The effects of chronic hyperphenylalaninaemia on mouse brain protein synthesis can be prevented by other amino acids

Binek-Singer, Patricia; Johnson, Terry C.

doi:10.1042/bj2060407

Cited by 36 publications

(16 citation statements)

References 23 publications

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“…The L- [1][2][3][4][5][6][7][8][9][10][11][12][13][14] C]leucine method is based on a compartmental model for the behavior of leucine in brain that includes bidirectional carrier-mediated transport of leucine at the bloodbrain barrier, an extracellular and multiple intracellular compartments in brain, and the possibility that unlabeled leucine from the breakdown of tissue protein can be reincorporated into tissue protein. The application of the model together with an appropriate experimental design, i.e., a pulse injection of a tracer dose of L-[1-14 C]leucine followed by a 60-min interval for clearance of the tracer from the blood and the brain, gives rise to Eq.…”

Section: Discussionmentioning

confidence: 99%

“…The radiolabeled tracer is [1][2][3][4][5][6][7][8][9][10][11][12][13][14] C]leucine, which is used in conjunction with quantitative autoradiography to achieve spatial localization of the labeled protein in the brain for the determination of rates of protein synthesis in discrete brain regions (17). The operational equation of the method is:…”

Section: Methodsmentioning

confidence: 99%

“…Studies of developing mice administered high doses of Phe have shown disaggregation of brain polyribosomes and reduced rates of polypeptide chain elongation on polyribosomes prepared from brain homogenates (9,12); both of these effects were reversed by treatment of the mice with a mixture of neutral amino acids (leucine, isoleucine, valine, threonine, tryptophan, tyrosine, methionine) (13). Direct effects of hyperphenylalaninemia on cerebral protein synthesis in vivo have, however, been more difficult to demonstrate because of the complications of making such measurements in intact animals.…”

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confidence: 99%

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Cerebral protein synthesis in a genetic mouse model of phenylketonuria

Smith

Kang²

2000

Proc. Natl. Acad. Sci. U.S.A.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

mentioning

confidence: 99%

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Cerebral protein synthesis in a genetic mouse model of phenylketonuria

Smith

Kang²

2000

Proc. Natl. Acad. Sci. U.S.A.

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“…Hyperphenylalaninemia led to a loss of several AAs, especially LNAAs, in the brain of newborn mice, with a concomitant decrease in the incorporation of AAs into protein. Interestingly, the coadministration of LNAAs prevented this effect (30). However, the significance of animal models using experimentally induced hyperphenylalaninemia (29,30) remains questionable because of uncontrolled side effects of the PAH inhibitors used, e.g., α-methylphenylalanine.…”

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confidence: 99%

Large neutral amino acids block phenylalanine transport into brain tissue in patients with phenylketonuria

Pietz¹,

Kreis²,

Rupp³

et al. 1999

J. Clin. Invest.

255

178

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Large neutral amino acids (LNAAs), including phenylalanine (Phe), compete for transport across the blood-brain barrier (BBB) via the L-type amino acid carrier. Accordingly, elevated plasma Phe impairs brain uptake of other LNAAs in patients with phenylketonuria (PKU). Direct effects of elevated brain Phe and depleted LNAAs are probably major causes for disturbed brain development and function in PKU. Competition for the carrier might conversely be put to use to lower Phe influx when the plasma concentrations of all other LNAAs are increased. This hypothesis was tested by measuring brain Phe in patients with PKU by quantitative 1 H magnetic resonance spectroscopy during an oral Phe challenge with and without additional supplementation with all other LNAAs. Baseline plasma Phe was ∼1,000 µmol/l and brain Phe was ∼250 µmol/l in both series. Without LNAA supplementation, brain Phe increased to ∼400 µmol/l after the oral Phe load. Electroencephalogram (EEG) spectral analysis revealed acutely disturbed brain activity. With concurrent LNAA supplementation, Phe influx was completely blocked and there was no slowing of EEG activity. These results are relevant for further characterization of the LNAA carrier and of the pathophysiology underlying brain dysfunction in PKU and for treatment of patients with PKU, as brain function might be improved by continued LNAA supplementation.

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“…However, this pathway is inhibited when the supply of brain amino acids is altered by a singular hyperaminoacidemia, like phenylketonuria (PKU) (8 -11). PKU causes a decrease in amino acid supply in brain by competition effects at the BBB, and this decrease in brain protein synthesis is normalized by the administration of amino acids (12). In addition, many pathways of brain neurotransmitter synthesis are also rate-affected by the cerebral availability of precursor large neutral amino acids (6).…”

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confidence: 99%

Developmental Regulation of the Rabbit Blood-Brain Barrier LAT1 Large Neutral Amino Acid Transporter mRNA and Protein

Boado

Pardridge

2004

Pediatr Res

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The expression of the blood-brain barrier (BBB) LAT1 large neutral amino acid transporter mRNA and protein was investigated in development in rabbits. The BBB LAT1 mRNA was down-regulated with postnatal development. However, the BBB immunoreactive LAT1 protein was unchanged in postnatal development, despite an up-regulation of the BBB GLUT1 glucose transporter protein during this period. The dissociation between LAT1 protein and mRNA levels in development is consistent with posttranscriptional regulation of BBB LAT1 gene expression. The transport of the large neutral amino acids from blood to brain is mediated by the LAT1 large amino acid transporter located at the brain capillary endothelial membrane (1, 2), which forms the BBB in vivo. The LAT1 is also called the leucine-preferring or L-system amino acid transporter (3), and was originally cloned from C6 glial cells (4). The pools of amino acids in blood and in the brain intracellular spaces are separated by two membranes in series: the BBB and the BCM. Owing to the vastly greater surface area of the BCM compared with the BBB (5), the rate-limiting step in brain uptake of circulating amino acids is BBB transport (6). Therefore, amino acid availability in brain is regulated by BBB transport, and the availability of large neutral amino acids in brain regulates brain metabolism. For example, the influx of amino acids from blood to brain approximates the rates of amino acid incorporation into brain proteins (6). Under normal physiologic conditions, the synthesis of brain proteins is not influenced by the availability of amino acids (7). However, this pathway is inhibited when the supply of brain amino acids is altered by a singular hyperaminoacidemia, like phenylketonuria (PKU) (8 -11). PKU causes a decrease in amino acid supply in brain by competition effects at the BBB, and this decrease in brain protein synthesis is normalized by the administration of amino acids (12). In addition, many pathways of brain neurotransmitter synthesis are also rate-affected by the cerebral availability of precursor large neutral amino acids (6). In the developing brain, there are changes in protein synthesis that parallel the general reduction in cellular density of the older brain compared with the fetal or neonatal brain (13,14). Whether there is a parallel down-regulation of the BBB LAT1 gene expression with development is not known, although other BBB-nutrient transporters are developmentally regulated. For example, the gene expression of the BBB GLUT1 glucose transporter mRNA is up-regulated as suckling animals are weaned (15, 16). However, the regulation of the GLUT1 protein at the BBB is not linked to that of the BBB GLUT1 mRNA in developing rabbits, consistent with a posttranscriptional mechanism of regulation of BBB GLUT1 gene expression (16). The BBB GLUT1 glucose transporter protein is initially down-regulated after birth (16), when suckling animals use ketone bodies as a principal carbon source for the brain (15). Later in postnatal development, the BBB GLUT1 transporte...

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The effects of chronic hyperphenylalaninaemia on mouse brain protein synthesis can be prevented by other amino acids

Cited by 36 publications

References 23 publications

Cerebral protein synthesis in a genetic mouse model of phenylketonuria

Cerebral protein synthesis in a genetic mouse model of phenylketonuria

Large neutral amino acids block phenylalanine transport into brain tissue in patients with phenylketonuria

Developmental Regulation of the Rabbit Blood-Brain Barrier LAT1 Large Neutral Amino Acid Transporter mRNA and Protein

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