Molecular basis of phenotypic variation in patients with argininemia

Uchino, Tetsuya; Snyderman, Selma E.; Lambert, Marie; Qureshi, Ijaz A.; Shapira, Stuart K.; Sansaricq, Claude; Smit, L.; Jakobs, Cornelis; Matsuda, Ichiro

doi:10.1007/bf00210403

Cited by 45 publications

(43 citation statements)

References 19 publications

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“…Nonsense mutations have been reported in a minority of patients, with missense mutations being more prevalent [Uchino et al, 1995;Vockley et al, 1994]. Many of these missense mutations occur in highly conserved regions of the gene .…”

Section: Molecular Characteristicsmentioning

confidence: 99%

Clinical, biochemical, and molecular spectrum of hyperargininemia due to arginase I deficiency

Scaglia

Lee²

2006

American J of Med Genetics Pt C

103

160

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The urea cycle consists of six consecutive enzymatic reactions that convert waste nitrogen into urea. Urea cycle disorders are a group of inborn errors of hepatic metabolism that often result in life threatening hyperammonemia and hyperglutaminemia. Deficiencies of all of the enzymes of the cycle have been described and although each specific disorder results in the accumulation of different precursors, hyperammonemia and hyperglutaminemia are common biochemical hallmarks of these disorders. Arginase is the enzyme involved in the last step of the urea cycle. It catalyzes the conversion of arginine to urea and ornithine. The latter reenters the mitochondrion to continue the cycle. Hyperargininemia is an autosomal recessive disorder caused by a defect in the arginase I enzyme. Unlike other urea cycle disorders, this condition is not generally associated with a hyperammonemic encephalopathy in the neonatal period. It typically presents later in childhood between 2 and 4 years of age with predominantly neurological features. If untreated, it progresses with gradual developmental regression. A favorable outcome can be achieved if dietary treatment and alternative pathway therapy are instituted early in the disease course. With this approach, further neurological deterioration is prevented and partial recovery of skills ensues. Early diagnosis of this disorder through newborn screening programs may lead to a better outcome. This review article summarizes the clinical characterization of this disorder; as well as its biochemical, enzymatic, and molecular features. Treatment, prenatal diagnosis and diagnosis through newborn screening are also discussed.

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Section: Molecular Characteristicsmentioning

confidence: 99%

Clinical, biochemical, and molecular spectrum of hyperargininemia due to arginase I deficiency

Scaglia

Lee²

2006

American J of Med Genetics Pt C

103

160

View full text Add to dashboard Cite

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“…Hyperargininemia is a heterogeneous disease resulting from point mutations throughout the type I arginase gene (11)(12)(13)(14)(15)(16)(17). An R291X mutation has been identified that would lead to the production of a truncated protein lacking the final 32 amino acids at the C terminus of the 323 amino acid subunit.…”

mentioning

confidence: 99%

Subunit-Subunit Interactions in Trimeric Arginase

Lavulo¹,

Sossong²,

Brigham-Burke³

et al. 2001

Journal of Biological Chemistry

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The structure of the trimeric, manganese metalloenzyme, rat liver arginase, has been previously determined at 2.1-Å resolution (Kanyo, Z. F., Scolnick, L. R., Ash, D. E., and Christianson, D. W., (1996) Nature 383, 554 -557). A key feature of this structure is a novel Sshaped oligomerization motif at the carboxyl terminus of the protein that mediates ϳ54% of the intermonomer contacts. Arg-308, located within this oligomerization motif, nucleates a series of intramonomer and intermonomer salt links. In contrast to the trimeric wild-type enzyme, the R308A, R308E, and R308K variants of arginase exist as monomeric species, as determined by gel filtration and analytical ultracentrifugation, indicating that mutation of Arg-308 shifts the equilibrium for trimer dissociation by at least a factor of 10 5 . These monomeric arginase variants are catalytically active, with k cat /K m values that are 13-17% of the value for wild-type enzyme. The arginase variants are characterized by decreased temperature stability relative to the wild-type enzyme. Differential scanning calorimetry shows that the midpoint temperature for unfolding of the Arg-308 variants is in the range of 63.6 -65.5°C, while the corresponding value for the wild-type enzyme is 70°C. The three-dimensional structure of the R308K variant has been determined at 3-Å resolution. At the high protein concentrations utilized in the crystallizations, this variant exists as a trimer, but weakened salt link interactions are observed for Lys-308.

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“…At least 12 distinct disease-causing mutations in ARG1 have been identified so far in different human populations, indicating that argininemia is heterogeneous at the molecular level (Haraguchi et al, 1990;Grody et al 1992;Uchino et al 1992, Vockley et al, 1994Uchino et al, 1995). In this work we extend the sequence data on arginase deficiency by characterizing a novel R21X mutation found in four homozygous Portuguese patients with argininemia.…”

Section: Introductionmentioning

confidence: 60%

“…Based on the results from in vitro expression tests, Uchino et al (1995) proposed that ARG1 pathogenic mutations could be classified as either severe or moderate and further suggested that the clinical responses to dietary treatment were correlated with the nature of these mutations. Among the severe mutations, Uchino et al (1995) included the deletion 77delA, which leads to a shift in the reading frame after aminoacid residue 26 and creates a premature termination at codon 31.…”

Section: Arg1 R21x Substitution and Argininemia 5 Discussionmentioning

confidence: 99%