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Enzyme
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Query: EC:3.1.3.16 (
calcineurin
)
17,112
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Here we describe a small family of proteins, termed MCIP1 and
MCIP2
(for myocyte-enriched
calcineurin
interacting protein), that are expressed most abundantly in striated muscles and that form a physical complex with
calcineurin
A. MCIP1 is encoded by DSCR1, a gene located in the Down syndrome critical region. Expression of the MCIP family of proteins is up-regulated during muscle differentiation, and their forced overexpression inhibits
calcineurin
signaling to a muscle-specific target gene in a myocyte cell background. Binding of MCIP1 to
calcineurin
A requires sequence motifs that resemble
calcineurin
interacting domains found in NFAT proteins. The inhibitory action of MCIP1 involves a direct association with the catalytic domain of
calcineurin
, rather than interference with the function of downstream components of the
calcineurin
signaling pathway. The interaction between MCIP proteins and
calcineurin
may modulate
calcineurin
-dependent pathways that control hypertrophic growth and selective programs of gene expression in striated muscles.
...
PMID:A protein encoded within the Down syndrome critical region is enriched in striated muscles and inhibits calcineurin signaling. 1072 14
Down syndrome is one of the major causes of mental retardation and congenital heart malformations. Other common clinical features of Down syndrome include gastrointestinal anomalies, immune system defects and Alzheimer's disease pathological and neurochemical changes. The most likely consequence of the presence of three copies of chromosome 21 is the overexpression of its resident genes, a fact which must underlie the pathogenesis of the abnormalities that occur in Down syndrome. Here we show that DSCR1, the product of a chromosome 21 gene highly expressed in brain, heart and skeletal muscle, is overexpressed in the brain of Down syndrome fetuses, and interacts physically and functionally with
calcineurin
A, the catalytic subunit of the Ca(2+)/calmodulin-dependent
protein phosphatase
PP2B. The DSCR1 binding region in
calcineurin
A is located in the linker region between the
calcineurin
A catalytic domain and the calcineurin B binding domain, outside of other functional domains previously defined in
calcineurin
A. DSCR1 belongs to a family of evolutionarily conserved proteins with three members in humans: DSCR1,
ZAKI-4
and DSCR1L2. We further demonstrate that overexpression of DSCR1 and
ZAKI-4
inhibits
calcineurin
-dependent gene transcription through the inhibition of NF-AT translocation to the nucleus. Together, these results suggest that members of this newly described family of human proteins are endogenous regulators of
calcineurin
-mediated signaling pathways and as such, they may be involved in many physiological processes.
...
PMID:DSCR1, overexpressed in Down syndrome, is an inhibitor of calcineurin-mediated signaling pathways. 1086 Dec 95
The
protein phosphatase
calcineurin
mediates many cellular responses to calcium signals. Using a genetic screen in yeast, we identified a new family of proteins conserved in fungi and animals that inhibit
calcineurin
function when overexpressed. Overexpression of the yeast protein Rcn1p or the human homologs DSCR1 or
ZAKI-4
inhibited two independent functions of
calcineurin
in yeast: The activation of the transcription factor Tcn1p and the inhibition of the H(+)/Ca(2+) exchanger Vcx1p. Purified recombinant Rcn1p and DSCR1 bound
calcineurin
in vitro and inhibited its
protein phosphatase
activity. Signaling via calmodulin,
calcineurin
, and Tcn1p induced Rcn1p expression, suggesting that Rcn1p operates as an endogenous feedback inhibitor of
calcineurin
. Surprisingly, rcn1 null mutants exhibited phenotypes similar to those of Rcn1p-overexpressing cells. This effect may be due to lower expression of
calcineurin
in rcn1 mutants during signaling conditions. Thus, Rcn1p levels may fine-tune
calcineurin
signaling in yeast. The structural and functional conservation between Rcn1p and DSCR1 suggests that the mammalian Rcn1p-related proteins, termed calcipressins, will modulate
calcineurin
signaling in humans and potentially contribute to disorders such as Down Syndrome.
...
PMID:A conserved family of calcineurin regulators. 1088 54
Calcineurin, a calcium/calmodulin-regulated
protein phosphatase
, modulates gene expression in cardiac and skeletal muscles during development and in remodeling responses such as cardiac hypertrophy that are evoked by environmental stresses or disease. Recently, we identified two genes encoding proteins (MCIP1 and
MCIP2
) that are enriched in striated muscles and that interact with
calcineurin
to inhibit its enzymatic activity. In the present study, we show that expression of MCIP1 is regulated by
calcineurin
activity in hearts of mice with cardiac hypertrophy, as well as in cultured skeletal myotubes. In contrast, expression of
MCIP2
in the heart is not altered by activated
calcineurin
but responds to thyroid hormone, which has no effect on MCIP1. A approximately 900-bp intragenic segment located between exons 3 and 4 of the MCIP1 gene functions as an alternative promoter that responds to
calcineurin
. This region includes a dense cluster of 15 consensus binding sites for NF-AT transcription factors. Because MCIP proteins can inhibit
calcineurin
, these results suggest that MCIP1 participates in a negative feedback circuit to diminish potentially deleterious effects of unrestrained
calcineurin
activity in cardiac and skeletal myocytes. Inhibitory effects of
MCIP2
on
calcineurin
activity may be pertinent to gene switching events driven by thyroid hormone in striated muscles. The full text of this article is available at http://www. circresaha.org.
...
PMID:Independent signals control expression of the calcineurin inhibitory proteins MCIP1 and MCIP2 in striated muscles. 1111 Jul 80
We identified
ZAKI-4
(also designated as DSCR1L1) as a thyroid hormone responsive gene in cultured human skin fibroblasts. Recently it has been reported that
ZAKI-4
belongs to an evolutionary conserved family of proteins that function as calcineurin inhibitor. In human,
ZAKI-4
and
calcineurin
are highly expressed in brain, where thyroid hormones play essential roles in the development during fetal and neonatal periods. In the present study, we examined the temporal and spatial expression patterns of
ZAKI-4
messenger RNA (mRNA) in control and hypothyroid rat brains. Northern blot analysis revealed that
ZAKI-4
mRNA was detected in both cerebral cortex and cerebellum as early as embryonic day (E)18. In the cerebral cortex, the expression level gradually increased with age, reaching a plateau at postnatal day (P)7 and remained constant thereafter until P30. A similar pattern of increase with age was also observed in hypothyroid rats; however, the magnitude of the increase was significantly reduced. In control rats, the fold increase in
ZAKI-4
mRNA level from E18 to P17 was 10.8; whereas in hypothyroid rats, it was 7.4. In cerebellum the expression level did not change with age or by thyroid status. In situ hybridization revealed that
ZAKI-4
mRNA is widely expressed in neurons throughout the brain. It is noteworthy that the expression in the neurons of layer VI of the cerebral cortex was more evident in control rats than that in hypothyroid rats from P17 to P30. Though not influenced by hypothyroidism, there were several regions of the brain in which
ZAKI-4
mRNA was strongly expressed. These regions were the mitral cell layer of the olfactory bulb, the substantia nigra, and the hippocampus, where
calcineurin
is also abundantly expressed. Therefore, it may be hypothesized that
ZAKI-4
plays an important role in the development and function of the brain by modulating
calcineurin
function; and decrease in
ZAKI-4
mRNA expression in the specific brain areas may explain, in some parts, the mechanism of abnormal brain development by hypothyroidism.
...
PMID:Expression of ZAKI-4 messenger ribonucleic acid in the brain during rat development and the effect of hypothyroidism. 1131 38
Calcineurin is a Ca(2+)/calmodulin-activated
protein phosphatase
that transduces hypertrophic stimuli to regulate transcriptional control of myocyte transformation. It is not known whether overexpression of MCIP1, a recently described endogenous inhibitor of
calcineurin
, impacts the hypertrophic response to pathophysiologically relevant pressure overload. Further, the functional consequences of
calcineurin
inhibition by MCIP1 under conditions of hemodynamic stress are unknown. Transgenic mice expressing a human cDNA encoding hMCIP1 in the myocardium were subjected to thoracic aortic banding. Transgenic mice and wild type littermates tolerated pressure overload equally well. Wild type mice developed left ventricular hypertrophy, but the hypertrophic response in transgenics was significantly blunted. An isoform of MCIP1 transcript was up-regulated by pressure stress, whereas
MCIP2
transcript was not. Expression patterns of fetal genes were differentially regulated in banded MCIP1 hearts compared with wild type. Echocardiography performed at 3 weeks and 3 months revealed preservation of both left ventricular size and systolic function in banded MCIP1 mice despite the attenuated hypertrophic response. These data demonstrate attenuation of hypertrophic transformation when
calcineurin
is inhibited by MCIP1. Further, these data suggest that activation of hypertrophic marker genes may not be directly dependent on
calcineurin
activity. Finally, they demonstrate that ventricular performance is preserved despite attenuation of compensatory hypertrophy.
...
PMID:Targeted inhibition of calcineurin in pressure-overload cardiac hypertrophy. Preservation of systolic function. 1178 44
We identified a thyroid hormone [3,5,3'-tri-iodothyronine (T(3))]-responsive gene,
ZAKI-4
, in cultured human skin fibroblasts. It belongs to a family of genes that encode proteins containing a conserved motif. The motif binds to
calcineurin
and inhibits its phosphatase activity. In the present study, we have demonstrated three different
ZAKI-4
transcripts, alpha, beta1 and beta2, in human brain by 5'- and 3'-RACE (rapid amplification of cDNA ends). The alpha transcript was identical with the one that we originally cloned from human fibroblasts and the other two are novel. The three transcripts are generated by alternative initiation and splicing from a single gene on the short arm of chromosome 6. It is predicted that beta1 and beta2 encode an identical protein product, beta, which differs from alpha in its N-terminus. Since alpha and beta contain an identical C-terminal region harbouring the conserved motif, both isoforms are suggested to inhibit
calcineurin
activity. Indeed, each isoform associates with
calcineurin
A and inhibits its activity in a similar manner, suggesting that the difference in N-terminus of each isoform does not affect the inhibitory function on
calcineurin
. An examination of the expression profile of the three transcripts in 12 human tissues revealed that the alpha transcript is expressed exclusively in the brain, whereas beta transcripts are expressed ubiquitously, most abundantly in brain, heart, skeletal muscle and kidney. It was also demonstrated that human skin fibroblasts express both alpha and beta transcripts, raising the question of which transcript is up-regulated by T(3). It was revealed that T(3) markedly induced the expression of alpha isoform but not of beta. This T(3)-mediated increase in the alpha isoform was associated with a significant decrease in endogenous
calcineurin
activity. These results suggest that the expression of
ZAKI-4
isoforms is subjected to distinct hormonal as well as tissue-specific regulation, constituting a complex signalling network through inhibition of
calcineurin
.
...
PMID:Novel human ZAKI-4 isoforms: hormonal and tissue-specific regulation and function as calcineurin inhibitors. 1210 56
