Kynurenine metabolism in rats: some hormonal factors affecting enzyme activities.

Six male subjects (19–23 years old) underwent a 7-day control period with respect to diet, temperature (22C), and sleep (7.5 hrs), followed by a 2-day exposure to 15C and a 2-day recovery period (22C). Urine collections were made every 8 hours commencing at 2300 hours; MHPG and VMA were assayed using gas-liquid chromatography. During the control period a diurnal rhythmicity was demonstrated for MHPG and VMA with maxima at 0700–1500 hours. The mean excretory rates for MHPG and VMA were 0.71 ± 0.04 μg and 2.6 ± 0.2 μg per milligram creatinine (± S.E.), respectively. Cold exposure abolished the rhythms for MHPG and VMA and caused an 18% increase in MHPG excretion. In contrast, VMA excretion was not altered. Significant correlations were obtained with MHPG excretion and both urinary cortisol and rectal temperature. The data suggest that MHPG excretion may be indicative of changes in norephinephrine metabolism in the central nervous system, although alterations in peripheral degradative pathways cannot be ruled out. Careful interpretation of changes in MHPG excretion in clinical studies is emphasized due to the relative ease of altering MHPG metabolism.     

Effect of MPTP-induced parkinsonism in monkeys on the urinary excretion of HVA and MHPG during debrisoquin administration

During debrisoquin administration to three monkeys there were significant reductions in excretion rates of HVA, the major dopamine metabolite, and MHPG, the major norepinephrine metabolite. Excretion rates of HVA were highly correlated to those of MHPG. The regression line relating HVA and MHPG excretion suggests that a portion of HVA (about 25%) is derived from a source independent of norepinephrine metabolites. There was a striking reduction of this portion of HVA excretion after MPTP-induced destruction of dopaminergic nigrostriatal neurons. These results support the view that the rate of HVA formation in brain dopaminergic neurons can be estimated from the relationship of urinary excretion rates of HVA and MHPG before and during debrisoquin treatment.     

Urinary excretion of catecholamines in the night monkey (Aotus trivirgatus) (Primates, Cebidae)

A seasonal variation in the urinary catecholamines output has been demonstrated in two simians kept under constant ambient conditions : the nocturnal Aotus and the diurnal Sa?miri sciureus. In Aotus, catecholamines output (NA + A), in spring, is higher than in other Primates including man and even more so in winter. Cold exposure increases the NA + A excretion in Aotus as it does in squirrel monkey and rat but the A output is particularly prominent in Sa?miri. Fasting does not alter significantly the catecholamines excretion. Associated fasting and cold exposure do not modify the adrenosympathetic response observed in Aotus in cold conditions alone, but depresses the sympathetic activity and greatly enhance the adrenomedullary excretion in squirrel monkey, as it is the case in rat. Associated fasting and cold represents a highly stressful situation for squirrel monkey but not for night monkey. Catecholamines metabolites (MN, NMN, DOPAC, HVA, VMA and MHPG) are found in urine of both species, DOPAC and VMA being predominant in Aotus but DOPAC and MHPG in Sa?miri. The proportions of conjugated forms vary according to the metabolite : DOPAC and VMA are mainly under free form but NMN, MN and MHPG are mostly conjugated in both species. The daily output of pooled adrenergic metabolites (expressed as ng/mg creatinine) is higher in Aotus than in Sa?miri and man. Both monkey species display a high adrenosympathetic activity which does not correlate with their resting metabolic rate.     

The contribution of CNS MHPG to plasma MHPG in the rat

Two different experimental approaches were used to determine the central nervous system (CNS) contribution to plasma total 3-methoxy-4-hydroxyphenylglycol (MHPG) levels in the rat. One experiment, using intracisternal injection of 6-hydroxydopamine (6-OHDA), depleted total forebrain norepinephrine (NE) and MHPG to 26 and 34% of control values, respectively. In spite of the substantial reduction in CNS MHPG, plasma MHPG was not significantly different from control values. The second experiment used clonidine and debrisoquine to differentially impair central and peripheral NE metabolism. The results of this experiment confirm those of the 6-OHDA experiment in suggesting that the CNS contribution to plasma MHPG in the rat is negligeable.     

Suppression of norepinephrine secretion by dopamine in children with neuroblastoma: evidence for precursor inhibition in catecholamine pathway

To elucidate catecholamine (CA) secretory dynamics in neuroblastoma, urinary excretion of CAs and their metabolites was serially measured in 6 patients aged 3 months to 3 years before and during treatment. After tumor extirpation, increased urinary CAs were promptly normalized; the reduction reflected the amount of CA production from the tumor. Urinary dopamine (DA) showed the most prominent reduction, whereas DA content in the tumor was very small, indicating that the DA produced was immediately released from the tumor and metabolized in extra-tumor tissues. In contrast, patients receiving chemotherapy continued to excrete excess DA and homovanillic acid (HVA), which were increased further at recidivation. One patient showed an inverse correlation between DA and norepinephrine (NE) excretion; a decrease in DA was associated with an increase in NE and plasma DA-beta-hydroxylase (DBH) activity. A similar inverse correlation was also noted between NE and vanillylmandelic acid (VMA) or 3-methoxy-4-hydroxyphenylglycol (MHPG) excretion, while HVA and dihydroxyphenylacetic acid (DOPAC) were positively correlated with DA excretion. Urinary HVA and VMA were lineally correlated but in a patient excreting an enormous amount of DA, urinary VMA was markedly suppressed in terms of HVA excretion. Excessive DA induced an increase in renal water output but did not enhance Na and K excretion. These results indicate that endogenous DA overload in neuroblastoma inhibits NE production by suppressing DBH activity as well as by forming VMA and MHPG. This precursor regulation appears to be the characteristic of the CA metabolic pathway.     

Diurnal rhythm of 3-methoxy-4-hydroxyphenylglycol (MHPG): relationship between plasma and urinary levels

Plasma and urinary levels of MHPG were determined in six normal volunteers. Samples were obtained at 3-hour intervals for plasma and at 12-hour intervals for urine. Acrophase, amplitude and period were determined for plasma MHPG levels. A sinusoidal pattern was obtained for diurnal plasma MHPG with a peak at 15:00 hrs. +/- 46 min. Urinary MHPG, corrected for creatinine levels, correlated with both 9 AM plasma MHPG and with baseline plasma MHPG. Furthermore, the relationship between plasma and urinary MHPG was linear when the rhythm of urinary levels was assumed to lag 6.2 hours behind the plasma rhythm. It was concluded that free MHPG is evenly distributed in the total body space and that conjugated MHPG is largely restricted to the blood.     

A new approach to biochemical evaluation of brain dopamine metabolism

1. Dopaminergic neurotransmission in brain is receiving increased attention because of its known involvement in Parkinson's disease and new methods for the treatment of this disorder and because of hypotheses relating several psychiatric disorders to abnormalities in brain dopaminergic systems. 2. Chemical assessment of brain dopamine metabolism has been attempted by measuring levels of its major metabolite, homovanillic acid (HVA), in cerebrospinal fluid, plasma, or urine. Because HVA is derived in part from dopamine formed in noradrenergic neurons, plasma levels and urinary excretion rates of HVA do not adequately reflect solely metabolism of brain dopamine. 3. Using debrisoquin, the peripheral contributions of HVA to plasma or urinary HVA can be diminished, but the extent of residual HVA formation in noradrenergic neurons is unknown. By measuring the levels of methoxy-hydroxyphenylglycol (MHPG) in plasma or of urinary norepinephrine metabolites (total MHPG in monkeys; the sum of total MHPG and vanillyl mandelic acid (VMA) in humans) along with HVA, it is possible to estimate the degree of impairment by debrisoquin of HVA formation from noradrenergic neuronal dopamine and thereby better assess brain dopamine metabolism. 4. This method was applied to a monkey before and after destruction of the nigrostriatal pathway by the administration of MPTP.     

Cerebrospinal fluid,plasma, and urinary MHPG in children

Cerebrospinal fluid (CSF) free MHPG levels for six autistic and four medicated Tourette Syndrome (TS) patients are in the usual adult range, but levels are elevated in two recently medicated TS patients. Plasma free MHPG levels in unmedicated autistic and TS patients are similar to those in normal boys, but are increased in two of seven medicated TS patients. There is a strong association between plasma free MHPG and urinary total MHPG levels in normal boys. Age and total urinary MHPG are positively correlated in autistic children. MHPG appears to be a useful index of noradrenergic function in childhood neuropsychiatric disorders.     

Catecholamines Increase in the Urine of Non‐Segmental Vitiligo Especially During Its Active Phase

Neural factors appear to play a major role in the pathogenesis of vitiligo. To investigate the possible correlation between vitiligo and peripheral monoaminergic system activity, we used high‐pressure liquid chromatography and electrochemical detector methods to evaluate the basal urine excretion values of catecholamines [norepinephrine (NE), epinephrine and dopamine (DA)], their relative metabolites [3‐methoxy‐4‐hydroxyphenylglycol (MHPG), normetanephrine (NMN), metanephrine (MN), vanilmandelic acid (VMA) and homovanillic acid], as well as 5‐hydroxyindoleacetic acid (5‐HIAA), in 35 healthy subjects and in 70 patients, suffering from non‐segmental vitiligo at different stages of the disease. Levels of NE, DA, NMN, MN, MHPG, VMA and 5‐HIAA were found to be significantly higher in patients than in controls. The patients with progressive vitiligo (n = 56) presented increased urinary excretion values for all parameters (in particular, NE levels) than other patients. Interestingly, in patients at its more recent vitiligo onset (<1 yr), NE values were different to those of subjects affected from 1 to 5 yr and from 6 to 10 yr. This result was confirmed by the significant negative relationship detected between NE excretion values and disease duration. In both vitiligo and control groups, significant correlations were found between monoamines as well as between these monoamines and their metabolites. The increase in catecholamine turnover, mainly occurring at the onset of the disease, is probably due to the stress associated with the appearance of lesions. Moreover, considering that these compounds readily produce toxic free‐radicals and that vitiliginous subjects have a defective free radical defence mechanism, they may also contribute to the disappearance of melanocytes in the early phases of vitiligo.     

Catecholamines increase in the urine of non-segmental vitiligo especially during its active phase

Neural factors appear to play a major role in the pathogenesis of vitiligo. To investigate the possible correlation between vitiligo and peripheral monoaminergic system activity, we used high-pressure liquid chromatography and electrochemical detector methods to evaluate the basal urine excretion values of catecholamines [norepinephrine (NE), epinephrine and dopamine (DA)], their relative metabolites [3-methoxy-4-hydroxyphenylglycol (MHPG), normetanephrine (NMN), metanephrine (MN), vanilmandelic acid (VMA) and homovanillic acid], as well as 5-hydroxyindoleacetic acid (5-HIAA), in 35 healthy subjects and in 70 patients, suffering from non-segmental vitiligo at different stages of the disease. Levels of NE, DA, NMN, MN, MHPG, VMA and 5-HIAA were found to be significantly higher in patients than in controls. The patients with progressive vitiligo (n = 56) presented increased urinary excretion values for all parameters (in particular, NE levels) than other patients. Interestingly, in patients at its more recent vitiligo onset (<1 yr), NE values were different to those of subjects affected from 1 to 5 yr and from 6 to 10 yr. This result was confirmed by the significant negative relationship detected between NE excretion values and disease duration. In both vitiligo and control groups, significant correlations were found between monoamines as well as between these monoamines and their metabolites. The increase in catecholamine turnover, mainly occurring at the onset of the disease, is probably due to the stress associated with the appearance of lesions. Moreover, considering that these compounds readily produce toxic free-radicals and that vitiliginous subjects have a defective free radical defence mechanism, they may also contribute to the disappearance of melanocytes in the early phases of vitiligo.     

Free and conjugated catecholamines and metabolites in cat urine after hypoxia

Catecholamine and metabolite excretion was studied in the cat after 6 h of 7.5% O2 hypoxia. Norepinephrine (NE) release from sympathetic nervous endings was strongly activated, whereas epinephrine (E) excretion was only slightly increased. A noteworthy result was the increase of dopamine (DA) and its metabolites [3-methoxytyramine (MT); 3,4-dihydroxyphenylacetic acid (DOPAC)] in urine samples. This increased release does not seem to originate from the central nervous system, but rather from peripheral dopaminergic structures; available knowledge on peripheral DA suggests that the hypoxia-induced DA release might be partly related to chemosensory or renal function. Indeed, in addition to enhanced DA and NE excretion, we observed an increase in sodium excretion that correlated with both DA and NE. Analysis of free and conjugated urinary metabolites showed that only free NE and both free and conjugated normetanephrine were increased in urine after hypoxic stress. Among DA metabolites, conjugated DOPAC was the main DA metabolite in the basal state and after hypoxia. Both the free and the conjugated forms of DA, MT, and DOPAC were increased by hypoxia.     

Adrenaline in various organs of the rat: its origin, location and diurnal fluctuation

In order to examine the origin and location of adrenaline in peripheral organs of mammals, adrenaline and noradrenaline were measured in several organs of the rat after adrenalectomy, guanethidine treatment and imipramine injection. One week after bilateral adrenalectomy, adrenaline disappeared almost completely from the heart, spleen and submaxillary gland. Chronic administration of guanethidine caused decreases in both noradrenaline and adrenaline in the peripheral organs. Injection of imipramine induced a reduction of adrenaline concentration in the spleen and submaxillary gland. It is considered that adrenaline in the peripheral organs of mammals is mostly derived from the adrenal gland and that circulating adrenaline is taken up by sympathetic nerve endings in the organs. The adrenaline content of the peripheral organs increased after electric foot-shock and changed according to the time of day. The peak of the circadian rhythm appeared about 6 hours after the peak of the urinary adrenaline rhythm. These findings suggest that adrenaline in body organs plays some role in the responses of the sympathetic nervous system to stressful conditions or even to daily activities.     

Effects of pressure on the skin exerted by clothing on responses of urinary catecholamines and cortisol,heart rate and nocturnal urinary melatonin in humans

The study investigated how the pressure exerted on the skin by clothing worn while working in the daytime affected the urinary excretion of adrenaline, noradrenaline and cortisol, heart rate, and also melatonin secretion at night. Nine young women (experiment I) and seven young women (experiment II) participated. Participants wore either a 100% cotton jacket (tight clothes, TC) or a 100% cotton T-shirt (loose clothes, LC). Loose-fitting, 100% cotton tank tops and panties were worn as underwear in both the TC and the LC groups. The main results can be summarized as follows: (1) urinary excretion of adrenaline, noradrenaline and cortisol was facilitated, and the amounts of urinary excretion were significantly higher when TC were worn. Heart rate was significantly higher in the TC group; (2) nocturnal urinary melatonin excretion was significantly greater in the TC group. These results are discussed in terms of an enhancement of diurnal sympathetic nervous system activity caused by pressure on the skin produced by tight clothing.     

DISTRIBUTION AND TURNOVER RATE OF VANILLYL-MANDELIC ACID AND 3-METHOXY- 4- HYDROXYPHENYLGLYCOL IN RAT BRAIN

Abstract— Vanillylmandelic acid (VMA) and 3-methoxy-4- hydroxyphenylglycol (MHPG) were measured in rat brain by a mass fragmentographic procedure. The concentration of VMA and MHPG in whole brain is 11 and 533 pmol/g, respectively. Both compounds were found in all areas of brain studied with VMA, as a percentage of both metabolites, ranging between about 1 and 8%. From the decline of the compounds after pargyline. 75 mg/kg i.p., we calculated that the rate of formation of VMA is 15 and for MHPG 202 pmol/g per h. The fractional rate of elimination of VMA and MHPG is 1.4 and 0.38 h⁻¹, respectively. The rapid rate of loss of VMA suggests that it is transported from brain. However, we were unable to block the elimination of VMA from brain by treatment with probenecid. In contrast, the elimination of MHPG could be blocked by treatment with probenecid. Our study adds support to the notion that MHPG is a major whereas VMA is a minor product of norepinephrine metabolism in brain.     

A radiotracer method for the measurement of central nervous system catecholamines in vivo.

A new strategy for measurement of brain catecholamines was tested in an animal model. [3H]Norepinephrine was infused intravenously in rabbits to label the peripheral norepinephrine pools. The specific activity of urinary 3-methoxy-4-hydroxymandelic acid was consistently higher than that for 3-methoxy-4-hydroxyphenyglycol (MHPG). Central sympathectomy with 6-hydroxydopamine abolished this difference. Using the formula we propose, it is estimated that 30-50% of urinary MHPG originates from the central nervous system.     

The significance of duration of salt loading on cardiovascular response and urinary excretion of catecholamine in rats

To analyze the conflicting data on the relationship between sodium intake and catecholamine release, the effect of the duration of high sodium loading on cardiovascular response and catecholamine release was examined in conscious rats. Urinary excretions of norepinephrine (NE), and dopamine (DA) were measured frequently over a 4 week period. Male Wistar rats at 4 weeks of age were given a diet containing either basal (0.3%) or high (3.1%) sodium content. Systolic blood pressure was measured weekly by the tail cuff method. Twenty-four hour urine collections were made for analysis of catecholamines in metabolic cages every other day during the initial 2 weeks and once a week in the following 2 weeks of salt loading. High sodium intake resulted in a rise in blood pressure and a reduction in heart rate. Bradycardia was significant during the initial 2 weeks and not significant during the following 2 weeks after the initiation of salt loading. Urinary excretion of NE did not change during the initial 2 weeks of salt loading but increased significantly following the 2 week period after salt loading. Urinary excretion of DA increased diphasically, showing the first peak at 1 week after salt loading and the second peak at 4 weeks after the initiation of salt loading. These results suggest that the heart rate and urinary excretion of catecholamine are influenced by the duration of salt loading. When we estimate the effect of salt loading on cardiovascular response and urinary excretion of catecholamine, we should draw attention to the importance of the duration of salt loading, because this duration of time further elicites delayed response in the sympathetic nervous system.     

Blood pressure lability in the sympathectomized rat

Intra-aortic blood pressure (BP) was measured in conscious rats after early chronic destruction of the peripheral sympathetic nervous system (SNS) with guanethidine. In sympathectomized rats, the mean level of BP was not different from that of control rats but its variability was markedly increased. These results indicate that functional integrity of the SNS is of primary importance for the short-term control of BP but is not essential for its long-term maintenance.     

Diurnal variations of heart rate,urine flow and catecholamine excretion in subjects wearing clothing that provides different thermal insulation

This study investigated the effects of clothing providing different Clo values upon the circadian rhythm of sympathetic nervous activity, as inferred from urinary catecholamine excretion and heart rate, in a thermoneutral environment. Seven health female subjects were studied for 37.5 h, from 21:00 h on the first day to 10:30 h on the third day, in an isolated climatic chamber controlled at 23.8?±?0.2 °C and 60?±?5% RH. Light intensity was 500 lux from 06:30 to 19:30 h, 100 lux from 19:30 to 22:30 h and 0 lux from 22:30 to 06:30 h. Subjects were tested while wearing two different types of clothing: Type L, offering 1.048 Clo of thermal insulation and with the subjects’ extremities covered; and Type H, 0.744 Clo of thermal insulation and the subjects’ extremities exposed. Urine samples were collected every 4 h, their volumes were measured and they were later assayed for their contents of adrenaline and noradrenaline; the mean heart rate for each of these 4-h periods was also calculated. The daily profiles of the variables were assessed by ANOVA, which indicated that the amplitudes and phases of the daily rhythms differed between the clothing types. This result was examined in more detail by assessing the profiles by single and group cosinor analysis (period = 24 h). All four physiological variables showed clear and statistically significant group cosinor rhythms with both types of clothing. The mean amplitudes of urine flow, the excretion rate of urinary adrenaline and heart rate were greater when wearing Type H rather than Type L clothing (p = 0.01 for urine flow and heart rate; p = 0.072 for rate of excretion of adrenaline). Also, the acrophase of the rate of urinary adrenaline excretion was earlier in all subjects wearing Type H rather than Type L clothing (p = 0.048), and the acrophases of urine flow and urinary noradrenaline excretion rate were earlier in six and five of the subjects, respectively. These results show that clothing which is worn in an environment of moderate temperature (23.8 °C) and which offers a lower Clo value (especially if the distal extremities are exposed) might induce an increase in amplitude and/or an advance of acrophase in circadian rhythms of urine flow, excretion of urinary catecholamines and heart rate. It is suggested that these rhythmic changes, which imply changes in the daily profile of sympathetic nervous system activity, might be important when daily thermoregulation and comfort in response to the type of clothing being worn in daily life are considered.     

Regulation of urinary thromboxane B2 in man: Influence of urinary flow rate and tubular transport

Thromboxane B₂ (TxB) is excreted in human urine, but the mechanism of renal excretion and the quantitative relationship of urinary TxB to the active parent compound, thromboxane A₂, of renal or extrarenal origin is not established. To determine the effects of vasoactive hormones, uricosuric agents and urinary flow rate on TxB excretion, urinary TxB was measured by radioimmunoassay and mass spectrometry, and renal metabolism of blood TxB was determined by radiochromatography of urine after i.v. [³H]-TxB infusions. Basal TxB was 6.7 ± 1.1 ng/h during an oral water load, and TxB fell with s.q. antidiuretic hormone (to 3.4 ± 0.4 ng/h, P<0.01) and with fluid restriction (to 2.6 ± 0.5 ng/hr, P=0.001) in parallel with urinary volume. Urinary excretion of unmetabolized [³H]-TxB also fell (by 56%) with fluid restriction, implicating altered metabolism rather than synthesis as the mechanism of the urinary flow effect. Angiotensin II infusions slightly reduced both TxB and urine volume, consistent with a flow effect. In contrast, probenecid did not alter urine volume, but increased urinary uric acid (by 244%), TxB (from 5.6 ± 0.9 to 11.1 ± 2.9 ng/h) and urinary excretion of blood [³H]-TxB (by 243%) by similar amounts (all P<0.05), suggesting that TxB is actively reabsorbed in the proximal tubule, similarly to uric acid. Thus, urinary excretion of TxB of renal and extrarenal origin is regulated by proximal and distal tubule factors.     

Effects of alfa-receptor and adrenergic neuron blockade on indomethacin-induced changes of renal haemodynamics

The effect of prostaglandin synthesis inhibitor indomethacin was studied on renal haemodynamics by radioactive microspheres in untreated control dogs and in animals treated by the alfa-adrenergic receptor blocking agent phentolamine or by the adrenergic neuron blocking agent guanethidine. RBF was reduced by indomethacin. The reduction of blood flow was more pronounced in the inner cortical zones, which resulted in a blood flow redistribution towards the superficial cortical regions. Urine flow, osmotic concentration and electrolyte excretion did not change significantly. Pretreatment by phentolamine or by guanethidine did not influence the effect of indomethacin on renal haemodynamics or renal function. These data suggest that the sympathetic nervous system is not involved in the renal effects of indomethacin.