Comparison of α-methylphenylalanine and <i>p</i>-chlorophenylalanine as inducers of chronic hyperphenylalaninaemia in developing rats

Delvalle, J A; Dienel, Gerald A.; Greengard, Olga

doi:10.1042/bj1700449b

Cited by 56 publications

(27 citation statements)

References 34 publications

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“…Procedures were similar to those previously described [12, 18, 19] and used either αMePhe or pCPhe to inhibit liver phenylalanine hydroxylase along with large doses of Phe in the presence or absence of enzyme inhibition. Stock solutions (all were adjusted to pH 7.2) for injection of αMePhe (70 μmol/mL), αMePhe (70 μmol/mL) plus Phe (152 μmol/mL), or Phe (152 μmol/mL) were prepared in 0.9% NaCl (w/v) with warming.…”

Section: Methodsmentioning

confidence: 99%

“…To better understand the biochemical, developmental, physiological, and behavioral changes associated with hyperphenylalanemia, a number of animal models have been developed by treatments with their onset at various postnatal ages for different durations using specific metabolites of Phe given alone (e.g., phenylacetate [9, 10]), or different doses of Phe either alone [11] or in combination with an inhibitor of Phe hydroxylase (p-chlorophenylalanine (pCPhe) or α-methylphenylalanine (αMePhe) [12]). A PKU mouse model (BTBR background-Pah enu2 ) was subsequently developed by producing germline mutagenesis with ethylnitrosourea (enu) and identification of Phe hydroxylase deficiency by Phe clearance screening [13].…”

Section: Introductionmentioning

confidence: 99%

“…A PKU mouse model (BTBR background-Pah enu2 ) was subsequently developed by producing germline mutagenesis with ethylnitrosourea (enu) and identification of Phe hydroxylase deficiency by Phe clearance screening [13]. These models reproduce many of the biochemical, developmental, and behavioral characteristics of PKU patients, but the use of enzyme inhibitors involves side effects of the drugs and differential toxicity, with pCPhe having greater deleterious effects than αMePhe or high doses of Phe alone, and the residual Phe hydroxylase activity in the rat models causes high levels of tyrosine (e.g., [12, 14–16]). The Phe hydroxylase-deficient mouse model is generally considered advantageous due to lack of inhibitor side effects, but lack of sufficient demand led Jackson Laboratory to maintain the mutant lines by cryopreservation, increasing the cost and time to obtain the animals unless they are available from active PKU researchers [17].…”

Section: Introductionmentioning

confidence: 99%

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Biochemical, Metabolic, and Behavioral Characteristics of Immature Chronic Hyperphenylalanemic Rats

Dienel

Cruz

2015

Neurochem Res

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Phenylketonuria and hyperphenylalanemia are inborn errors in metabolism of phenylalanine arising from defects in steps to convert phenylalanine to tyrosine. Phe accumulation causes severe mental retardation that can be prevented by timely identification of affected individuals and their placement on a Phe-restricted diet. In spite of many studies in patients and animal models, the basis for acquisition of mental retardation during the critical period of brain development is not adequately understood. All animal models for human disease have advantages and limitations, and characteristics common to different models are most likely to correspond to the disorder. This study established similar levels of Phe exposure in developing rats between 3 and 16 days of age using three models to produce chronic hyperphenylalanemia, and identified changes in brain amino acid levels common to all models that persist for ~16h of each day. In a representative model, local rates of glucose utilization (CMRglc) were determined at 25–27 days of age, and only selective changes that appeared to depend on Phe exposure were observed. CMRglc was reduced in frontal cortex and thalamus and increased in hippocampus and globus pallidus. Behavioral testing to evaluate neuromuscular competence revealed poor performance in chronically-hyperphenylalanemic rats that persisted for at least three weeks after cessation of Phe injections and did not occur with mild or acute hyperphenylalanemia. Thus, the abnormal amino acid environment, including hyperglycinemia, in developing rat brain is associated with selective regional changes in glucose utilization and behavioral abnormalities that are not readily reversed after they are acquired.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Biochemical, Metabolic, and Behavioral Characteristics of Immature Chronic Hyperphenylalanemic Rats

Dienel

Cruz

2015

Neurochem Res

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“…Although rhemically induced animal modeling systems for HPA have been developed (5,6,17), there is always a degree of uncertainty inherent in their use due to the potential presence of unknown secondary effects induced by the chemical agents used (7).…”

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confidence: 99%

Hyperphenylalaninemia in the hph-1 Mouse Mutant

McDonald

Bode

1988

Pediatr Res

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ABSTRACT. A mutation, resulting in a deficiency of liver GTP-cyclohydrolase activity, has been induced in the laboratory mouse. Mice homozygous for this mutation exhibit hyperphenylalaninemia under the following conditions: 1 ) early in life and 2) throughout life when exposed to phenylalanine. A phenylalanine loading regimen was used to discriminate between mutant and wild type mice on the basis of the resultant phenylalanine and tyrosine serum levels. Subjecting mice to this regimen reveals several distinguishing characteristics. Mutant mice exhibit approximately 2-fold higher peak phenylalanine levels than wild-type mice. In wild-type mice the hyperphenylalaninemic state is transient and rapidly abates while in mutant mice it is persistent and remains for a prolonged period. Mutant mice exhibit normal serum tyrosine levels after a loading challenge, while wild-type mice experience an increase in tyrosine levels. The loading regimen was also used to gauge the response of mutant hyperphenylalaninemic mice to exposure to chemical compounds required for normal phenylalanine catabolism (i.e. pteridine cofactors of the phenylalanine hydroxylase reaction). Mutant mice exposed to native enzyme cofactor or cofactor precursors exhibit a sharp decline in serum phenylalanine levels relative to their uninjected counterparts coupled with a tyrosine increase. By contrast, mutant mice exposed to nonprecursor compounds that are structurally related to the native cofactor, experience no diminution of serum phenylalanine levels. (Pediatr Res 23: 63-67, 1988)

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“…In the experiments of figure 1, this treatment was given to every rat once (on the indicated day of age) and most of them received no other treatment. A subgroup was also given a daily injection of a-Mcphe plus Phe (replaced by dietary sup plementation at weaning) so as to impose chronic hyperphenylalaninemia from the 3rd day on [ 16], However, this condition did not alter the developmental change in the extent of rise of cerebral Phe content at blood levels elevated to 4.000 nmol/ml.…”

Section: Resultsmentioning

confidence: 99%

Phenylalanine Uptake in Neonatal and Infant Rat Brain

McChesney

Habermann²,

Greengard³

1988

Neonatology

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At the same severe elevations in blood phenylalaline (Phe) levels maintained for 4 h, much higher cerebral Phe concentrations were found in 4-day-old than in 16- or 70-day-old rats. In order to compare this developmental change with ¹⁴C-Phe influx mediated by the L transport system, the rapid intracarotid injection method was adapted for use in neonatal rats. The brain uptake index (BUI) thus determined for the first time through the suckling period was significantly higher on the 4th day of age than on the 7th or 24th day, while no significant change occurred during subsequent life. This early period of change in influx across the blood-brain barrier overlapped with the age period of decrease of the hyperphenylalaninemia-associated accumulation of Phe in the brain. The results indicate that by the time when intermittent feeding begins, the brain has developed a considerable ability (a) to protect itself against physiological (e.g. postprandial) fluctuations in circulating Phe levels, and (b) to restrict the cerebral accumulation of Phe from pathologically elevated blood concentrations such as those in phenylketonuria.

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Comparison of α-methylphenylalanine and p-chlorophenylalanine as inducers of chronic hyperphenylalaninaemia in developing rats

Cited by 56 publications

References 34 publications

Biochemical, Metabolic, and Behavioral Characteristics of Immature Chronic Hyperphenylalanemic Rats

Biochemical, Metabolic, and Behavioral Characteristics of Immature Chronic Hyperphenylalanemic Rats

Hyperphenylalaninemia in the hph-1 Mouse Mutant

Phenylalanine Uptake in Neonatal and Infant Rat Brain

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