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(Received for publication, June 23, 1995) Tyrosine 3-hydroxylase (TH, EC 1.14.16.2) catalyzes the first
and rate-limiting step of the catecholamine biosynthetic pathway in the
nervous and endocrine systems. The TH locus was disrupted in mouse
embryonic stem cells by homologous recombination. Mice heterozygous for
the TH mutation were apparently normal. In these mice, TH activity in
the embryos and adult tissues was less than 50% of the wild-type
values, but the catecholamine level was decreased only moderately in
the developing animals and was maintained normally at adulthood,
suggesting the presence of a regulatory mechanism for ensuring the
proper catecholamine level during animal development. In contrast, the
homozygous mutant mice died at a late stage of embryonic development or
shortly after birth. Both TH mRNA and enzyme activity were lacking in
the homozygous mutants, which thus explained the severe depletion of
catecholamines. These changes, however, did not affect gross
morphological development of the cells that normally express high
catecholamine levels. Analysis of electrocardiograms of surviving
newborn mutants showed bradycardia, suggesting an alteration of cardiac
functions in the homozygous mice that may lead to the lethality of this
mutation. In addition, transfer of a human TH transgene into the
homozygous mice corrected the mutant phenotype, showing recovery of TH
activity by expression of the human enzyme. These results indicate that
TH is essential for survival of the animals during the late gestational
development and after birth.
Volume 270,
Number 45,
Issue of November 10, 1995 pp. 27235-27243
©1995 by The American Society for Biochemistry and Molecular Biology, Inc.
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