoglycan into the medium. No difference between normal and WS fibroblasts in any of the above parameters was observed. These results strongly imply that the primary biochemical defect in WS fibroblasts does not involve sulfated GAG metabolism.     

Nonenzymatic galactosylation of human LDL decreases its metabolism by human skin fibroblasts

Incubation of human LDL with galactose in vitro resulted in a glycosylated-LDL containing radiolabel covalently attached to apo B. The rate of radiolabel incorporation was proportional to the time of incubation and concentration of carbohydrate. The rate of incorporation of galactose into apo B was higher than with glucose or mannose. The nonenzymatic glycosylation of LDL decreased its uptake and metabolism by the high affinity, receptor dependent process for LDL in normal human skin fibroblasts.     

Regulation of synthesis of lactosylceramide and long chain bases in normal and familial hypercholesterolemic cultured proximal tubular cells

We have investigated the effects of lipoproteins on sphingolipid metabolism in proximal renal tubular cells from normal subjects and low density lipoprotein (LDL) receptor-negative homozygous familial hypercholesterolemic subjects employing radioactive precursors, e.g. [3H]serine, [3H]glucose, and [14C]galactose. Compared to cells incubated with lipoprotein-deficient serum, maximum suppression (70-80%) of incorporation of [3H]glucose and [3H]serine into ceramide and LacCer occurred when the LDL concentration in the medium was 25 micrograms/ml medium, and addition of higher amounts of LDL (up to 500 micrograms/ml medium) to normal cells did not produce further suppression. In contrast, high density lipoproteins did not suppress the incorporation of [3H]glucose into lactosylceramide (LacCer) in normal cells. The incorporation of [14C] galactose into LacCer was also suppressed by LDL (50% suppression at a concentration of 100 micrograms/ml medium). In contrast, LDL modified by reductive methylation of lysine residues did not suppress the incorporation of [3H]glucose into LacCer and the incorporation of [3H]serine into ceramide, whereas, native LDL exerted a concentration-dependent suppression of [3H]serine incorporation into ceramide and sphingomyelin in normal cells. At high concentrations of LDL (50-500 micrograms/ml medium), the incorporation of [3H]glucose and [14C]galactose into LacCer in homozygous FH cells was stimulated approximately 2-fold. Maximum stimulation of [3H]serine incorporation into ceramides, LacCer, and sphingomyelin occurred at 100 micrograms LDL/ml medium. Our studies indicate that the endogenous synthesis of sphingolipids in normal renal cells is regulated by the LDL receptor. Modification of the lysine residues in LDL by reductive methylation results in the inability to suppress sphingolipid synthesis in normal cells. Lack of LDL receptors, as in the case of homozygous FH cells, results in the lack of suppression of endogenous sphingolipid synthesis.     

Growth responses of cell cultures in a galactose medium

Under specific conditions utilized, Eagle's minimum essential medium containing “substantially glucose-free” galactose instead of glucose supported the growth of every cell culture tested with the exception of embryonic cells. Growth of various primary kidney cultures in galactose-EMEM was greater or, at least, equal to that obtained with the same medium containing glucose. Cell lines of non-human origin showed extensive growth in galactose-EMEM and were further stimulated by supplemental pyruvate. Only limited, if any, growth of human cell lines occurred in galactose-EMEM under routine conditions of culture. The growth response of these cells was greatly increased and approached that with glucose if the initial pH of the galactose medium was adjusted in the acid pH range or, with WISH cells, if the galactose medium was supplemented with pyruvate.     

The autocrine regulation of the proliferation of cell line A-549 under conditions facilitating the acidification of the culture medium]

The influence of serum-free media, previously conditioned by A-549 line cells of the human lung adenocarcinoma (c-medium), on the intensity of 3H-thymidine incorporation into DNA of the same cells was studied. It was found that, depending on the duration of conditioning (2, 4 and 6 days), the c-media were obtained with corresponding values of pH--7.2, 6.9 and 6.3, in the latter case the contact inhibition of cell growth being seen. On culturing the A-549 line cells in the c-medium at pH 7.2 and 6.9, the intensity of DNA biosynthesis was shown to be 2.4 and 1.8 times higher, respectively, compared to that under condition of the fresh serum-free medium. The cell culturing in the c-medium at pH 6.3 (here and in the case of pH 6.9 c-medium the media pH were made up to 7.2 before utilization) leads to the inhibition of DNA biosynthesis intensity in the cells. It was also detected that a temporary acidification of the pH 7.2 c-medium to pH 4.0 or 2.0, using, respectively CO2 bubbling or HCl titration, caused the growth inhibiting manifestation in this medium. The results obtained testify that the carcinoma cells of A-549 line are able to secrete into the cultured medium both stimulators and inhibitors of DNA biosynthesis, with a transforming growth factor beta being of primary importance among the latter.     

Abnormal balance between proliferation and apoptotic cell death in fibroblasts derived from keloid lesions

A new culture model was developed to study the role of proliferation and apoptosis in the etiology of keloids. Fibroblasts were isolated from the superficial, central, and basal regions of six different keloid lesions by using Dulbecco's Modified Eagle Medium containing 10% fetal calf serum as a culture medium. The growth behavior of each fibroblast fraction was examined in short-term and long-term cultures, and the percentage of apoptotic cells was assessed by in situ end labeling of fragmented DNA. The fibroblasts obtained from the superficial and basal regions of keloid tissue showed population doubling times and saturation densities that were similar to those of age-matched normal fibroblasts. In contrast, the fibroblasts from the center of the keloid lesions showed significantly reduced doubling times (25.9 +/- 6.3 hours versus 43.5 +/- 6.3 hours for normal fibroblasts) and reached higher cell densities. In long-term culture, central keloid fibroblasts formed a stratified three-dimensional structure, contracted the self-produced extracellular matrix, and gave rise to nodular cell aggregates, mimicking the formation of keloid tissue. Apoptotic cells were detected in both normal and keloid-derived fibroblasts, but their numbers were twofold higher in normal cells compared with all keloid fibroblasts. To examine whether apoptosis mediates the therapeutic effect of ionizing radiation on keloids, the cells were exposed to gamma rays at a dose of 8 Gy. Under these conditions, a twofold increase in the population of apoptotic cells was detected. These results indicate that the balance between proliferation and apoptosis is impaired in keloid fibroblasts, which could be responsible for the formation of keloid tumors. The results also suggest that keloids contain at least two different fibroblast fractions that vary in growth behavior and extracellular matrix metabolism.     

Proton movements coupled to sugar transport via the galactose transport system in Salmonella typhimurium.

We have studied proton movements associated with substrate transport via the galactose transport system in Salmonella typhimurium. The addition of galactose to lightly buffered suspensions of anaerobic, non-metabolizing cells of Salmonella typhimurium, specifically induced for the galactose transport system, causes an increase in extracellularpH as galactose and protons enter the cell together. Other substrates for this transport system, D-fucose, 2-deoxygalactose, glucose and 2-deoxyglucose similarly cause an influx of protons when transported. In contrast, transport via the other major transport system for galactose, the methylgalactoside transport system, is not coupled to H+ influx. Comparison of kinetic data obtained from pH measurements with data obtained from measurement of active transport of galactose via the galactose transport system suggests that the apparent Km of the galactose transport system for this sugar differs under energized and non-energized conditions. At pH 7.2 the permeant anion SCN- increases both the rate and extent of galactose-induced proton influx; at pH 6 the rate, but not the extent is increased by SCN-.     

Formation and properties of retinylphosphate galactose.

Crude cell membrane fractions from a number of tissues can form acidic glycolipids. The formation of acidic galactose lipid and mannose lipid was greatly reduced in vitamin A deficiency, primarily in tissues known to be mucus-producing. Mouse mastocytoma tissue was active in forming acidic galactose lipids with UDP-galactose as substrate. One of the products was identified as retinylphosphate galactose. The synthetase reaction producing this compound exhibited an apparent pH optimum at 6.3. The presence of detergent and retinol stimulated the synthetase reaction, which exhibited an absolute requirement for Mn2+ or Mg2+. The synthetase reaction was readily reversible. Incubation of particulate enzyme with retinylphosphate galactose and UDP yielded UDP-galactose and a compound tentatively identified as retinylphosphate. The galactose lipid was isolated by column chromatography on DEAE-cellulose and silica gel. The retinylphosphate galactose was homogeneous when examined by thin layer chromatography. Mild acid hydrolysis of labeled retinylphosphate galactose yields [14C]galactose, whereas alkaline hydrolysis and hydrogenolysis produced [14C]galactose 1-phosphate. Retinylphosphate galactose bound to vitamin A-depleted, retinol-binding protein.     

A process related to membrane potential involved in bacterial chemotaxis to galactose

Attractants, in the presence of respiration and ATPase inhibitors, stimulate a hyperpolarization in Escherichia coli [Eisenbach, M. (1982) Biochemistry 21, 6818-6825]. In order to examine whether this hyperpolarization is correlated with chemotaxis, the effect of the attractant D-galactose and its analogues on the membrane potential of wild-type E. coli strains and some of their mutants was studied. The main observations were the following: (i) Wild-type cells became hyperpolarized by either galactose or its nonmetabolizable analogues, D-fucose and L-sorbose. (ii) A mutant defective in galactose metabolism became hyperpolarized by galactose. (iii) Inhibiting the galactose permease system did not prevent the hyperpolarization, rather it facilitated the observation of the hyperpolarization. (iv) Mutants unable to transport galactose via the methyl beta-galactoside (Mgl) transport system but having normal chemotaxis to galactose became normally hyperpolarized by D-fucose. (v) Mutants which cannot bind galactose were not hyperpolarized by galactose. (vi) The hyperpolarization in flaI mutants, in which the whole chemotaxis machinery is repressed, was reduced to 12-15% of the hyperpolarization in the parent strains. (vii) Nonattractant sugars did not stimulate hyperpolarization. It is concluded that the hyperpolarization is the consequence of neither galactose metabolism nor transport but rather is correlated with galactose taxis.     

Inhibitor of apoptosis proteins and ovarian dysfunction in galactosemic rats

Galactosemia is a genetic disease with deficiency of galactose-1-uridyltransferase, resulting in the accumulation of galactose or galactose-1-phosphate in the blood and tissues. Rats were fed with normal rat chow and with a high-galactose diet for 4 weeks to give control and galactosemic groups, and their ovarian function was studied. The two groups of rats were injected with pregnant mare's serum gonadotrophin (PMSG) and were killed at different time points after human chorionic gonadotrophin (hCG) injection. The number of oocytes ovulated in the controls was significantly higher than in the galactosemic group. Morphometric studies of the ovaries also showed a higher number of corpora lutea in the controls. Western blot analysis of granulosa cells showed that the overall expressions of Fas and FasL were lower in the control group and their expressions of inhibitor of apoptosis proteins (IAPs) were higher than in the galactosemic group, especially at 8 h post hCG injection. TDT-mediated dUTP-biotin nick end-labeling (TUNEL) and immunohistochemical staining of ovarian sections with Ki-67 and IAPs showed more apoptotic granulosa cells in the galactosemic group and the expressions of IAPs in granulosa cells also confirmed the result of the Western blot. These findings support our hypothesis that ovarian dysfunction in galactosemic rats is due to increased apoptosis in granulosa cells of maturing follicles.     

Regulation of galactose oxidase synthesis and secretion in Dactylium dendroides: effects of pH and culture density.

The effects of pH and growth density on the amount of an extracellular enzyme, galactose oxidase, synthesized by the fungus Dactylium dendroides were studied. Growth at a pH below 6.7 caused a decrease in the ability of the organism to release galactose oxidase. The enzyme retained by these fungal cells was liberated whenever the pH was raised to 7.0. Cycloheximide addition failed to inhibit the appearance of this protein; [3H]leucine added prior to pH adjustment was not incorporated into the released protein, These observations indicate the released protein is not newly synthesized protein. The retained enzyme would be secreted slowly over a 2-day period if the pH was not increased. In addition to regulating protein retention, pH was also shown to be associated with vacuolization, cell volume, culture density, and inhibition of protein synthesis. Cultures maintained at low pH were characterized by a dense growth consisting of highly vacuolated, buoyant, fungal hyphae. Increasing the pH from 6 to 7 caused a decrease in vacuole size. Cells grown at neutral pH maintained a lower density of growth and, based on activity measurements, synthesized 33% more galactose oxidase. Furthermore, cultures grown at pH 6.0 and maintained at a lower cell density produced galactose oxidase at a level similar to that of cells grown at neutral pH. Thus, the elevated density of the cell culture was inhibitory to galactose oxidase synthesis. The observed effects on protein synthesis and release were rather specific for galactose oxidase, since other extracellular proteins appeared in the earliest stages of growth.