Effect of protein ingestion on splanchnic and leg metabolism in normal man and in patients with diabetes mellitus.

The inter-organ flux of substrates after a protein-rich meal was studied in seven healthy subjects and in eight patients, with diabetes mellitus. Arterial concentrations as well as leg and splanchnic exchange of amino acids, carbohydrate substrates, free fatty acids (FFA), and ketone bodies were examined in the basal state and for 3 h after the ingestion of lean beef (3 g/kg body wt). Insulin was withheld for 24 h before the study in the diabetic patients. In the normal subjects, after protein ingestion, there was a large amino acid release from the splanchnic bed predominantly involving the branched chain amino acids. Valine, isoleucine, and leucine accounted together for more than half of total splanchnic amino acid output. Large increments were seen in the arterial concentrations of the branched chain amino acids (100-200%) and to a smaller extent for other amino acids. Leg exchange of most amino acids reverted from a basal net outut to a net uptake after protein feeding which was most marked for the branched chain amino acids. The latter accounted for more than half of total peripheral amino acid uptake...

Splanchnic and leg exchange of glucose, amino acids, and free fatty acids during exercise in diabetes mellitus.

The influence of exercise on leg and splanchnic exchange of substrates was examined in eight insulin-dependent diabetics 24 h after withdrawal of insulin and in eight healthy controls studied at rest and after 40 min of bicycle ergometer exercise at 55-60% of maximal capacity. In four of the diabetic subjects, basal arterial ketone acid levels were 3-4 mmol/ liter (ketotic diabetics) and in the remainder, below 1 mmol/liter (nonketotic diabetics). ,ree fatty acid (FFA) turnover and regional exchange were evaluated with 14-C- labeled oleic acid. Leg uptake of blood glucose rose 13-18 fold during exercise in both the diabetics and controls and accounted for a similar proportion of the total oxygen uptake by leg muscles (25-28%) in the two groups. In contrast, leg uptake of FFA corresponded to 39% of leg oxygen consumption in the diabetic group but only 27% in controls. Systemic turnover of oleic acid was similar in the two groups. Splanchnic glucose output increased during exercise 3-4 fold above resting levels in both groups. In the diabetics, splanchnic uptake of lactate, pyruvate, glycerol, and glycogenic amino acids rose more than twofold above resting levels and was fourfold greater than in exercising controls. Total precursor uptake could account for 30% of the splanchnic glucose output in the diabetic group. In contrast, in the controls, total splanchnic uptake of glucose precursors was no greater during exercise than in the resting state and could account for no more than 11% of splanchnic glucose output. The augmented precursor uptake during exercise in the diabetics was a consequence of increased splanchnic fractional extraction as well as increased peripheral production of gluconeogenic substrates. The arterial glucagon concentration was unchanged by exercise in both groups, but was higher in the diabetics. In the diabetic subjects with ketosis in the resting state, exercise elicited a rise in arterial glucose and FFA, an augmented splanchnic uptake of FFA, and a 2-3 fold increase in splanchnic output of 3-hydroxybutyrate. Uptake of 3-hydroxybutyrate by the exercising leg rose more rapidly than splanchnic production, resulting in a fall in arterial levels of 3-hydroxybutyrate. It is concluded that (a) glucose uptake by exercising muscle in hyperglycemic diabetics is no different from that of controls; (b) splanchnic glucose output rises during exercise to a similar extent in diabetics and controls, while uptake of gluconeogenic substrates is markedly higher in diabetics and accounts for a greater proportion of total splanchnic glucose output; (c) exercise in diabetic patients with mild ketosis is associated with a rise in blood glucose and FFA levels as well as augmented splanchnic production and peripheral uptake of ketone bodies.

Uptake of individual free fatty acids by skeletal muscle and liver in man.

Arterial-venous concentration differences for individual free fatty acids (FFA) were measured across the deep tissues of the forearm, the splanchnic vascular bed, and the kidney in healthy, postabsorptive subjects. In addition, arterial-portal venous FFA differences were determined in five patients undergoing elective cholecystectomy. The differences in fractional uptake among the individual FFA across the forearm were small and not statistically significant. Splanchnic fractional uptake was high for FFA with short chain lengths and rose with increasing degree of unsaturation. Small, negative arterial-portal venous differences for individual FFA were observed, indicating that arterial-hepatic venous FFA differences mainly reflect hepatic uptake. When the arterial FFA concentration was reduced to approximately 25% of the control values by the administration of nicotinic acid, net uptake of total FFA ceased but there was release of stearic acid and uptake of lauric, myristic, and palmitoleic acid to the splanchnic region. Muscle and liver uptakes of individual FFA were both dependent on their arterial concentrations with the exception of the splanchnic uptake of stearic acid. There was no uptake of free arachidonic acid by either muscle or liver, nor was there significant uptake of any of the free fatty acids by the kidney. It is concluded (a) that there are important quantitative differences between the net exchanges of individual FFA across the splanchnic vascular bed, (b) that tracer studies of FFA metabolism require the determination of individual FFA specific activities, (c) that palmitic and oleic acid appear to be suitable tracers for the entire FFA fraction in most instances.

Turnover and splanchnic metabolism of free fatty acids in hyperthyroid patients.

The arterial concentration and turnover rate and the splanchnic exchange of FFA were examined after an overnight fast in a group of 11 female patients with clinical and laboratory evidence of hyperthyroidism. [14C]oleic acid was infused intravenously and the hepatic venous catheter technique was used. As compared with healthy control individuals, the arterial concentrations of FFA and oleic acid were elevated by 30--40% in the hyperthyroid group. Both the turnover rate and the fractional turnover of oleic acid were significantly increased. The turnover rate correlated directly with arterial concentration of oleic acid in both the control and the patient group but the slope was steeper in the patients. The splanchnic uptake of oleic acid was three times higher than in the control group. The augmented uptake was a consequence of elevated arterial concentrations and increased hepatic plasma flow, whereas fractional splanchnic uptake remained unchanged. Ketone body production was four- to fivefold greater in the patients and could be largely accounted for by increased splanchnic FFA uptake. In six patients studied after treatment resulting in a return to normal thyroid function, a significant reduction was observed in arterial FFA, estimated hepatic blood flow, oleic acid turnover, and ketone body production. It is concluded that hyperthyroidism is characterized by increased turnover and splanchnic uptake of FFA and augmented ketogenesis. These findings can be explained on the basis of elevated arterial FFA concentrations and increased blood flow, particularly to the splanchnic bed.

Turnover and splanchnic metabolism of free fatty acids and ketones in insulin-dependent diabetics at rest and in response to exercise.

Nine insulin-dependent diabetics and six healthy controls were studied at rest, during, and after 60 min of bicycle exercise at a work load corresponding to 45% of their maximal oxygen intake. The catheter technique was employed to determine splanchnic and leg exchange of metabolites. FFA turnover and regional exchange was evaluated using [14C]oleate infusion. Basal glucose (13.8 +/- 1.1 mmol/l), ketone body (1.12 +/- 0.12 mmol/l), and FFA (967 +/- 110 mumol/l) concentrations were elevated in the diabetics in comparison with controls. In the resting state, splanchnic ketone acid production in the diabetics was 6-10-fold greater than in controls. Uptake of oleic acid by the splanchnic bed was increased 2-3-fold, and the proportion of splanchnic FFA uptake converted to ketones (61%) was threefold greater than in controls. In contrast, splanchnic fractional extraction of oleic acid was identical in diabetics and controls. A direct relationship was observed between splanchnic uptake and splanchnic inflow (plasma concentration X hepatic plasma flow) of oleic acid that could be described by the same regression line in the diabetic and control groups. During exercise, splanchnic ketone production rose in both groups. In the control group the increase in ketogenesis was associated with a rise in splanchnic inflow and in uptake of oleic acid, a rise in splanchnic fractional extraction of oleate, and an increase in the proportion of splanchnic FFA uptake converted to ketone acids from 20-40%. In the diabetic group, the increase in ketogenesis occurred in the absence of a rise in splanchnic inflow or uptake of oleic acid, but was associated with an increase in splanchnic fractional extraction of oleic acid and a marked increase in hepatic conversion of FFA to ketones, so that the entire uptake of FFA was accountable as ketone acid output. Splanchnic uptake of oleic acid correlated directly with splanchnic oleic acid inflow in both groups, but the slope of the regression line was steeper than in the resting state. Plasma glucagon levels were higher in the diabetic group at rest and during exercise, while plasma norepinephrine showed a twofold greater increment in response to exercise in the diabetic group (to 1,400-1,500 pg/ml). A net uptake of ketone acids by the leg was observed during exercise but could account for less than 5% of leg oxidative metabolism in the diabetics and less than 1% in controls. Despite the increase in ketogenesis during exercise, a rise in arterial ketone acid levels was not observed in the diabetics until postexercise recovery, during which sustained increments to values of 1.8-1.9 mmol/l and sustained increases in splanchnic ketone production were observed at 30-60 min. The largest increment in blood ketone acids and in splanchnic ketone production above values observed in controls thus occurred in the diabetics after 60 min of recovery from exercise. We concluded that: (a) In the resting state, increased ketogenesis in the diabetic is a consequence of augmented splanchnic inflow of FFA and increased intrahepatic conversion of FFA to ketones, but does not depend on augmented fractional extraction of circulating FFA by the splanchnic bed. (b) Exercise-induced increases in ketogenesis in normal subjects are due to augmented splanchnic inflow and fractional extraction of FFA as well as increased intrahepatic conversion of FFA to ketones. (c) When exercise and diabetes are combined, ketogenesis increases further despite the absence of a rise in splanchnic inflow of FFA. An increase in splanchnic fractional extraction of FFA and a marked increase intrahepatic conversion of FFA to ketones accounts for the exaggerated ketogenic response to exercise in the diabetic. (d) Elevated levels of plasma glucagon and/or norepinephrine may account for the increased hepatic ketogenic response to exercise in the diabetic. (e) Ketone utilization by muscle increases during exercise but constitutes a quantitatively minor oxidative fuel for muscle even in the diabetic. (f) The accelerated ketogenesis during exercise in the diabetic continues unabated during the recovery period, resulting in an exaggerated postexercise ketosis.

Influence of somatostatin on splanchnic glucose metabolism in postabsorptive and 60-hour fasted humans.

Cyclic somatostatin was administered intravenously (10 mug/min for 60 min) to 10 healthy overnight fasted (postabsorptive) subjects and to 5 healthy 60-h fasted subjects. In both groups, arterial insulin and glucagon fell 50% and splanchnic release of these hormones was inhibited. In the overnight fasted subjects splanchnic glucose output fell 70%, splanchnic uptake of lactate and pyruvate was unchanged, alanine uptake fell by 25%, and glycerol uptake rose more than twofold in parallel with an increase in arterial glycerol. In the 60-h fasted group splanchnic glucose output was less than 40% of that observed in the overnight fasted subjects. Somatostatin led to a further decrease (--70%) in glucose production. Splanchnic uptake of lactate and pyruvate fell by 30-40%, amino acid uptake was unchanged, while uptake of glycerol rose fivefold. Total uptake of glucose precursors thus exceeded the simultaneous glucose output by more than 200%. Splanchnic uptake of FFA rose fourfold during somatostatin while output of beta-hydroxybutyrate increased by 75%. Estimated hepatic blood flow fell 25-35% and returned to base line as soon as the somatostatin infusion ended. It is concluded that (a) somatostatin-induced hypoglucagonemia results in inhibition of splanchnic glucose output in glycogen-depleted, 60-h fasted subjects as well as in postabsorptive subjects, indicating an effect of glucagon on hepatic gluconeogenesis as well as glycogenolysis; (b) the glucagonsensitive step(s) in gluconeogenesis affected by somatostatin involves primarily intra-hepatic disposal rather than net hepatic uptake of glucose precursors; (c) splanchnic uptake of fatty acids and ketone output are increased in the face of combined insulin and glucagon deficiency; and (d) diminished splanchnic blood flow may contribute to some of the effects of somatostatin on splanchnic metabolism.

Free fatty acid metabolism of leg muscles during exercise in patients with obliterative iliac and femoral artery disease before and after reconstructive surgery.

The free fatty acid (FFA) uptake and oxidation and the carbohydrate substrate exchange of leg muscles were studied during exercise in 14 patients with occlusive disease of the iliac or femoral arteries before and 3-6 months after reconstructive vascular surgery and in 5 healthy subjects. (14)C-labeled oleic acid was infused continuously at rest and during exercise at work loads of 150-400 kg-m/min. The arterial concentration of FFA was similar both at rest and during exercise in patients and controls. The patients showed a smaller increase in the fractional turnover of FFA during exercise. Leg uptake and release of FFA in terms of micromoles per liter plasma did not differ significantly either at rest or during exercise between patients and controls. FFA oxidation could not be measured at rest but exercise data showed a lower fractional oxidation of FFA (P < 0.001) in the patient group (53+/-6%) compared with the controls (84+/-2%). For the entire material, fractional oxidation of FFA showed a significant negative regression on the lactate/pyruvate ratio in femoral venous blood. The ventilatory respiratory quotient (RQ) and the leg muscle exchange of glucose and lactate in the patients exceeded that of the controls. When six patients were studied after reconstructive surgery, fractional oxidation of FFA had risen from a preoperative value of 47+/-8 to 90+/-10%, other data for leg muscle FFA metabolism being unchanged. IT IS CONCLUDED: (a) that substrate catabolism by the leg muscles during exercise in these patients proceeds in excess of the simultaneous capacity to oxidize acetyl-CoA in the tricarboxylic acid cycle, and (b) oxidation of FFA by contracting muscle is related to the muscle cell redox state.

Substrate turnover during prolonged exercise in man. Splanchnic and leg metabolism of glucose, free fatty acids, and amino acids.

Arterial concentrations and substrate exchange across the leg and splanchnic vascular beds were determined for glucose, lactate, pyruvate, glycerol, individual acidic and neutral amino acids, and free fatty acids (FFA) in six subjects at rest and during 4 h of exercise at approximately 30% of maximal oxygen uptake. FFA turnover and regional exchange were evaluated using (14)C-labeled oleic acid. The arterial glucose concentration was constant for the first 40 min of exercise, but fell progressively thereafter to levels 30% below basal. The arterial insulin level decreased continuously, while the arterial glucagon concentration had risen fivefold after 4 h of exercise. Uptake of glucose and FFA by the legs was markedly augmented during exercise, the increase in FFA uptake being a consequence of augmented arterial levels rather than increased fractional extraction. As exercise was continued beyond 40 min, the relative contribution of FFA to total oxygen metabolism rose progressively to 62%. In contrast, the contribution from glucose fell from 40% to 30% between 90 and 240 min. Leg output of alanine increased as exercise progressed. Splanchnic glucose production, which rose 100% above basal levels and remained so throughout exercise, exceeded glucose uptake by the legs for the first 40 min but thereafter failed to keep pace with peripheral glucose utilization. Total estimated splanchnic glucose output was 75 g in 4 h, sufficient to deplete approximately 75% of liver glycogen stores. Splanchnic uptake of gluconeogenic precursors (lactate, pyruvate, glycerol, alanine) had increased 2- to 10-fold after 4 h of exercise, and was sufficient to account for 45% of glucose release at 4 h as compared to 20-25% at rest and at 40 min of exercise. In the case of alanine and lactate, the increase in precursor uptake was a consequence of a rise in splanchnic fractional extraction. It is concluded that during prolonged exercise at a low work intensity (a) blood glucose levels fall because hepatic glucose output fails to keep up with augmented glucose utilization by the exercising legs; (b) a large portion of hepatic glycogen stores is mobilized and an increasing fraction of the splanchnic glucose output is derived from gluconeogenesis; (c) blood-borne substrates in the form of glucose and FFA account for a major part of leg muscle metabolism, the relative contribution from FFA increasing progressively; and (d) augmented secretion of glucagon may play an important role in the metabolic adaptation to prolonged exercise by its stimulatory influence on hepatic glycogenolysis and gluconeogenesis.

Influence of arginine on splanchnic glucose metabolism in man.

To examine the mechanism of the arginine-induced rise in blood glucose concentration, splanchnic glucose output (SGO) and precursor uptake were studied during i.v. infusion of arginine (30 g/30 min) with and without somatostatin infusion (500 microgram/h, 90 min) in postabsorptive and in 60-h fasted healthy subjects. The hepatic venous catheter technique was employed. In the postabsorptive state, arginine infusion was accompanied by an eightfold and a fivefold increment, respectively, in the hepatic venous concentration of insulin and glucagon; SGO doubled and blood glucose increased by 30%. After cessation of arginine infusion, SGO and blood glucose returned to basal levels within 30 min. When both arginine and somatostatin were administered, glucagon rose threefold, whereas the insulin response was abolished. And while the rise in SGO during arginine infusion and its subsequent decline were uninfluenced by the simultaneous infusion of somatostatin, the rise in blood glucose was more pronounced and the glucose concentration remained elevated longer than in control studies without somatostatin. Splanchnic uptake of glucogenic precursors was uninfluenced by arginine infusion, with or without simultaneous somatostatin administration. In the 60-h fasted group, arginine infusion was accompanied by a minimal increase in insulin but a fivefold elevation of the glucagon level. Combined arginine and somatostatin infusion did not boost insulin significantly but the glucagon level rose threefold above the basal value. Basal SGO was 55% lower than in the postabsorptive state, and it rose in response to arginine administration (+50%) as well as during combined arginine and somatostatin infusion (+80%). No significant change in splanchnic uptake of glucogenic precursors was observed during arginine infusion with or without somatostatin administration. We conclude that (1) arginine infusion is accompanied by a rise in SGO and blood glucose due to arginine-induced stimulation of glucagon secretion, (2) the rise in SGO is caused primarily by glucagon-stimulated hepatic glycogenolysis, and (3) combined somatostatin and arginine administration is accompanied by a more marked rise in blood glucose due to hypoinsulinemia and reduced peripheral glucose utilization.

Aberrant tyrosine transport across the cell membrane in patients with schizophrenia.

BACKGROUND: There is evidence that patients with schizophrenia exhibit abnormalities, not only in the brain but also in peripheral organs. An abnormal cell membrane composition has been suggested to be a common denominator, supported by findings of alterations in membrane phospholipid levels. In a previous study, the transport of amino acids across the plasma membrane was investigated with fibroblasts from patients with schizophrenia and controls. An isolated decrease in the maximal transport capacity (V(max)) of tyrosine was observed in the cells from patients. In this context, tyrosine transport across the fibroblast membrane was investigated in patients with schizophrenia and healthy control subjects. METHODS: Skin fibroblasts were obtained from 36 patients with schizophrenia (15 first episode and 21 chronic) and 10 healthy controls. Tyrosine transport across the cell membrane was studied in cultivated fibroblasts. The V(max) and the affinity of the tyrosine binding sites (K(m)) were determined. RESULTS: Significantly lower V(max) (F(1,41) = 12.80; P =.001; effect size = 1.36) and K(m) (F(1,41) = 24.85; P<.001; effect size = 1.00) were observed in fibroblasts from the patients. The findings were present in both neuroleptic-naive patients with their first episode and patients with chronic schizophrenia. CONCLUSIONS: The lower V(max) and K(m) are compatible with a cell membrane disturbance and support the view of schizophrenia as a systemic disorder. The decreased V(max) and K(m) observed in cells from schizophrenic patients probably reflect a genetic trait, as the changes were transmitted through several cell generations of cultured fibroblast.

Metabolic control in 131 juvenile-onset diabetic patients as measured by HbA1c: relation to age, duration, C-peptide, insulin dose, and one or two insulin injections.

Glycosylated hemoglobin A (HbA1c), considered to reflect long-term metabolic control of diabetes, was analyzed in 131 patients, aged 2 5/12-19 6/12 yr, with juvenile-onset diabetes. Using stepwise multiple regression HbA1c, fasting blood glucose and plasma 3-hydroxybutyrate were analyzed as dependent variables versus independent variables such as age of the patients, duration of the disease, level of plasma immunoreactive C-peptide (IRCP), insulin dose, and number of insulin injections (one or two) per day. HbA1c was inversely related only to IRCP concentration. A low but significant, positive correlation was found between HbA1c and the duration of diabetes. Stepwise addition of the other independent variables did not further increase the fraction of explained variance. HbA1c was also correlated with a subjective rating score of the metabolic control performed by the treating physician. Fasting plasma glucose was significantly related to HbA1c but not to any of the independent variables. Fasting 3-hydroxybutyrate showed an inverse correlation to the age of the patient. The present study showed that in juvenile-onset diabetic patients, endogenous insulin secretion as reflected by IRCP was the factor best correlated with a low level of HbA1c. After the cessation of endogenous insulin secretion, there is a progressive deterioration of metabolic control and multiple injections of insulin rather than one or two per day may be needed to reach optimal control in the patients.

Hepatic glucose production and splanchnic glucose exchange in hyperthyroidism.

Hepatic glucose production (HGP) and net splanchnic glucose balance (NSGB) were simultaneously determined in the basal state in 8 hyperthyroid patients and 10 normal subjects using iv infusion of [3H]3-glucose and the hepatic venous catheter technique. Splanchnic glucose uptake (SGU) was calculated as the difference between the HGP and NSGB. SGU was also measured by determining the splanchnic extraction ratio of [3H]3-glucose across the splanchnic bed. In 5 hyperthyroid patients and 5 normal subjects a renal vein was also catheterized in the basal state. The influence of increased endogenous insulin secretion [stimulated by a low rate iv infusion of glucose (2 mg/kg . min)] on splanchnic and hepatic glucose exchange was also examined. Basal HGP (measured with [3H]3-glucose) was increased by 20% in the hyperthyroid patients [14.2 +/- 0.6 (SEM) mumol/kg . min] as compared to normal subjects (11.9 +/- 0.6, P less than 0.02). In marked contrast, NSGB output was slightly but not significantly decreased in the hyperthyroid group. SGU in the hyperthyroid patients, as determined with both techniques, was more than 2-fold higher than in the normal group (P less than 0.02-P less than 0.005). Splanchnic uptake of gluconeogenic precursors (lactate, pyruvate, glycerol) was increased by 20-120% in the patient group. During iv infusion of glucose, plasma insulin levels increased more in the hyperthyroid group (66% vs. 37%, P less than 0.05). Nevertheless, HGP and NSGB were less markedly suppressed in the patients as compared to the normal subjects (P less than 0.01), whereas the augmented SGU in the hyperthyroid patients reverted to normal. Splanchnic uptake of gluconeogenic precursors was unchanged in both groups. No net renal glucose production could be demonstrated in either group in the basal state. We conclude that in hyperthyroidism, increased HGP occurs in the face of an unchanged or slightly reduced rate of net glucose delivery to extrasplanchnic tissue. This discrepancy can be ascribed to augmented splanchnic uptake of glucose. These findings raise the possibility of futile cycling of glucose in the liver as a mechanism of increased oxygen consumption in hyperthyroidism. The data also demonstrate a diminished inhibitory effect of endogenous insulin on splanchnic glucose production, suggesting the presence of hepatic resistance to insulin in hyperthyroidism.

Genotyping is a valuable diagnostic complement to neonatal screening for congenital adrenal hyperplasia due to steroid 21-hydroxylase deficiency.

To evaluate genotyping as a diagnostic complement to neonatal screening for congenital adrenal hyperplasia, 91 children who had been diagnosed with this condition between 1986 and 1997 were analyzed for mutations in the steroid 21-hydroxylase gene. Screening levels of 17-hydroxyprogesterone were compared in patients representing different genotypes. Genotyping was performed using allele-specific PCR, the patients were divided into four groups according to the severity of their mutations, and screening results were compared between these groups as well as with 141 values representing false positive samples. The screening levels of 17-hydroxyprogesterone were significantly different in the five groups of samples. Values above 500 nmol/L were clearly associated with the most severe genotypes, whereas conclusions concerning disease severity could not be drawn from individual samples representing lower levels. For example, values around 150-200 nmol/L could be seen in children with all degrees of disease severity and could also constitute false positive samples. We conclude that genotyping is a valuable diagnostic tool and a good complement to neonatal screening, especially in confirming or discarding the diagnosis in cases with slightly elevated 17-hydroxyprogesterone levels. An additional benefit is that it provides information on disease severity, which reduces the risk of overtreatment of mildly affected children.

Three polymorphisms but no disease-causing mutations in the proximal part of the promoter of the phenylalanine hydroxylase gene.

The proximal promoter region of the human phenylalanine hydroxylase (PAH) gene was analyzed for the presence of mutations in 122 European phenylketonuria (PKU) and hyperphenylalaninemia patients having altogether 187 uncharacterized mutant PAH alleles. This promoter fragment, which contained the most 5' transcription start site and about 300 bp upstream, was sequenced directly from polymerase-chain-reaction-amplified genomic DNA. No disease-causing mutations but three neutral nucleotide substitutions were found. A -195 T-to-C transition was present on 1% of 441 normal and 0.3% of 653 mutant chromosomes. All chromosomes that carried this transition and to which a restriction fragment length polymorphism (RFLP) haplotype had been assigned were of haplotype 1. A -71 G-to-A change and a +7 C-to-T change were always observed together and were found on 1% of 425 normal and 4% of 681 mutant chromosomes. In addition, these two transitions were found in seven heterozygote samples where the phase could not be established due to incomplete family samples. In individuals where RFLP haplotypes were known and phase could be established, these linked substitutions were associated with RFLP haplotype 9. The relatively high frequency (10-20%) of these two polymorphisms on PKU chromosomes from Great Britain, Ireland and France may reflect a relative concentration of haplotype 9 alleles among PKU chromosomes from these countries compared to the rest of Europe. The absence of disease-causing mutations within a region of the PAH gene that possesses basal promoter activity suggests that transcriptional mutations are not likely causes of PKU in Caucasian populations.

The transport of tyrosine into the human brain as determined with L-[1-11C]tyrosine and PET.

An alteration of dopaminergic transmission in the brain has been proposed for schizophrenia. To explore this, the rate constant for the intransport of L-tyrosine across the blood-brain barrier in healthy controls and in patients with schizophrenia (DSM-III-R) was determined with PET and L-[1-11C] tyrosine as the tracer. Kinetics for tyrosine transport were determined according to a two-compartment model using radioactivity data of arterial blood and brain tissue sampled between 1 and 3.5 min after a bolus injection of L-[1-11C] tyrosine. Radioactivity was measured every second in the blood and in 10-sec intervals in the brain tissue. In the normal controls the brain intransport rate constant for tyrosine was 0.052 ml/g/min with an influx rate of 2.97 nmol/g/min. The patients had a similar intransport rate constant (0.045 ml/g/min) but a lower influx rate of tyrosine 1.95 nmol/g/min (p less than 0.05). The patients' tyrosine concentrations in the blood were lower. For data sampled between 5 and 25 min, the net accumulation rate of tyrosine into the brain was 0.015 ml/g/min in the controls which did not differ to the patients' rate. However, the net utilization of tyrosine was lower in the patients (0.672 nmol/g/min) than in the controls (0.883 nmol/g/min) despite similar tissue concentrations of tyrosine.

Improved peripheral nerve conduction, EEG and verbal IQ after bone marrow transplantation for adult metachromatic leukodystrophy.

A 28-year-old woman with a 4 year history of slowly progressing 'frontal dementia' was diagnosed as having adult metachromatic leukodystrophy and was followed for 4 years after bone marrow transplantation (BMT). MRI, neurophysiological tests (EEG, ENeG, VEP, SEP and BAEP) and neuropsychological assessment were performed before, and repeatedly after BMT. MRI showed symmetrical white matter lesions in the frontal and parieto-occipital lobes and in the corpus callosum. EEG showed frontal and temporal slow wave abnormalities and nerve conduction was slow. Neuropsychological tests showed cognitive impairment in executive functions, decline in visuospatial-constructive and spatial memory tasks and disorganized thinking. IQ was low (52), with slightly better values for verbal IQ than for performance IQ. After BMT, the patient was followed for 4 years. Clear improvements were seen in EEG, in peripheral nerve conduction and in neuropsychological tests (especially in verbal IQ). MRI findings were unchanged. We believe that the improvement in our patient resulted from the bone marrow transplantation.

Clinical and biochemical effects of citalopram, a selective 5-HT reuptake inhibitor--a dose-response study in depressed patients.

Citalopram is a bicyclic phtalane derivative. In animal experiments, citalopram has been demonstrated to possess a potent and highly selective inhibitory effect on serotonin reuptake. Several studies in man have indicated that citalopram given in daily doses of 40-60 mg has antidepressant properties and few side effects. The present double-blind study investigated the effects of three doses of citalopram (5 mg, 25 mg, and 50 mg) on depressive symptoms and various biochemical variables in 26 depressive patients. A significant reduction of the clinical ratings of depressive symptoms occurred at all dose levels. In endogenously depressed patients, a dose of 25 or 50 mg daily seemed to have the most pronounced antidepressive effect. The side effects were few and not related to dose level. A highly significant decrease in 5-HIAA in the CSF was found. MO-PEG in the CSF was also significantly decreased, while HVA in the CSF was increased. In addition, a significant decrease in the plasma concentrations of valine, leucine, tyrosine, and histidine was found. None of the biochemical effects was dose-dependent. The complex pattern of biochemical effects indicate that the amelioration of depressive symptoms might be related to effects of citalopram on central monoaminergic mechanisms and peripheral amino acid concentrations.

Tyrosine transport in schizophrenia.

Tyrosine transport was examined in cultured skin fibroblasts from patients with schizophrenia (DSM-III-R) and normal subjects. The transport capacity (Vmax) was lower in the patients. The results confirm previous findings of decreased tyrosine transport in schizophrenia. In cells incubated with psychotropic drugs at different concentrations, tyrosine transport was not differentially influenced across patients and normal subjects. Dopaminergic and beta-adrenergic receptor mechanisms did not seem to influence tyrosine uptake. There seems to be a primary disturbance of tyrosine transport in schizophrenia which indicates a generalized cell membrane dysfunction.

Tyrosine transport is regulated differently in patients with schizophrenia.

Previous PET studies of tyrosine transport have suggested that the transport of tyrosine from blood to brain compartment is not dependent on its plasma concentration in patients with schizophrenia. In order to examine this relationship, the transport constant (K1) of tyrosine was determined in five patients with schizophrenia and five normals. L-[1-11C]Tyrosine was injected i.v. and arterial blood samples were taken during PET scanning. The tyrosine transport was assessed during baseline conditions and after oral administration of L-tyrosine at a dose (175 mg/kg) that significantly elevated the plasma levels. K1 was determined from tracer kinetic modelling. The transport rate dropped in the normals after tyrosine loading, which is consistent with the prevailing notion that the brain transport system for neutral amino acids works close to saturation, whereas it was virtually unchanged in the schizophrenics. The results demonstrated that tyrosine transport was not saturated in the patients with schizophrenia and thus could lead to elevated brain concentrations of tyrosine.

Turnover of plasma free stearic and oleic acids in resting and exercising human subjects.

Turnover rates and metabolism in the legs and the splanchnic region of free stearic and oleic acid have been studied in five healthy male volunteers at rest and during bicycle exercise. A continuous infusion of 14C-labeled stearic acid and tritiated oleic acid was given intravenously. At rest, the fractional turnover was the same for the two acids; the fractional leg uptakes were also similar, while fractional uptake in the splanchnic region was 80% higher for oleic than for stearic acid. The response to exercise differed between the two acids: the arterial concentration of stearic acid fell, its fractional turnover and fractional leg uptake became higher than for oleic acid, and its fractional uptake in the splanchnic region increased, while that of oleic acid remained unchanged. It is concluded (1) that stearic acid turnover in the postabsorptive state is similar to that of the main part of the FFA fraction and (2) that the decrease in stearic acid concentration during exercise can be explained by an increased removal in excess of that for other FFA.