Tissue development and RNA control: "HOW" is it coordinated?

The regulation of developmental processes at the RNA level enables selective and rapid modulation of gene expression. Studies in model organisms revealed the essential contribution of the signal transduction and activation of RNA (STAR) family of RNA binding proteins to developmental processes. STAR proteins coordinate the proper timing of developmental events by delaying expression or altering the mRNA or protein levels of essential genes. Recent functional analysis of the Drosophila melanogaster STAR protein, Held Out Wing (HOW), in the context of embryonic development, provided insight into its mode of activity. Here, we describe HOW's activity in the temporal repression or elevation of gene expression that is essential for coordinating the correct timing of instructive signals.

Post-transcriptional repression of the Drosophila midkine and pleiotrophin homolog miple by HOW is essential for correct mesoderm spreading.

The even spreading of mesoderm cells in the Drosophila embryo is essential for its proper patterning by ectodermally derived signals. In how germline clone embryos, defects in mesoderm spreading lead to a partial loss of dorsal mesoderm derivatives. HOW is an RNA-binding protein that is thought to regulate diverse mRNA targets. To identify direct HOW targets, we implemented a series of selection methods on mRNAs whose levels were elevated in how germline clone embryos during the stage of mesoderm spreading. Four mRNAs were found to be specifically elevated in the mesoderm of how germline clone embryos, and to exhibit specific binding to HOW via their 3' UTRs. Importantly, overexpression of three of these genes phenocopied the mesoderm-spreading phenotype of how germline clone embryos. Further analysis showed that overexpressing one of these genes, miple (a Drosophila midkine and pleiotrophin heparin-binding growth factor), in the mesoderm led to abnormal scattered MAPK activation, a phenotype that might explain the abnormal mesoderm spreading. In addition, the number of EVE-positive cells, which are responsive to receptor tyrosine kinase (RTK) signaling, was increased following Miple overexpression in the mesoderm and appeared to be dependent on Heartless function. In summary, our analysis suggests that HOW downregulates the levels of a number of mRNA species in the mesoderm in order to enable proper mesoderm spreading during early embryogenesis.

Cell divisions in the drosophila embryonic mesoderm are repressed via posttranscriptional regulation of string/cdc25 by HOW.

BACKGROUND: Cell-cycle progression is tightly regulated during embryonic development. In the Drosophila early embryo, the levels of String/Cdc25 define the precise timing and sites of cell divisions. However, cell-cycle progression is arrested in the mesoderm of gastrulating embryos despite a positive transcriptional string/cdc25 activation provided by the mesoderm-specific action of Twist. Whereas String/Cdc25 is negatively regulated by Tribbles in the mesoderm at these embryonic stages, the factor(s) controlling string/cdc25 mRNA levels has yet to be elucidated. RESULTS: Here, we show that the repressor isoform of the Drosophila RNA binding protein Held Out Wing [HOW(L)] is required to inhibit mesodermal cell division during gastrulation. Embryos mutant for how exhibited an excess of cell divisions, leading to delayed mesoderm invagination. The levels of the mitotic activator string/cdc25 mRNA in these embryos were significantly elevated. Protein-RNA precipitation experiments show that HOW(L) binds string/cdc25 mRNA. Overexpression of HOW(L) in Schneider cells reduces specifically the steady-state mRNA levels of a gfp reporter fused to string/cdc25 untranslated region (3'UTR). CONCLUSIONS: Our results suggest that in wild-type embryos, string/cdc25 mRNA levels are downregulated by the repressor isoform HOW(L), which binds directly to string/cdc25 mRNA and regulates its degradation. Thus, we are proposing a novel posttranscriptional mechanism controlling cell-cycle progression in the Drosophila embryo.

Dimerization in vivo and inhibition of the nonreceptor form of protein tyrosine phosphatase epsilon.

cyt-PTP epsilon is a naturally occurring nonreceptor form of the receptor-type protein tyrosine phosphatase (PTP) epsilon. As such, cyt-PTP epsilon enables analysis of phosphatase regulation in the absence of extracellular domains, which participate in dimerization and inactivation of the receptor-type phosphatases receptor-type protein tyrosine phosphatase alpha (RPTPalpha) and CD45. Using immunoprecipitation and gel filtration, we show that cyt-PTP epsilon forms dimers and higher-order associations in vivo, the first such demonstration among nonreceptor phosphatases. Although cyt-PTP epsilon readily dimerizes in the absence of exogenous stabilization, dimerization is increased by oxidative stress. Epidermal growth factor receptor stimulation can affect cyt-PTP epsilon dimerization and tyrosine phosphorylation in either direction, suggesting that cell surface receptors can relay extracellular signals to cyt-PTP epsilon, which lacks extracellular domains of its own. The inactive, membrane-distal (D2) phosphatase domain of cyt-PTP epsilon is a major contributor to intermolecular binding and strongly interacts in a homotypic manner; the presence of D2 and the interactions that it mediates inhibit cyt-PTP epsilon activity. Intermolecular binding is inhibited by the extreme C and N termini of D2. cyt-PTP epsilon lacking these regions constitutively dimerizes, and its activities in vitro towards para-nitrophenylphosphate and in vivo towards the Kv2.1 potassium channel are markedly reduced. We conclude that physiological signals can regulate dimerization and phosphorylation of cyt-PTP epsilon in the absence of direct interaction between the PTP and extracellular molecules. Furthermore, dimerization can be mediated by the D2 domain and does not strictly require the presence of PTP extracellular domains.

Protein tyrosine phosphatase epsilon inhibits signaling by mitogen-activated protein kinases.

Mitogen-activated protein kinases (MAPKs) mediate signaling from the cell membrane to the nucleus following their phosphorylation at conserved threonine and tyrosine residues within their activation loops. We show that protein tyrosine phosphatase epsilon (PTP epsilon) inhibits ERK1 and ERK2 kinase activity and reduces their phosphorylation; in agreement, ERK phosphorylation is increased in fibroblasts and in mammary tumor cells from mice genetically lacking PTP epsilon. PTP epsilon inhibits events downstream of ERKs, such as transcriptional activation mediated by Elk1 or by the serum response element. PTP epsilon also inhibits transcriptional activation mediated by c-Jun and C/EBP binding protein (CHOP) but not that mediated by the unrelated NFkB, attesting that it is broadly active within the MAPK family but otherwise specific. The effect of PTP epsilon on ERKs is at least in part indirect because phosphorylation of the threonine residue in the ERK activation loop is reduced in the presence of PTP epsilon. Nonetheless, PTP epsilon is present in a molecular complex with ERK, providing PTP epsilon with opportunity to act on ERK proteins also directly. We conclude that PTP epsilon is a physiological inhibitor of ERK signaling. Slow induction of PTP epsilon and its lack of nuclear translocation following mitogenic stimulation suggest that PTP epsilon functions to prevent inappropriate activation and to terminate prolonged, rather than acute, activation of ERK in the cytosol.

Nuclear localization of non-receptor protein tyrosine phosphatase epsilon is regulated by its unique N-terminal domain.

Precise subcellular localization is an important factor in regulation of the functions of protein tyrosine phosphatases. The non-receptor form of protein tyrosine phosphatase epsilon (cyt-PTP(epsilon)) can be found in cell nuclei, among other cellular locations, while p67 PTP(epsilon), a naturally occurring isoform which lacks the 27 N terminal residues of cyt-PTP(epsilon), is exclusively cytosolic. Using deletion and scanning mutagenesis we report that the first 10 amino acid residues of cyt-PTP(epsilon), in particular residues R4, K5, and R9, are critical components for its nuclear localization. We also establish that increased oxidative stress enhances accumulation of cyt-PTP(epsilon) in cell nuclei. Of the four known protein forms of PTP(epsilon), cyt-PTP(epsilon) is the only one which includes the extreme N-terminal sequence containing R4, K5, and R9. The role of the unique N terminus of cyt-PTP(epsilon) is therefore to regulate its subcellular localization. The existence of naturally occurring forms of PTP(epsilon) which lack this sequence and which are generated by translational and posttranslational mechanisms, suggests that nuclear localization of cyt-PTP(epsilon) can be actively regulated by cells.