A novel cytoplasmic dual specificity protein tyrosine phosphatase implicated in muscle and neuronal differentiation.

Dual specificity protein tyrosine phosphatases (dsPTPs) are a subfamily of protein tyrosine phosphatases implicated in the regulation of mitogen-activated protein kinase (MAPK). In addition to hydrolyzing phosphotyrosine, dsPTPs can hydrolyze phosphoserine/threonine-containing substrates and have been shown to dephosphorylate activated MAPK. We have identified a novel dsPTP, rVH6, from rat hippocampus. rVH6 contains the conserved dsPTP active site sequence, VXVHCX2GX2RSX5AY(L/I)M, and exhibits phosphatase activity against activated MAPK. In PC12 cells, rVH6 mRNA is induced during nerve growth factor-mediated differentiation but not during insulin or epidermal growth factor mitogenic stimulation. In MM14 muscle cells, rVH6 mRNA is highly expressed in proliferating cells and declines rapidly during differentiation. rVH6 expression correlates with the inability of fibroblast growth factor to stimulate MAPK activity in proliferating but not in differentiating MM14 cells. rVH6 protein localizes to the cytoplasm and is the first dsPTP to be localized outside the nucleus. This novel subcellular localization may expose rVH6 to potential substrates that differ from nuclear dsPTPs substrates.

Differential activation of mitogen-activated protein kinase in response to basic fibroblast growth factor in skeletal muscle cells.

In the MM14 mouse myoblast cell line, fibroblast growth factor (FGF) stimulates proliferation and represses differentiation. However, the intracellular signaling pathways used by FGF to affect these cellular processes are unknown. The predominant FGF receptor present on MM14 cells, FGFR1, is a receptor tyrosine kinase capable of activating the mitogen-activated protein kinase (MAPK) cascade in fibroblast and neuronal cell lines. To determine whether the FGF signal is mediated via the MAPK cascade in myoblasts, MM14 cells were stimulated with basic FGF (bFGF) and activities of the various kinases were measured. After withdrawal from serum and bFGF for 3 hr, bFGF stimulated MAPK kinase (MAPKK) activity, but MAPK and S6 peptide kinase activities were not detected. In contrast, when serum and bFGF were withdrawn for 10 hr, the activities of MAPKK, MAPK, and S6 peptide kinase were all stimulated by bFGF treatment. The inability of bFGF to stimulate MAPK after 3 hr of withdrawal may be due, in part, to the presence of a MAPK phosphatase activity that was detected in MM14 cell extracts. This dephosphorylating activity diminishes during commitment to terminal differentiation and is inhibited by sodium orthovanadate. Thus, the ability of bFGF to stimulate MAPK in MM14 cells is correlated with the loss of a MAPK phosphatase activity. These results show that although bFGF activates MAPKK in proliferating myoblasts, the mitogenic signal does not progress to the downstream kinases, providing a physiological example of an uncoupling of the MAPK cascade.

Remodeling of myofibrils: subcellular distribution of myosin heavy chain mRNA and protein.

Myofibril remodeling occurs during the normal life, in growth and development, and in the special case when isoform switching occurs. In this review we concentrate on the ultrastructural aspects of how myosin is incorporated into the A-band. Anatomic methods of study are emphasized that include isotope and immunochemical labeling as well as in situ hybridization. We conclude that the mechanism of remodeling is one of continual orderly exchange between a monomeric myosin pool and the thick filament. Myosin mRNA distribution is intermyofibrillar and nonsarcomeric, which suggests that newly translated myosin is released before diffusion and insertion in the A-band of the myofibrillar lattice.

Ultrastructural distribution of myosin heavy chain mRNA in cardiac tissue: a comparison of frozen and LR White embedment.

Electron microscopy (EM) in situ hybridization provides the higher resolution necessary to determine the spatial relationship between a specific mRNA and the organelle containing the protein encoded by that message. EM in situ hybridization was used to determine the subcellular myosin heavy chain (MHC) mRNA distribution with respect to the myofibril in normal cardiac tissue. Sections of frozen or acrylic-embedded tissue were compared for ultrastructural integrity and content of endogenous mRNA. Papillary muscles dissected from hearts of normal rabbits were aldehyde-fixed and either frozen or embedded in LR White. EM in situ hybridization with no riboprobe, vector sequence, same-sense, and anti-sense biotinylated riboprobes was detected by indirect immunocytochemistry. Labeling density using an antisense probe was highest over the intermyofibrillar space, with an average signal five times that of background. Background labeling by nonspecific sense probe was consistently low but not random, also having the highest density of gold clusters over the intermyofibrillar space. Ultracryomicrotomy yielded a higher absolute number of gold clusters, but sections were fragmented and disrupted striated muscle morphology. LR White embedment maintained ultrastructural integrity but gave a lower absolute signal. Fortunately, MHC mRNA is an abundant message and can tolerate the decreased sensitivity of LR White.

Distribution of myosin heavy chain mRNA in normal and hyperthyroid heart.

Hyperthyroid treatment produces rapid cardiac cell hypertrophy with all subcellular components increasing in an orderly manner. We compare normal and hyperthyroid tissue in order to relate changes in distribution of myosin mRNA during rapid assembly of myofibrils. At the light microscopic level, in situ hybridization of the ventricular cells shows myosin heavy chain mRNA to be distributed in a spoke-like pattern radiating from the nucleus. Electron microscopy provides the higher resolution necessary to determine mRNA distribution with respect to adjacent sarcomeric and cytoskeletal structures. Papillary muscles were removed from hyperthyroid and normal rabbits, aldehyde fixed, and embedded in LR white. Biotinated riboprobe transcribed from 0.5 kb in the coding region of terminal portion of the rod of alpha-myosin was hybridized and detected by immunocytochemical methods using 5 nm immunoglobulin G gold conjugates. Electron microscopy in situ hybridization runs with same-sense and anti-sense riboprobes were processed and ten micrographs randomly taken from each. Specific cytoplasmic densities of myosin mRNA were calculated by counting clusters of five or more gold particles over respective tissue components after subtraction of background counts. For both normal myocytes and hyperthyroid myocytes, the density of myosin mRNA was about 15 times higher in the cytoskeletal-rich inter-myofibrillar space than in the myofibrils. About half of the myosin mRNA in this inter-myofibrillar region is found within 10 nm of the peripheral filament, but no excess sarcomeric accumulation was seen beside the A-Band. It appears that most of the myosin is translated from mRNA within the inter-myofibrillar space along the entire length of the myofibril periphery. The emerging myosin heavy chain is not directly anchored to the thick filaments in either normal or rapidly growing cardiac cells.

Individual rabbit cardiac myocytes have different thresholds for alpha myosin heavy chain regulation by thyroid hormone.

Myocytes in adult rabbit ventricle express and alpha and a beta form of myosin heavy chain (MHC). The alpha-MHC distribution detected with indirect immunofluorescence has been found in different proportions in adjacent myocytes producing a mosaic staining pattern. The basis for cell-specific expression of the alpha-MHC isoform is not known. Since thyroid hormone is a major regulator of myosin gene expression, we varied the plasma thyroid level and followed the alpha-MHC content within a population of myocytes. Ventricular myocytes were induced to become 100% beta-MHC by placing the rabbits on a 0.15% propylthiouracil diet for 70 days. L-triiodothyronine (LT3) over a dose range of 1 to 10 micrograms/kg/day was delivered by an osmotic minipump for 5 days, with actual serum levels confirmed by LT3 radioimmunoassay to be in the range of from 115 to 1,230 ng/dl. The amount of alpha-MHC that returned was estimated in randomly selected cells by measuring the relative intensity of the fluorescence-tagged secondary antibody. The normal mosaic pattern of alpha-MHC expression in the left ventricle returned with an LT3 dose of 2-5 micrograms/kg/day. The first myocytes to express alpha-MHC were in the subepicardium and did so at a LT3 serum level of 115 of ng/dl. All myocytes of the ventricular wall expressed alpha-MHC at serum levels above 1,230 ng/dl. These data are interpreted to show that the variation of myosin isoform content seen in the adult heart is indicative of heterogeneity of thyroid sensitivity, with the threshold for serum LT3 being between 115 and 370 ng/dl.

Incorporation of nascent myosin heavy chains into thick filaments of cardiac myocytes in thyroid-treated rabbits.

A monoclonal antibody (mAb 37) specific for alpha-myosin heavy chain (alpha-MHC) is used to follow the spatial and temporal incorporation of alpha-MHC into rabbit left ventricular myocytes. The expression of the two adult cardiac MHC genes, alpha and beta, is regulated by manipulating the thyroid hormone level of the animal. 10 wk on a propylthiouracil diet down-regulates expression of alpha-MHC to near 0%. alpha-MHC gene expression is up-regulated by injecting L-triiodothyronine (100 micrograms/kg per d) for 1-4 d. This protocol provides a means by which to follow the redistribution pattern of alpha-MHC within the myocyte in vivo. A uniform distribution of immunofluorescent signal is seen within every myocyte throughout the left ventricle. Ultracryomicrotomy without fixation is used to obtain sections for immunogold-electron microscopy. To quantify the immunogold method the density of gold-labeled antibody per unit of area tissue is determined for various regions of the sarcomere. Tissue from normal and 2-wk baby has a uniform distribution of gold density along the length of the A band. The average gold density of the A band increases with days of thyroid injection from 38 +/- 4 grains/micron 2 (n = 2 animals) (mean +/- SE) at day 1 to 182 +/- 59 grains (n = 2 animals) at day 4. There is a nonuniform incorporation of the newly synthesized alpha-MHC within the A band of thyroid-treated animals since 50% more of the alpha-MHC is found at the end of the A band while the center of the A band has 40% less than the average alpha-MHC content (grains/micron 2, n = 7 animals). These results support a thick filament assembly model that allows every myosin in a thick filament to be exchanged with new myosin. However, in the intact functioning myocyte, there is greater exchange of new myosin at the ends than in the central region of the thick filament.

Relationship of membrane systems in muscle to isomyosin content.

The structures and functions of the various subdivisions of the membrane systems of muscle are reviewed. Morphometric data have been recalculated using functional definitions of the membranes as identified by their proteins. Thus, the junctional coupling between the sarcoplasmic reticulum and T system is separated from the remaining longitudinal sarcoplasmic reticulum that bears the calcium ATPase protein. In addition, the morphometry of the membrane systems is related to the various muscle fiber types as defined histochemically and by protein isoforms. The relation of isomyosin type and membrane quantities are compared for guinea pig, chicken, frog, and lobster skeletal muscles and rat and rabbit cardiac muscles. Fiber plasticity is considered in terms of the mixing and matching of amounts and kinds of membranes and proteins.