The MARCKS protein is a widely distributed cellular substrate for protein kinase C. It is a myristoylprotein that binds calmodulin and actin in a manner reversible by protein kinase C-dependent phosphorylation. It is also highly expressed in nervous tissue, particularly during development.
Tristetraprolin (TTP) is a zinc finger protein that can bind to AU-rich elements within certain mRNAs, resulting in deadenylation and destabilization of those mRNAs. Its physiological targets include the mRNAs encoding the cytokines tumor necrosis factor ␣ (TNF) and granulocyte-macrophage colony-stimulating factor. TTP was originally identified on the basis of its massive but transient increase in mRNA levels following mitogen stimulation of fibroblasts. It has been difficult to reconcile this transient mRNA profile with the presumed continuing "need" for TTP protein, for example, to reverse the effects of lipopolysaccharide (LPS)-stimulated TNF secretion. To investigate this and other questions concerning endogenous TTP protein in cells and tissues, we raised a high titer rabbit antiserum against full-length mouse TTP. TTP could be detected on immunoblots of mouse cytosolic tissue extracts; it was most highly expressed in spleen, but its concentration in that tissue was only about 1.5 nM. TTP could be detected readily in splenic macrophages and stromal cells from LPS-injected rats. In both LPS-treated RAW 264.7 macrophages and fetal calf serum-treated mouse embryonic fibroblasts, TTP protein was stable after induction, with minimal degradation occurring for several hours after treatment of the cells with cycloheximide. The biosynthesis of TTP was accompanied by large changes in electrophoretic mobility consistent with progressive phosphorylation. Confocal microscopy revealed that TTP accumulated in a vesicular pattern in the cytosol of the LPS-stimulated RAW 264.7 cells, and was occasionally seen in the cytosol of unstimulated dividing cells. Gel filtration of the endogenous protein suggested that its predominant structure was monomeric. TTP appears to be a low abundance, cytosolic protein in unstimulated cells and tissues, but once induced is relatively stable, in contrast to its very labile mRNA.
The myristoylated alanine-rich C kinase substrate, or MARCKS protein, is a widely expressed, prominent substrate for protein kinase C. Although the exact function of MARCKS has not been elucidated, targeted disruption of the MARCKS gene (Macs) in mice has shown that MARCKS plays a crucial role in the development of the central nervous system. Mice deficient in MARCKS exhibited universal perinatal death with defects in neurulation, fusion of the cerebral hemispheres, formation of the great forebrain commissures, and retinal and cortical lamination (Stumpo et al., Proc. Natl. Acad. Sci. USA 92, 944-948, 1995). In the present studies, a transgene consisting of approximately 3.4 kb of promoter from the human MARCKS gene (MACS), with an epitope tag sequence inserted at the carboxyl terminus of the MARCKS coding region, was able to complement completely MARCKS deficiency in mice. Thus, the human transgene contained all of the elements necessary for normal developmental expression of MARCKS. To test the importance of MARCKS myristoylation to its developmental role, an otherwise identical transgene was constructed in which the glycine at the amino terminus of MARCKS was mutated to an alanine. This mutation, which resulted in the expression of nonmyristoylated MARCKS, was successful in partially rescuing the Macs null phenotype. Specifically, about 25% of these mice survived the perinatal period; these survivors appeared to develop normally except for slightly decreased body size. In both the survivors and the nonsurvivors, all of the known anatomical defects associated with MARCKS deficiency were corrected by expression of the nonmyristoylated human protein. These results indicate that myristoylation of MARCKS is not required for the protein to correct many of the developmental abnormalities characteristic of its deficiency.
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