Effect of Fructose, Dihydroxyacetone, Glycerol, and Glucose on Metabolites and Related Compounds in Liver and Kidney

A tipping point in dihydroxyacetone exposure: mitochondrial stress and metabolic reprogramming alter survival in rat cardiomyocytes H9c2 cells

Exogenous exposures to the triose sugar dihydroxyacetone (DHA) occur from sunless tanning products and electronic cigarette aerosol. Once inhaled or absorbed, DHA enters cells, is converted to dihydroxyacetone phosphate (DHAP), and incorporated into several metabolic pathways. Cytotoxic effects of DHA vary across the cell types depending on the metabolic needs of the cells, and differences in the generation of reactive oxygen species (ROS), cell cycle arrest, and mitochondrial dysfunction have been reported. We have shown that cytotoxic doses of DHA induced metabolic imbalances in glycolysis and oxidative phosphorylation in liver and kidney cell models. Here, we examine the dose-dependent effects of DHA on the rat cardiomyocyte cell line, H9c2. Cells begin to experience cytotoxic effects at low millimolar doses, but an increase in cell survival was observed at 2 mM DHA. We confirmed that 2 mM DHA increased cell survival compared to the low cytotoxic 1 mM dose and investigated the metabolic differences between these two low DHA doses. Exposure to 1 mM DHA showed changes in the cell's fuel utilization, mitochondrial reactive oxygen species (ROS), and transient changes in the glycolysis and mitochondrial energetics, which normalized 24 h after exposure. The 2 mM dose induced robust changes in mitochondrial flux through acetyl CoA and elevated expression of fatty acid synthase. Distinct from the 1 mM dose, the 2 mM exposure increased mitochondrial ROS and NAD(P)H levels, and sustained changes in LDHA/LDHB and acetyl CoA-associated enzymes were observed. Although the cells were exposed to low cytotoxic (1 mM) and non-cytotoxic (2 mM) acute doses of DHA, significant changes in mitochondrial metabolic pathways occurred. Further, the proliferation increase at the acute 2 mM DHA dose suggests a metabolic adaption occurred with sustained consequences in survival and proliferation. With increased exogenous exposure to DHA through e-cigarette aerosol, this work suggests cell metabolic changes induced by acute or potentially chronic exposures could impact cell function and survival.

Dihydroxyacetone suppresses mTOR nutrient signaling and induces mitochondrial stress in liver cells

Dihydroxyacetone (DHA) is the active ingredient in sunless tanning products and a combustion product from e-juices in electronic cigarettes (e-cigarettes). DHA is rapidly absorbed in cells and tissues and incorporated into several metabolic pathways through its conversion to dihydroxyacetone phosphate (DHAP). Previous studies have shown DHA induces cell cycle arrest, reactive oxygen species, and mitochondrial dysfunction, though the extent of these effects is highly cell-type specific. Here, we investigate DHA exposure effects in the metabolically active, HepG3 (C3A) cell line. Metabolic and mitochondrial changes were evaluated by characterizing the effects of DHA in metabolic pathways and nutrient-sensing mechanisms through mTOR-specific signaling. We also examined cytotoxicity and investigated the cell death mechanism induced by DHA exposure in HepG3 cells. Millimolar doses of DHA were cytotoxic and suppressed glycolysis and oxidative phosphorylation pathways. Nutrient sensing through mTOR was altered at both short and long time points. Increased mitochondrial reactive oxygen species (ROS) and mitochondrial-specific injury induced cell cycle arrest and cell death through a non-classical apoptotic mechanism. Despite its carbohydrate nature, millimolar doses of DHA are toxic to liver cells and may pose a significant health risk when higher concentrations are absorbed through e-cigarettes or spray tanning.

Renal Tubular Handling of Glucose and Fructose in Health and Disease

The proximal tubule of the kidney is programmed to reabsorb all filtered glucose and fructose. Glucose is taken up by apical sodium-glucose cotransporters SGLT2 and SGLT1 whereas SGLT5 and potentially SGLT4 and GLUT5 have been implicated in apical fructose uptake. The glucose taken up by the proximal tubule is typically not metabolized but leaves via the basolateral facilitative glucose transporter GLUT2 and is returned to the systemic circulation or used as an energy source by distal tubular segments after basolateral uptake via GLUT1. The proximal tubule generates new glucose in metabolic acidosis and the postabsorptive phase, and fructose serves as an important substrate. In fact, under physiological conditions and intake, fructose taken up by proximal tubules is primarily utilized for gluconeogenesis. In the diabetic kidney, glucose is retained and gluconeogenesis enhanced, the latter in part driven by fructose. This is maladaptive as it sustains hyperglycemia. Moreover, renal glucose retention is coupled to sodium retention through SGLT2 and SGLT1, which induces secondary deleterious effects. SGLT2 inhibitors are new anti-hyperglycemic drugs that can protect the kidneys and heart from failing independent of kidney function and diabetes. Dietary excess of fructose also induces tubular injury. This can be magnified by kidney formation of fructose under pathological conditions. Fructose metabolism is linked to urate formation, which partially accounts for fructose-induced tubular injury, inflammation, and hemodynamic alterations. Fructose metabolism favors glycolysis over mitochondrial respiration as urate suppresses aconitase in the tricarboxylic acid cycle, and has been linked to potentially detrimental aerobic glycolysis (Warburg effect). © 2022 American Physiological Society. Compr Physiol 12:2995-3044, 2022.

Principles of Ice-Free Cryopreservation by Vitrification

Vitrification is an alternative to cryopreservation by freezing that enables hydrated living cells to be cooled to cryogenic temperatures in the absence of ice. Vitrification simplifies and frequently improves cryopreservation because it eliminates mechanical injury from ice, eliminates the need to find optimal cooling and warming rates, eliminates the importance of differing optimal cooling and warming rates for cells in mixed cell type populations, eliminates the need to find a frequently imperfect compromise between solution effects injury and intracellular ice formation, and can enable chilling injury to be "outrun" by using rapid cooling without a risk of intracellular ice formation. On the other hand, vitrification requires much higher concentrations of cryoprotectants than cryopreservation by freezing, which introduces greater risks of both osmotic damage and cryoprotectant toxicity. Fortunately, a large number of remedies for the latter problem have been discovered over the past 35 years, and osmotic damage can in most cases be eliminated or adequately controlled by paying careful attention to cryoprotectant introduction and washout techniques. Vitrification therefore has the potential to enable the superior and convenient cryopreservation of a wide range of biological systems (including molecules, cells, tissues, organs, and even some whole organisms), and it is also increasingly recognized as a successful strategy for surviving harsh environmental conditions in nature. But the potential of vitrification is sometimes limited by an insufficient understanding of the complex physical and biological principles involved, and therefore a better understanding may not only help to improve present outcomes but may also point the way to new strategies that may be yet more successful in the future. This chapter accordingly describes the basic principles of vitrification and indicates the broad potential biological relevance of this alternative method of cryopreservation.

Exogenous exposure to dihydroxyacetone mimics high fructose induced oxidative stress and mitochondrial dysfunction

Dihydroxyacetone (DHA) is a three-carbon sugar that is the active ingredient in sunless tanning products and a by-product of electronic cigarette (e-cigarette) combustion. Increased use of sunless tanning products and e-cigarettes has elevated exposures to DHA through inhalation and absorption. Studies have confirmed that DHA is rapidly absorbed into cells and can enter into metabolic pathways following phosphorylation to dihydroxyacetone phosphate (DHAP), a product of fructose metabolism. Recent reports have suggested metabolic imbalance and cellular stress results from DHA exposures. However, the impact of elevated exposure to DHA on human health is currently under-investigated. We propose that exogenous exposures to DHA increase DHAP levels in cells and mimic fructose exposures to produce oxidative stress, mitochondrial dysfunction, and gene and protein expression changes. Here, we review cell line and animal model exposures to fructose to highlight similarities in the effects produced by exogenous exposures to DHA. Given the long-term health consequences of fructose exposure, this review emphasizes the pressing need to further examine DHA exposures from sunless tanning products and e-cigarettes.

Probing hepatic metabolism of [2-13C]dihydroxyacetone in vivo with 1H-decoupled hyperpolarized 13C-MR

OBJECTIVES

To enhance detection of the products of hyperpolarized [2-13C]dihydroxyacetone metabolism for assessment of three metabolic pathways in the liver in vivo. Hyperpolarized [2-13C]DHAc emerged as a promising substrate to follow gluconeogenesis, glycolysis and the glycerol pathways. However, the use of [2-13C]DHAc in vivo has not taken off because (i) the chemical shift range of [2-13C]DHAc and its metabolic products span over 144 ppm, and (ii) 1H decoupling is required to increase spectral resolution and sensitivity. While these issues are trivial for high-field vertical-bore NMR spectrometers, horizontal-bore small-animal MR scanners are seldom equipped for such experiments.

METHODS

Real-time hepatic metabolism of three fed mice was probed by 1H-decoupled 13C-MR following injection of hyperpolarized [2-13C]DHAc. The spectra of [2-13C]DHAc and its metabolic products were acquired in a 7 T small-animal MR scanner using three purpose-designed spectral-spatial radiofrequency pulses that excited a spatial bandwidth of 8 mm with varying spectral bandwidths and central frequencies (chemical shifts).

RESULTS

The metabolic products detected in vivo include glycerol 3-phosphate, glycerol, phosphoenolpyruvate, lactate, alanine, glyceraldehyde 3-phosphate and glucose 6-phosphate. The metabolite-to-substrate ratios were comparable to those reported previously in perfused liver.

DISCUSSION

Three metabolic pathways can be probed simultaneously in the mouse liver in vivo, in real time,  using hyperpolarized DHAc.

Soft drink consumption during and following exercise in the heat elevates biomarkers of acute kidney injury

The purpose of this study was to test the hypothesis that consuming a soft drink (i.e., a high-fructose, caffeinated beverage) during and following exercise in the heat elevates biomarkers of acute kidney injury (AKI) in humans. Twelve healthy adults drank 2 liters of an assigned beverage during 4 h of exercise in the heat [35.1 (0.1)°C, 61 (5)% relative humidity] in counterbalanced soft drink and water trials, and ≥1 liter of the same beverage after leaving the laboratory. Stage 1 AKI (i.e., increased serum creatinine ≥0.30 mg/dl) was detected at postexercise in 75% of participants in the Soft Drink trial compared with 8% in Water trial ( P = 0.02). Furthermore, urinary neutrophil gelatinase-associated lipocalin (NGAL), a biomarker of AKI, was higher during an overnight collection period after the Soft Drink trial compared with Water in both absolute concentration [6 (4) ng/dl vs. 5 (4) ng/dl, P < 0.04] and after correcting for urine flow rate [6 (7) (ng/dl)/(ml/min) vs. 4 (4) (ng/dl)/(ml/min), P = 0.03]. Changes in serum uric acid from preexercise were greater in the Soft Drink trial than the Water trial at postexercise ( P < 0.01) and 24 h ( P = 0.05). There were greater increases from preexercise in serum copeptin, a stable marker of vasopressin, at postexercise in the Soft Drink trial ( P < 0.02) than the Water trial. These findings indicate that consuming a soft drink during and following exercise in the heat induces AKI, likely via vasopressin-mediated mechanisms.

Baccharis dracunculifolia (Asteraceae) essential oil toxicity to Culex quinquefasciatus (Culicidae)

The control of mosquitoes by means of chemical insecticides has been a problem, mainly due to the possibility of resistance developed by insects to xenobiotics. For this reason, demand for botanical insecticides has increased. In this sense, the present work aims to verify the susceptibility and morphological and biochemical alterations of Culex quinquefasciatus larvae after exposure to essential oil (EO) of leaves of Baccharis dracunculifolia. To observe the larvicidal action, larvae were exposed to EO at concentrations of 25, 50, 100, and 200 mg/L, until their emergence to adults. The control group was exposed to deionized water and dimethyl sulfoxide. Morphological analyses were also carried out using hematoxylin and eosin, mercury bromophenol blue, Nile blue, and periodic acid Schiff. Biochemical analyses of total glucose, triacylglyceride (TAG), protein, and acetylcholinesterase levels were performed. The phytochemical analysis of the EO showed (E)-nerolidol as the major compound (30.62%). Larvae susceptibility results showed a LC₅₀ of 34.45 mg/L for EO. Morphological analysis showed that there were histological changes in midgut. For biochemical analyses, the glucose level in the larvae exposed to EO for 24 h decreased significantly, unlike the TAG levels, which increased. The total protein level of the larvae also increased after exposure for 24 h, and acetylcholinesterase levels decreased significantly. Taking all our data into account, we can conclude that EO causes destabilization in larva, leading to histological changes, metabolic deregulation and, consequently, their death.

Toxicity of different fatty acids and methyl esters on Culex quinquefasciatus larvae

The Culex quinquefasciatus mosquito is a vector of several diseases, and its control has been performed with synthetic insecticides, which may have human and environmental side effects. Thus, the use of new and safe molecules are important, and this study evaluated the toxicity of active substances against this mosquito. The oleic, linoleic, linolenic, palmitic and stearic acids and their respective methyl esters were tested against fourth instar C. quinquefasciatus larvae. Oleic, linoleic and linolenic acids had LC50 values of 8.58, 10.04 and 19.78 mg/L, respectively. Histological analysis showed that these three compounds caused cell instability with an increase in the number of vesicles in the fat body and in the midgut cells. Based on these results, glucose, triglyceride, and protein levels were evaluated after 1 h of acid exposure. These compounds decreased in insects treated with linoleic acid. Linolenic acid also caused a significant increase in acetylcholinesterase activity. These results show that oleic, linoleic, and linoleic acids have a lower LC50 for C. quinquefasciatus, affecting its metabolism and the morphology of midgut and fat body.

Larvicidal activity of vegetable oils and esterified compounds against Culex quinquefasciatus (Diptera: Culicidae)

Control of Culex quinquefasciatus using chemical insecticides may result in the selection of resistant mosquito strains. Thus, the use of plant-derived products has been studied as alternative for the mosquito control. Fatty acid methyl esters (FAMEs) obtained by transesterification of vegetable oils may result in compounds with larvicidal potential against C. quinquefasciatus. However, little is known about the morphological, physiological or biochemical effects that these FAMEs may have on mosquito larvae. The present study reports the effects of these FAMEs in mosquito larvae. The FAMEs were obtained by transesterification of canola, corn, sunflower, and soybean oils with acid catalysis and the determination of FAMEs composition was done by gas chromatography-mass spectrometry (GC-MS). Larvae of C. quinquefasciatus were exposed to different concentrations of the vegetable oils and FAMEs. Thereby, different FAMEs showed LC₅₀ values ranging from 42.32 to 196.27mg/L against C. quinquefasciatus larvae. The methyl ester obtained from sunflower oil showed the lowest LC₅₀. Histology of C. quinquefasciatus larvae exposed to LC₅₀ of FAMEs was performed and changes in the midgut and fat body morphology were identified. Therefore, larval mortality and changes in the internal organs suggested that FAMEs might be a promising new class of larvicidalcompounds. Cytotoxicity of FAMEs compounds was assessed with the HeLa human cell line and no effect was observed.

Monitoring acute metabolic changes in the liver and kidneys induced by fructose and glucose using hyperpolarized [2-13 C]dihydroxyacetone

PURPOSE

To investigate acute changes in glucose metabolism in liver and kidneys in vivo after a bolus injection of either fructose or glucose, using hyperpolarized [2-¹³ C]dihydroxyacetone.

METHODS

Spatially registered, dynamic, multislice MR spectroscopy was acquired for the metabolic products of [2-¹³ C]dihydroxyacetone in liver and kidneys. Metabolism was probed in 13 fasted rats at three time points: 0, 70, and 140 min. At 60 min, rats were injected intravenously with fructose (n = 5) or glucose (n = 4) at 0.8 g/kg to initiate acute response. Controls (n = 4) did not receive a carbohydrate challenge.

RESULTS

Ten minutes after fructose infusion, levels of [2-¹³ C]phosphoenolpyruvate and [2-¹³ C]glycerol-3-phosphate halved in liver: 51% (P = 0.0010) and 47% (P = 0.0001) of baseline, respectively. Seventy minutes later, levels returned to baseline. The glucose challenge did not alter the signals significantly, nor did repeated administration of the dihydroxyacetone imaging bolus. In kidneys, no statistically significant changes were detected after sugar infusion other than a 20% increase of the glycerol-3-phosphate signal between 10 and 80 min after fructose injection (P = 0.0028).

CONCLUSION

Hyperpolarized [2-¹³ C]dihydroxyacetone detects a real-time, transient metabolic response of the liver to an acute fructose challenge. Observed effects possibly include ATP depletion and changes in the unlabeled pool sizes of glycolytic intermediates. Magn Reson Med 77:65-73, 2017. © 2016 International Society for Magnetic Resonance in Medicine.

Added fructose: a principal driver of type 2 diabetes mellitus and its consequences

Data from animal experiments and human studies implicate added sugars (eg, sucrose and high-fructose corn syrup) in the development of diabetes mellitus and related metabolic derangements that raise cardiovascular (CV) risk. Added fructose in particular (eg, as a constituent of added sucrose or as the main component of high-fructose sweeteners) may pose the greatest problem for incident diabetes, diabetes-related metabolic abnormalities, and CV risk. Conversely, whole foods that contain fructose (eg, fruits and vegetables) pose no problem for health and are likely protective against diabetes and adverse CV outcomes. Several dietary guidelines appropriately recommend consuming whole foods over foods with added sugars, but some (eg, recommendations from the American Diabetes Association) do not recommend restricting fructose-containing added sugars to any specific level. Other guidelines (such as from the Institute of Medicine) allow up to 25% of calories as fructose-containing added sugars. Intake of added fructose at such high levels would undoubtedly worsen rates of diabetes and its complications. There is no need for added fructose or any added sugars in the diet; reducing intake to 5% of total calories (the level now suggested by the World Health Organization) has been shown to improve glucose tolerance in humans and decrease the prevalence of diabetes and the metabolic derangements that often precede and accompany it. Reducing the intake of added sugars could translate to reduced diabetes-related morbidity and premature mortality for populations.

Ketohexokinase-dependent metabolism of fructose induces proinflammatory mediators in proximal tubular cells

Increased consumption of fructose may play an important role in the epidemic of metabolic syndrome and may presage the development of diabetes, cardiovascular disease, and chronic kidney disease. Once in the cell, fructose is phosphorylated by ketohexokinase (KHK), leading to consumption of ATP, formation of AMP, and generation of uric acid through xanthine oxidoreductase (XOR). This study aimed to examine the direct effects of fructose in human kidney proximal tubular cells (HK-2) and whether they are mediated by the fructose metabolism via KHK. At a similar concentration to that observed in peripheral blood after a meal, fructose induced production of monocyte chemotactic protein 1 (MCP-1) and reactive oxygen species in HK-2 cells. Knockdown of KHK by stable transfection with small hairpin RNA demonstrated that these processes were KHK dependent. Several antioxidants, including specific inhibitors of NADPH oxidase and XOR, prevented MCP-1 secretion. We detected XOR mRNA in HK-2 cells and confirmed its activity by identifying uric acid by mass spectrometry. Fructose increased intracellular uric acid, and uric acid induced production of MCP-1 as well. In summary, postprandial concentrations of fructose stimulate redox- and urate-dependent inflammatory mediators in proximal tubular cells.

Hepatic adaptations to sucrose and fructose

The liver is an important site of postprandial glucose disposal, accounting for the removal of up to 30% of an oral glucose load. The liver is also centrally involved in dietary lipid and amino acid uptake, and the presence of either or both of these nutrients can influence hepatic glucose uptake. The composition of ingested carbohydrate also influences hepatic glucose metabolism. For example, fructose can increase hepatic glucose uptake. In addition, fructose extraction by the liver is exceedingly high, approaching 50% to 70% of fructose delivery. The selective hepatic metabolism of fructose, and the ability of fructose to increase hepatic glucose uptake can, under appropriate conditions (eg, diets enriched in sucrose or fructose, high fructose concentrations), provoke major adaptations in hepatic metabolism. Potential adaptations that can arise in response to these conditions and putative mechanisms driving these adaptations are the subject of this review.

2,5-Anhydro-D-mannitol increases hepatocyte calcium: implications for a hepatic hunger stimulus

The fructose analogue, 2,5-anhydro-D-mannitol (2,5-AM), triggers feeding in rats via a mechanism linked to its ability to trap phosphate and deplete hepatic ATP. This metabolic inhibitor is particularly useful in the study of the role of the liver in initiation of feeding as its effects are preferentially localized to the liver, and its metabolic consequences have been extensively characterized. To determine whether changes in intracellular calcium may participate in a mechanism conveying information about hepatic energy status to the nervous system, we studied the effects of 2,5-AM on intracellular calcium in isolated hepatocytes using the ratiometric indicator, fura-2. 2,5-AM elicited a marked elevation of intracellular calcium within 2-3 min of exposure that returned to baseline upon removal of the agent. Removal of external calcium failed to prevent this response, while emptying intracellular stores prevented it. These data are consistent with the hypothesis that hepatic energy status may be conveyed to the nervous system via a calcium-mediated secretion event.

Lethal hypoglycemic ketosis and glyceroluria in mice lacking both the mitochondrial and the cytosolic glycerol phosphate dehydrogenases

The activities of either the mitochondrial or cytosolic glycerol phosphate dehydrogenase (mGPD, cGPD) plus that of glycerol kinase are required for the use of glycerol in aerobic metabolism and gluconeogenesis. A knockout mouse lacking mGPD has reduced body weight and fertility but shows remarkably normal liver and muscle metabolite levels. The BALB/cHeA mouse strain, which lacks cGPD, breeds well and is phenotypically normal, although it demonstrates metabolite abnormalities in certain tissues. Crosses were made between these two strains, and mice were generated that lacked both dehydrogenases. These mice, although active and nursing well for several days, failed to grow, and usually died within the first week. Liver glycerol phosphate levels were elevated 30-fold, whereas liver ATP, ADP, and AMP levels were reduced by 30-40%. Plasma glycerol was elevated 30- to 50-fold to 30-50 mm, and urine glycerol exceeded 0.45 m (4% w/v). GPD-deficient mice were hypoglycemic, had a 50% increase in plasma free fatty acids, and developed ketonuria within the first day of life. Uncoupling protein-1 mRNA in brown adipose tissue was reduced 60%. These mice share some features of both glycerol kinase deficiency and hereditary fructose intolerance, suggesting the phenotype may be due to the combined effects of the loss of a gluconeogenic substrate, the osmotic effects of glycerol, and the metabolic effects of the accumulation of a phosphorylated metabolite.

Normal thyroid thermogenesis but reduced viability and adiposity in mice lacking the mitochondrial glycerol phosphate dehydrogenase

The mitochondrial glycerol phosphate dehydrogenase (mGPD) is important for metabolism of glycerol phosphate for gluconeogenesis or energy production and has been implicated in thermogenesis induced by cold and thyroid hormone treatment. mGPD in combination with the cytosolic glycerol phosphate dehydrogenase (cGPD) is proposed to form the glycerol phosphate shuttle, catalyzing the interconversion of dihydroxyacetone phosphate and glycerol phosphate with net oxidation of cytosolic NADH. We made a targeted deletion in Gdm1 and produced mice lacking mGPD. On a C57BL/6J background these mice showed a 50% reduction in viability compared with wild-type littermates. Uncoupling protein-1 mRNA levels in brown adipose tissue did not differ between mGPD knockout and control pups, suggesting normal thermogenesis. Pups lacking mGPD had decreased liver ATP and slightly increased liver glycerol phosphate. In contrast, liver and muscle metabolites were normal in adult animals. Adult mGPD knockout animals had a normal cold tolerance, normal circadian rhythm in body temperature, and demonstrated a normal temperature increase in response to thyroid hormone. However, they were found to have a lower body mass index, a 40% reduction in the weight of white adipose tissue, and a slightly lower fasting blood glucose than controls. The phenotype may be secondary to consequences of the obligatory production of cytosolic NADH from glycerol metabolism in the mGPD knockout animal. We conclude that, although mGPD is not essential for thyroid thermogenesis, variations in its function affect viability and adiposity in mice.

Enhanced nephrotoxicity of acetaminophen in fructose-induced hypertriglyceridemic rats: contribution of oxidation and deacetylation of acetaminophen to an enhancement of nephrotoxicity

Fructose-induced hypertriglyceridemic Sprague-Dawley (SD) rats become resistant to hepatotoxicity and susceptible to nephrotoxicity of acetaminophen (APAP) as compared with normal SD rats. Fischer-344 rats, which are susceptible to APAP nephrotoxicity, have two toxic metabolic pathways involving cytochrome P450-dependent oxidation of APAP to N-acetyl-p-benzoquinone imine (NAPQI) and P450-independent deacetylation of APAP to p-aminophenol (PAP). SD rats, however, have only the former pathway. This study was undertaken to investigate whether alterations in the metabolic pathways of APAP and in the intrinsic susceptibility to toxic metabolites are responsible for an enhancement of APAP nephrotoxicity in the fructose-pretreated SD-rats. In the non-pretreated rats, the inhibition of APAP oxidation by the MFO inhibitor, piperonyl butoxide, and deacetylation by carboxyesterase inhibitor, bis(p-nitrophenyl)phosphate, did not alter APAP-induced renal lesions. In contrast, these inhibitors protected the fructose-pretreated rats from APAP-induced renal lesions. Since there were no differences in the severity of gentamicin-, chloroform, and 45 min-ischemia/reperfusion-induced renal lesions between the non-pretreated and the fructose-pretreated rats, it is unlikely that the increased intrinsic susceptibility to chemicals and their metabolites in the fructose-pretreated rats is a major factor in the enhancement of APAP nephrotoxicity. These results indicate that the enhancement of APAP nephrotoxicity in the fructose-pretreated rats is due, at least in part, to an alteration in metabolic pathways of APAP.

Effects of fructose-induced hypertriglyceridemia on hepatorenal toxicity of acetaminophen in rats. II. Role of enhancement of fructose metabolism and overproduction of triglyceride in the liver and kidney on hepatorenal toxicity of acetaminophen

Fructose-induced hypertriglyceridemic rats are resistant to hepatoxicity and susceptible to nephrotoxicity of acetaminophen (APAP) as compared with normal ones. The present studied were designed to evaluate how fructose-treatment affects the developmental mode of hepatorenal toxicity of APAP. First, following fructose-pretreatment for various durations (1 day, 1 week or 3 weeks), 1-day-fructose-pretreatment induced hypertriglyceridemia and enhancement of APAP-nephrectoxicity simultaneously. However, it took at least 3 weeks for fructose-pretreatment to reduce APAP-hepatotoxicity. Second, following fructose, sucrose or glucose-pretreatment for 3 weeks, fructose-pretreated rats showed marked hypertriglyceridemia and modification of APAP-hepatorenal toxicity. Sucrose-pretreated rats showed less effects than fructose-pretreated rats. Glucose-pretreated rats showed no changes in plasma triglyceride and APAP-hepatorenal toxicity. Third, rats with hypertriglyceridemia induced by olive oil or Triton WR-1339 which did not produce enhanced metabolism and triglyceride-overproduction in the liver and kidney showed no modification of APAP-hepatorenal toxicity. Pretreatment of glycerol which was metabolized in liver and kidney and induced an overproduction of triglyceride resulted in an enhancement of APAP-nephrotoxicity. These results indicate that an enhancement of fructose metabolism and an overproduction of triglyceride in liver and kidney are responsible for the modification of APAP-hepatorenal toxicity in fructose-induced hypertriglyceridemic rats.

Dynamic phosphorus-31 spectroscopy after fructose load in experimental biliary liver cirrhosis

RATIONALE AND OBJECTIVES

The authors investigated the usefulness of dynamic phosphorus-31 magnetic resonance (MR) spectroscopy in the assessment of hepatic function by studying the effect of a fructose load on a rat model of liver cirrhosis.

METHODS

In vivo P-31 MR liver spectra of eight rats with bile duct ligature and 10 control rats were obtained every 4.6 minutes before and after intraperitoneal fructose load (10 mmol per kilogram of body weight).

RESULTS

In the basal spectra of the experimental group, the phosphomonoester peak was higher than in the control group (P = .026). After the fructose load, the phosphomonoester peak increase and the inorganic phosphate peak decrease were significantly less marked in the experimental group (P = .003). There was a linear correlation between the serum level of bilirubin and the phosphomonoester increase (r = .61, P < .001).

CONCLUSION

Dynamic P-31 MR spectroscopy may be useful in the assessment of hepatic function in chronic liver disease.

Responses of insulin to oral glucose and fructose loads in marginally copper-deficient rats fed starch or fructose

The purpose of this study was to assess the effects of dietary fructose either alone or in combination with marginal copper deficiency in weanling male rats exposed to their respective diets for only 2 wk. This short duration of exposure to inadequate copper intake prevents progressive morbidity brought about by increasing periods of exposure to dietary copper deprivation. Weanling male rats were fed a copper-deficient (0.6 microgram Cu/g) or a copper-adequate (6.0 micrograms Cu/g) diet containing 62% fructose or 62% starch for 2 wk. Either an oral glucose or an oral fructose tolerance test was conducted after an overnight fast. Insulin levels were elevated by either oral glucose or oral fructose at fasting and at 30 min postload in rats fed fructose compared with those fed starch. Despite high levels of plasma, insulin blood glucose was not reduced. Marginal copper deficiency had no effect on either plasma insulin or blood glucose. Data identify fructose as the sole agent responsible for inducing adverse changes in glucose metabolism. Two weeks of fructose consumption was sufficient to produce these changes.

Mitochondrial free radical production induces lipid peroxidation during myohemoglobinuria

Iron catalyzed free radical formation and lipid peroxidation are accepted mechanisms of heme protein-induced acute renal failure. However, the source(s) of those free radicals which trigger lipid peroxidation in proximal tubular cells remains unknown. This study tested the potential involvement of mitochondrial electron transport, xanthine oxidase activity, and arachidonic acid metabolism in the heme-induced peroxidative state. The impact of cytosolic Ca2+ loading also was assessed. Rhabdomyolysis was induced in mice by glycerol injection, and two hours later heme-laden proximal tubular segments (PTS) were isolated for study. PTS from normal mice served as controls. During 30 to 60 minute incubations, heme loaded PTS developed progressive cytotoxicity (LDH release) and iron-dependent lipid peroxidation (malondialdehyde, MDA, generation; inhibited by deferoxamine). Site 2 (antimycin A) or site 3 (cyanide, hypoxia) mitochondrial respiratory chain inhibition completely blocked lipid peroxidation, whereas site 1 inhibition (rotenone) doubled its extent (presumably by shunting NADH through NADH dehydrogenase, a free radical generating system). Conversely, these agents did not substantially alter MDA in normal PTS. Normal and heme loaded PTS developed comparable degrees of LDH release during respiratory blockade irrespective of increased or decreased MDA production (indicating that lipid peroxidation was not a critical determinant of cell death). Neither increasing free arachidonic acid (PLA2 treatment) nor adding cyclooxygenase/lipoxygenase/cytochrome p450 inhibitors conferred a consistent protective effect. Altering free Ca2+ status (chelators; ionophore addition) and xanthine oxidase inhibition had no discernible impacts. Despite mitochondrial free radical production, mitochondrial function, as assessed by the ATP/ADP ratio, seemingly remained intact. In conclusion, (1) the terminal mitochondrial respiratory chain is the dominant source of free radicals which trigger PTS lipid peroxidation; (2) iron is a required secondary factor; (3) although mitochondria fuel lipid peroxidation, they do not appear to be critical targets of the heme-induced oxidant attack.

Allyl alcohol cytotoxicity in isolated rat hepatocytes: effects of azide, fasting, and fructose

The role of altered energy homeostasis in the lethality of allyl alcohol to isolated rat hepatocytes was studied. ATP, ADP, AMP, and viability loss (leakage of lactate dehydrogenase into the medium) were measured in isolated hepatocytes of fed or fasted rats exposed to 0.5 mM allyl alcohol. Adenine mononucleotides and cytotoxicity were determined also in hepatocytes incubated with allyl alcohol in the presence of 4 mM sodium azide or 15 mM fructose. Allyl alcohol-induced cell death in hepatocytes of fed rats was preceded by slight decreases in ATP content and energy charge (16% and 12%, respectively). More substantial decreases in these parameters occurred in parallel with cell killing, but the effect of allyl alcohol on energy status did not exceed the effect produced by a nonlethal concentration of sodium azide. Neither azide nor fructose affected the development of allyl alcohol cytotoxicity. Moreover, allyl alcohol-induced cytotoxicity was similar in hepatocytes of fed and fasted rats. The results suggest that altered energy homeostasis is a consequence rather than a cause of allyl alcohol-induced hepatocyte lethality.

Assessment of absolute metabolite concentrations in human tissue by 31P MRS in vivo. Part II: Muscle, liver, kidney

Absolute metabolite concentrations were assessed in the muscle, the liver, and the kidney of healthy human volunteers by 31P MRS. Fully relaxed in vivo spectra were acquired with a surface coil and were localized with an adiabatic ISIS pulse sequence. The spectra were quantified with a subsequent measurement of a calibration phantom and were processed iteratively in the time domain. The following mean metabolite concentrations (mmol/liter) were measured in the resting male calf muscle (n = 9), in the fasting liver (n = 12), and in the orthotopic kidney (n = 5): [PME] = 2.0 +/- 0.6, 3.8 +/- 0.7, and 2.6 +/- 0.9, [Pi] = 2.9 +/- 0.3, 1.8 +/- 0.3, and 1.6 +/- 0.4, [PDE] = 3.8 +/- 0.8, 9.7 +/- 1.5, and 4.9 +/- 1.1, [PCr] = 22.0 +/- 1.2, 0, and 0, [NTP] = 5.7 +/- 0.4, 2.9 +/- 0.4, and 2.0 +/- 0.3, respectively. Several interesting findings are to be emphasized: The concentrations of Pi, PCr, and NTP were 20% lower in the muscle of women than of men. In addition, the pHi was significantly lower in female muscle (6.99 +/- 0.03) than in male muscle (7.05 +/- 0.03). The pHi in the liver (7.12 +/- 0.09) and in the kidney (7.09 +/- 0.08) were higher than in the muscle of both genders. The free magnesium concentration (mmol/liter) was higher in the liver (1.40 +/- 0.64) than in the kidney (0.79 +/- 0.39) and in the muscle (0.52 +/- 0.10).

Decrease in cytosolic ATP/ADP ratio and activation of pyruvate kinase after in vitro addition of almitrine in hepatocytes isolated from fasted rats

Previously, we have shown in experiments with isolated mitochondria that almitrine, a drug used for patients with chronic lung disease, affects the H+/ATP stoichiometry of the F0F1-ATPase [Rigoulet, M., Fraisse, L., Ouhabi, R., Guérin, B., Fontaine, E. & Leverve, X. M. (1990) Biochim. Biophys. Acta 1018, 91-97]. In the present study, we have investigated the effect of almitrine on gluconeogenesis and oxygen consumption in isolated hepatocytes. Almitrine decreased both the cytosolic and mitochondrial ATP/ADP ratios but had no effect on oxygen consumption in cells incubated with and without octanoate. This must have been due to a double effect. On the one hand, a decrease in the ATP/ADP ratio decreases ATP utilization; on the other hand, in the presence of almitrine more oxygen is required to synthesize ATP. Almitrine did affect gluconeogenesis from various substrates (lactate + pyruvate, glycerone or fructose), but had no effect on glycerol or glutamine metabolism. The effect on gluconeogenesis from glycerone was due to an increase in glycolytic flux. The rate of lactate + pyruvate production increased whereas there was no effect on glycerone utilization. This effect was caused by an activation of pyruvate kinase. Our data indicate that this enzyme is an extremely sensitive sensor of the cytosolic ATP/ADP ratio. Hence, under our experimental conditions, the cytosolic ATP/ADP ratio decrease affects only the balance between glucose and lactate + pyruvate productions, and not the phosphorylation of glycerone, the first and controlling step of this pathway.

Corneal tolerance of vitrifiable concentrations of glycerol

Equilibration of corneas with sufficiently high concentrations of cryoprotectants to inhibit potentially damaging ice formation during cryopreservation has not yet been achieved. This study examined the effects on the structure and function of rabbit corneal endothelium of the low toxicity cryoprotectant glycerol. Corneas were exposed to concentrations ranging from 2.0 to 6.8 M glycerol in a Hepes-buffered Ringer's solution containing glutathione, adenosine, 5 mM sodium bicarbonate and 6% w/v bovine serum albumin. Endothelial function was assessed by monitoring corneal thickness during perfusion of the endothelial surface at 34 degrees C for 6 h. Endothelial structure was observed using specular microscopy during perfusion and scanning electron microscopy after perfusion. Corneas tolerated exposure to 2.0 and 3.4 M glycerol for 20 min at 4 and -5 degrees C, respectively. Tolerance of 4.8 M glycerol for 10 min at -10 degrees C was improved by decreasing the dilution temperatures. Ten-minute exposure to 6.1 and 6.8 M glycerol was tolerated at -15 degrees C. In all cases corneas initially showed signs of damage but endothelial function was regained following structural repair. Corneas exposed to 6.8 M glycerol and cooled below the glass transition temperature were nonfunctional after warming. Ice formation during warming was believed to be the cause of injury.

Prevention of nitrofurantoin-induced cytotoxicity in isolated hepatocytes by fructose

Nitrofurantoin is a widely utilized urinary antimicrobial drug which has been associated with pulmonary fibrosis, neuropathy, and hepatitis as well as hemolytic anemia in glucose-6-phosphate dehydrogenase-deficient individuals. Incubation of freshly isolated rat hepatocytes with nitrofurantoin caused oxygen activation as a result of futile redox cycling. Glutathione disulfide (GSSG) was formed and rapidly exported from the cell resulting in complete glutathione (GSH) depletion followed by cell death. However, fructose prevented the export of GSSG from the cell and GSH levels recovered rapidly without cytotoxicity occurring. Fructose did not affect nitrofurantoin metabolism but rapidly depleted cellular ATP levels by approximately 80% which remained depressed during the incubation period. Fructose, however, did not protect hepatocytes from nitrofurantoin-induced cytotoxicity if GSH was depleted beforehand. Protection by fructose only occurred at concentrations which caused ATP depletion. These results suggest that fructose prevents nitrofurantoin-induced toxicity by depleting ATP and thereby preventing the ATP-dependent GSSG efflux. GSSG is retained enabling NADPH and glutathione-reductase to reduce the GSSG back to GSH, thereby protecting the cell from nitrofurantoin-induced oxidative stress.

Phosphocreatine protects ATP from a fructose load in transgenic mouse liver expressing creatine kinase

The effects of an intraperitoneal dose of fructose on hepatic metabolism in transgenic mice expressing creatine kinase in liver were investigated using phosphorus-31 nuclear magnetic resonance (31P-NMR). Transgenic mice were fed diets containing varying amounts of creatine (Cr; 0-12%). It has previously been shown that 31P-NMR spectra of transgenic mice have a peak due to phosphocreatine (PCr), the intensity of which was proportional to the amount of Cr in the diet. No PCr peak was detected in control mice or transgenic mice not fed Cr. In the present study NMR spectra were collected before and for a 1-h recovery period after infusion of 0.15 mmol/10 g body wt fructose. In all mice infusion of fructose resulted in a two- to threefold elevation of phosphomonoesters. In control and non-Cr-fed transgenic mice this was accompanied by a 60% reduction of the inorganic phosphate (Pi) and a 50% fall in ATP. In transgenic mice fed Cr, the extent of reduction of Pi was dependent on the level of PCr and was markedly reduced compared with controls. Falls in Pi of 46, 24, and 6% were detected 12.5 min after fructose infusion in low, intermediate, and high PCr-containing livers, respectively. The presence of PCr also protected hepatic ATP levels from a fructose load. Transgenic mice fed on high or intermediate Cr diets showed no significant loss of ATP. However, livers with low levels of PCr lost ATP during a fructose challenge. From the equilibrium established by creatine kinase, free ADP levels were calculated throughout the fructose dose. Fructose caused a 2.5-fold increase in free ADP. This rise in ADP was independent of the total Cr or whether Pi and ATP were reduced by fructose infusion. These results indicate that an increase in ADP is not sufficient to cause depletion of ATP during a fructose challenge.

Myoglobin depletes renal adenine nucleotide pools in the presence and absence of shock

To assess whether myoglobin adversely affects renal adenylate pools, rats were infused with purified myoglobin (50 mg/100 g body wt) for two hours and renal ATP, ADP, and AMP levels were measured in the absence of shock, after 25 minutes of hemorrhagic shock (55 to 60 mm Hg) or 30 minutes post-recovery. In the absence of shock, myoglobin lowered ATP by 24% (assessed 65 min post-infusion) without affecting renal blood flow (RBF). This effect was completely blocked by deferoxamine (DFO) treatment and it could not be reproduced by ribonuclease infusion (a non-Fe containing, but filtered, protein). Myoglobin + shock caused a three- to fourfold greater decline in ATP than did shock alone despite comparable RBFs. Shock plus myoglobin, but neither one alone, induced substantial S1/S2 proximal tubular morphologic damage and a severe reduction in creatinine clearance, confirming synergistic injury. Ribonuclease completely reproduced myoglobin's effect on shock-induced adenylate profiles. DFO +/- hydroxyl radical scavenger therapy (Na benzoate) did not block the myoglobin shock effect on adenylate pools. Post-shock adenylate recovery was not compromised by myoglobin pre-treatment. If renal artery occlusion (RAO), rather than shock, was used as the ischemic challenge, myoglobin had no discernible impact on adenine nucleotide content. This study concludes that: 1) myoglobin modestly lowers baseline adenylate pools due to an Fe dependent mechanism; 2) myoglobin drastically accentuates shock-induced adenylate depletion by a non-hemodynamic/non-Fe dependent mechanism; 3) myoglobin nephrotoxicity cannot be attributed solely to tissue iron loading; and 4) the RAO model can completely mask important influences on ischemic cellular energetics.(ABSTRACT TRUNCATED AT 250 WORDS)

Cryoprotectant toxicity and cryoprotectant toxicity reduction: in search of molecular mechanisms

Cryoprotectant toxicity is a fundamental obstacle to the full potential of artificial cryoprotection, yet it remains in general a poorly understood phenomenon. Unfortunately, most relevant biochemical studies to date have not met the basic criteria required for demonstrating mechanisms of toxicity. A model biochemical study of cryoprotectant toxicity was that of Baxter and Lathe, which demonstrated that alteration of a specific enzyme (fructose diphosphatase, or FDPase) was the cause of impaired glycolysis after treatment with and removal of dimethyl sulfoxide (D). FDPase alteration by D was reported to be preventable by the simultaneous presence of amides. This protection could be due to a "counteracting solute" effect similar to that employed by nature, but we find no meaningful correlation between the general protein stabilizing or destabilizing tendency of the cryoprotectant medium and its toxicity. Baxter and Lathe postulated that the effect of D arises from hydrogen bonding between D and the epsilon amino groups of surface lysine residues on FDPase, and it was found that molecules which resembled this group could block the alteration induced by D, presumably by competing with lysine residues for association with D. However, we find that the interaction between D and lysine in the presence of water is actually thermochemically repulsive, and that the presence of formamide does not affect the interaction between D and lysine, implying no useful complex formation between formamide and D. We were also unable to demonstrate that the blocking compounds consistently reduce toxicity when added to D rather than substituting for D, contrary to predictions based on complex formation between blocking compounds and D. In summary, it seems that present concepts of cryoprotectant toxicity are in need of serious revision.

Flavor preferences and fructose: evidence that the liver detects the unconditioned stimulus for calorie-based learning

Previous work suggests that fuel oxidation in the liver provides an unconditioned stimulus for "calorie-based" flavor preference learning. To investigate this possibility in more detail, we manipulated liver metabolism by taking advantage of the greater specificity to the liver of fructose than glucose. Intact rats preferred flavored food ingested with a drink of 35% fructose solution to flavored food eaten with either no sweet drink (Experiment 1) or an equicaloric drink of glucose (Experiment 2). The effect on food preference did not depend on the taste of the sugar solutions: when given a choice between glucose and fructose solutions, the rats drank the same volume of each. Moreover, a preference for fructose-paired flavored food was obtained when fructose and glucose solutions were given by gavage (Experiment 3). Unlike intact rats, rats with hepatic vagotomy preferred equally flavored food paired with fructose solution and flavored food paired with no sugar solution (Experiment 1). They also avoided flavored food paired with gavage of fructose slightly, relative to flavored food paired with gavage of glucose (Experiment 3). These results suggest that the unconditioned stimulus for calorie-based conditioning is transduced in the liver, and that an intact hepatic vagus nerve is required for conditioning to occur.

Effect of momentary stress on brain energy metabolism in weanling mice: apparent use of lactate as cerebral metabolic fuel concomitant with a decrease in brain glucose utilization

The hypothesis that the anxiety induced by repeated injections affects brain energy metabolism was tested. Normal 19- to 21-day-old mice were stressed by two sham intraperitoneal injections within 4 min, at which time they were decapitated. Noninjected, control littermates were quickly decapitated. Momentary stress increased plasma glucose (12%), glycerol (85%), beta-hydroxybutyrate (108%), and lactate (153%)--a reflection of elevated plasma cortisol (25%) and glucagon (45%). In brain, stress increased levels of glucose-6-P (15%) and fructose-6-P (17%). The brain pyruvate concentration increased 74%; lactate 76%. Citrate, alpha-ketoglutarate, and malate increased 15, 95, and 37%, respectively. Levels of glycogen, glucose, phosphocreatine, ATP, ADP, and AMP were unchanged. The brain lactate/pyruvate ratio was normal but the brain/plasma lactate ratio fell 32%. Metabolite changes in the stressed animals were compatible with a decrease in the glycolytic flux at the phosphofructokinase step and a paradoxical increased flux in the Krebs citric acid cycle. The decreased brain/plasma lactate ratio supported increased uptake of lactate from plasma and increased brain lactate oxidation. Metabolite changes similar to those described above occurred in unstressed mice injected with lactate. Findings confirm a positive effect of stress on brain metabolism, support a role for lactate as an oxidative fuel for brain, and caution that the rate of cerebral glucose utilization may not always reflect brain energy (oxidative) metabolism accurately.

The importance of nucleoside triphosphate inhibition of liver glycogen synthase phosphatase activity

The liver glycogen particle contains constitutive glycogen-synthase phosphatase activity which is inhibited by ATP-Mg in a concentration-dependent manner within the physiological range (I0.5 = 0.1 mM). Therefore, we determined whether other nucleoside triphosphate-magnesium complexes also inhibit synthase phosphatase activity. UTP-Mg, CTP-Mg and GTP-Mg were all found to be inhibitory. The maximum inhibition was 85-90% which was greater than that for ATP-Mg. The I0.5 for UTP-Mg was comparable to that of ATP-Mg but it was greater for CTP-Mg and for GTP-Mg. At in vivo physiological concentrations, both UTP and ATP are possible inhibitors of synthase phosphatase activity. In the presence of a saturating concentration of ATP-Mg, added UTP-Mg increased the inhibition suggesting the presence of at least two distinct nucleotide binding sites. Substitution of calcium for magnesium in an ATP complex had no effect on the I0.5, but increased the maximum inhibition. The present studies also suggest that in the multistep conversion of synthase D to synthase I, ATP-Mg inhibition occurs early in the sequence. Addition of glycogen, a known inhibitor of synthase phosphatase activity, to a reaction mixture containing 3 mM ATP-Mg did not further inhibit synthase phosphatase activity when added at concentrations up to 22 mg/ml. The latter data suggest that the presence of a nucleoside triphosphate may desensitize the phosphatase to glycogen inhibition. ATP-Mg and, to a lesser extent, UTP-Mg and CTP-Mg all stimulated phosphorylase phosphatase activity but GTP-Mg did not.

Effect of glycerol and dihydroxyacetone on hepatic lipogenesis

Glycerol is a dietary component which is metabolized primarily by the liver and kidney where it is used mainly for glucose synthesis. The metabolism of glycerol is very similar to that of dihydroxyacetone which can be considered its more oxidized counterpart. The effects of these substrates on hepatic lipogenesis and gluconeogenesis were examined. In isolated hepatocytes, 10 mM dihydroxyacetone caused a large increase in glucose output and stimulated lipogenesis without affecting the lactate/pyruvate ratio or the total ATP content of the cells. (As compared to dihydroxyacetone, 10 mM glycerol was less effective as a gluconeogenic substrate, increased the lactate/pyruvate ratio, caused a slight decrease in the total ATP content, and inhibited lipogenesis by at least 40% depending on the type of diet fed to the rats.) The fall in ATP levels was very small and did not correlate with the changes in fatty acid synthesis. The immediate cause of the inhibition of lipogenesis, brought about by glycerol in hepatocytes from sucrose fed rats, seemed to be a large decrease in pyruvate levels. This did not result from impairment of glycolysis but from a rise in the cytosolic NADH/NAD ratio.

Does glyceraldehyde enter pancreatic islet metabolism via both the triokinase and the glyceraldehyde phosphate dehydrogenase reactions? A study of these enzymes in islets

Glyceraldehyde has been known to be an insulin secretagogue for more than 15 years. It has been (reasonably) assumed that glyceraldehyde enters the glycolytic pathway via its phosphorylation by ATP to form glyceraldehyde phosphate, a reaction catalyzed by the enzyme triokinase, and that subsequent metabolism is identical to that of glucose. glucose. However, up to now there have been no studies verifying the presence of triokinase in the pancreatic beta cell. We report here that (1) the activity of triokinase in pancreatic islets is very low, indicating that the activity is intrinsically low and/or the enzyme was rapidly inactivated during the preparation of tissue for assay; (2) the activity is much lower than glucose phosphorylating activity (hexokinase plus glucokinase) in islets, even though glyceraldehyde is a more efficient insulin secretagogue than glucose; (3) glyceraldehyde phosphate dehydrogenase from pancreatic islets can use glyceraldehyde as a substrate in place of glyceraldehyde phosphate (the Vmax of glyceraldehyde phosphate dehydrogenase from islets when glyceraldehyde is the substrate is 20-fold that of triokinase when glyceraldehyde is the substrate); and (4) the Km of glyceraldehyde phosphate dehydrogenase with respect to glyceraldehyde (4.8 mM) is similar to the concentration of glyceraldehyde that gives one-half maximal rates of insulin release from pancreatic islets, whereas the Km of triokinase with respect to glyceraldehyde is much lower (less than 50 microM). These data suggest that besides stimulating insulin release in islets via its entering metabolism by phosphorylation to glyceraldehyde phosphate in the triokinase reaction, glyceraldehyde could be phosphorylated by Pi in the glyceraldehyde phosphate dehydrogenase reaction to form glycerate 1-phosphate which is probably unmetabolizable in islets. The second reaction could drastically increase the NADH/NAD ratio in islets without providing substrates for hydrogen shuttles that reoxidize cytosolic NADH. Since an increased NAD(P)H/NAD(P) ratio is believed to be a key part of the signal for insulin release, such a mechanism would explain the potent insulinotropism of glyceraldehyde in short-term experiments. In addition, the formation of unmetabolizable acids may explain the toxic effects of long-term exposure of islets to glyceraldehyde and why glyceraldehyde causes the beta cell to become acidic, whereas glucose does not.

Urine glyceraldehyde excretion is elevated in the renal Fanconi syndrome

We analyzed urinary constituents using GC/MS in 16 children with the renal Fanconi syndrome and 13 normal individuals. Urine glyceraldehyde levels were strikingly elevated in the renal Fanconi syndrome group (mean 5.1 +/- 4.8 mg/mg creatinine) compared to levels in the normal group (mean 0.04 +/- 0.04 mg/mg creatinine, P less than 0.001). Urine lactate levels were also elevated in the renal Fanconi syndrome group (mean 2.3 +/- 2.6 mg/mg creatinine) compared to normals (mean 0.01 +/- 0.01 mg/mg creatinine, P less than 0.003). Only small elevations of glyceraldehyde and lactate were found in urine from children with other renal disorders. Serum levels of glyceraldehyde and lactate were no greater in individuals with the Fanconi syndrome than in the normals. The fractional reabsorption of both glyceraldehyde and lactate was virtually complete in the normals, but was markedly impaired in the Fanconi syndrome patients where, in some cases, glyceraldehyde excretion greatly exceeded the excretion of creatinine. We conclude that marked glyceraldehyde excretion is a previously unrecognized feature of the renal Fanconi syndrome which may result from disordered proximal tubular glycolytic metabolism. Further studies will be required to determine the role of glyceraldehyde loss in the pathogenesis of this generalized disturbance of proximal tubular function.

Glycogen synthase activation by sugars in isolated hepatocytes

We have investigated the activation by sugars of glycogen synthase in relation to (i) phosphorylase a activity and (ii) changes in the intracellular concentration of glucose 6-phosphate and adenine nucleotides. All the sugars tested in this work present the common denominator of activating glycogen synthase. On the other hand, phosphorylase a activity is decreased by mannose and glucose, unchanged by galactose and xylitol, and increased by tagatose, glyceraldehyde, and fructose. Dihydroxyacetone exerts a biphasic effect on phosphorylase. These findings provide additional evidence proving that glycogen synthase can be activated regardless of the levels of phosphorylase a, clearly establishing that a nonsequential mechanism for the activation of glycogen synthase occurs in liver cells. The glycogen synthase activation state is related to the concentrations of glucose 6-phosphate and adenine nucleotides. In this respect, tagatose, glyceraldehyde, and fructose deplete ATP and increase AMP contents, whereas glucose, mannose, galactose, xylitol, and dihydroxyacetone do not alter the concentration of these nucleotides. In addition, all these sugars, except glyceraldehyde, increase the intracellular content of glucose 6-phosphate. The activation of glycogen synthase by sugars is reflected in decreases on both kinetic constants of the enzyme, M0.5 (for glucose 6-phosphate) and S0.5 (for UDP-glucose). We propose that hepatocyte glycogen synthase is activated by monosaccharides by a mechanism triggered by changes in glucose 6-phosphate and adenine nucleotide concentrations which have been described to modify glycogen synthase phosphatase activity. This mechanism represents a metabolite control of the sugar-induced activation of hepatocyte glycogen synthase.