Two isoforms of the Drosophila RNA binding protein, how, act in opposing directions to regulate tendon cell differentiation

Differential RNA metabolism regulates a wide array of developmental processes. Here, we describe a mechanism that controls the transition from premature Drosophila tendon precursors into mature muscle-bound tendon cells. This mechanism is based on the opposing activities of two isoforms of the RNA binding protein How. While the isoform How(L) is a negative regulator of Stripe, the key modulator of tendon cell differentiation, How(S) isoform elevates Stripe levels, thereby releasing the differentiation arrest induced by How(L). The opposing activities of the How isoforms are manifested by differential rates of mRNA degradation of the target stripe mRNA. This mechanism is conserved, as the mammalian RNA binding Quaking proteins may similarly affect the levels of Krox20, a regulator of Schwann cell maturation.     

Kakapo,a Novel Cytoskeletal-associated Protein Is Essential for the Restricted Localization of the Neuregulin-like Factor,Vein, at the Muscle–Tendon Junction Site

In the Drosophila embryo, the correct association of muscles with their specific tendon cells is achieved through reciprocal interactions between these two distinct cell types. Tendon cell differentiation is initiated by activation of the EGF-receptor signaling pathway within these cells by Vein, a neuregulin-like factor secreted by the approaching myotube. Here, we describe the cloning and the molecular and genetic analyses of kakapo, a Drosophila gene, expressed in the tendons, that is essential for muscle-dependent tendon cell differentiation. Kakapo is a large intracellular protein and contains structural domains also found in cytoskeletal-related vertebrate proteins (including plakin, dystrophin, and Gas2 family members). kakapo mutant embryos exhibit abnormal muscle-dependent tendon cell differentiation. A major defect in the kakapo mutant tendon cells is the failure of Vein to be localized at the muscle–tendon junctional site; instead, Vein is dispersed and its levels are reduced. This may lead to aberrant differentiation of tendon cells and consequently to the kakapo mutant deranged somatic muscle phenotype.     

WNT5 interacts with the Ryk receptors doughnut and derailed to mediate muscle attachment site selection in Drosophila melanogaster

In recent years a number of the genes that regulate muscle formation and maintenance in higher organisms have been identified. Studies employing invertebrate and vertebrate model organisms have revealed that many of the genes required for early mesoderm specification are highly conserved throughout evolution. Less is known about the molecules that mediate the steps subsequent to myogenesis, e. g. myotube guidance and attachment to tendon cells. We use the stereotypic pattern of the Drosophila embryonic body wall musculature in genetic approaches to identify novel factors required for muscle attachment site selection. Here, we show that Wnt5 is needed in this process. The lateral transverse muscles frequently overshoot their target attachment sites and stably attach at novel epidermal sites in Wnt5 mutant embryos. Restoration of WNT5 expression in either the muscle or the tendon cell rescues the mutant phenotype. Surprisingly, the novel attachment sites in Wnt5 mutants frequently do not express the Stripe (SR) protein which has been shown to be required for terminal tendon cell differentiation. A muscle bypass phenotype was previously reported for embryos lacking the WNT5 receptor Derailed (DRL). drl and Wnt5 mutant embryos also exhibit axon path finding errors. DRL belongs to the conserved Ryk receptor tyrosine kinase family which includes two other Drosophila orthologs, the Doughnut on 2 (DNT) and Derailed-2 (DRL-2) proteins. We generated a mutant allele of dnt and find that dnt, but not Drl-2, mutant embryos also show a muscle bypass phenotype. Genetic interaction experiments indicate that drl and dnt act together, likely as WNT5 receptors, to control muscle attachment site selection. These results extend previous findings that at least some of the molecular pathways that guide axons towards their targets are also employed for guidance of muscle fibers to their appropriate attachment sites.     

Moleskin is essential for the formation of the myotendinous junction in Drosophila

It is the precise connectivity between skeletal muscles and their corresponding tendon cells to form a functional myotendinous junction (MTJ) that allows for the force generation required for muscle contraction and organismal movement. The Drosophila MTJ is composed of secreted extracellular matrix (ECM) proteins deposited between integrin-mediated hemi-adherens junctions on the surface of muscle and tendon cells. In this paper, we have identified a novel, cytoplasmic role for the canonical nuclear import protein Moleskin (Msk) in Drosophila embryonic somatic muscle attachment. Msk protein is enriched at muscle attachment sites in late embryogenesis and msk mutant embryos exhibit a failure in muscle–tendon cell attachment. Although the muscle–tendon attachment sites are reduced in size, components of the integrin complexes and ECM proteins are properly localized in msk mutant embryos. However, msk mutants fail to localize phosphorylated focal adhesion kinase (pFAK) to the sites of muscle–tendon cell junctions. In addition, the tendon cell specific proteins Stripe (Sr) and activated mitogen-activated protein kinase (MAPK) are reduced in msk mutant embryos. Our rescue experiments demonstrate that Msk is required in the muscle cell, but not in the tendon cells. Moreover, muscle attachment defects due to loss of Msk are rescued by an activated form of MAPK or the secreted epidermal growth factor receptor (Egfr) ligand Vein. Taken together, these findings provide strong evidence that Msk signals non-autonomously through the Vein-Egfr signaling pathway for late tendon cell late differentiation and/or maintenance.     

Integrins modulate the Egfr signaling pathway to regulate tendon cell differentiation in the Drosophila embryo

Changes in the extracellular matrix (ECM) govern the differentiation of many cell types during embryogenesis. Integrins are cell matrix receptors that play a major role in cell-ECM adhesion and in transmitting signals from the ECM inside the cell to regulate gene expression. In this paper, it is shown that the PS integrins are required at the muscle attachment sites of the Drosophila embryo to regulate tendon cell differentiation. The analysis of the requirements of the individual alpha subunits, alphaPS1 and alphaPS2, demonstrates that both PS1 and PS2 integrins are involved in this process. In the absence of PS integrin function, the expression of tendon cell-specific genes such as stripe and beta1 tubulin is not maintained. In addition, embryos lacking the PS integrins also exhibit reduced levels of activated MAPK. This reduction is probably due to a downregulation of the Epidermal Growth Factor receptor (Egfr) pathway, since an activated form of the Egfr can rescue the phenotype of embryos mutant for the PS integrins. Furthermore, the levels of the Egfr ligand Vein at the muscle attachment sites are reduced in PS mutant embryos. Altogether, these results lead to a model in which integrin-mediated adhesion plays a role in regulating tendon cell differentiation by modulating the activity of the Egfr pathway at the level of its ligand Vein.     

Head activator and head inhibitor are signals for nerve cell differentiation in hydra

Head activator and head inhibitor control nerve cell differentiation in hydra. Head activator acts as a stimulatory signal on nerve cell differentiation by forcing nerve cell precursors, which are arrested before final differentiation, to develop into mature nerve cells. Head inhibitor acts antagonistically by keeping the cells in their arrested state, before mitosis and terminal differentiation. This and other evidence suggest that the arrest of the nerve cell precursors occurs in the G₂-phase of their cell cycle. Nerve cell differentiation can also be induced by wounding the animal. This is a consequence of an initial disinhibition caused by diffusion of head inhibitor out of the tissue and the subsequent release of head activator which then stimulates nerve cell differentiation.     

Altered cell-surface targeting of stem cell factor causes loss of melanocyte precursors in Steel17H mutant mice.

The normal products of the murine Steel (Sl) and Dominant white spotting (W) genes are essential for the development of melanocyte precursors, germ cells, and hematopoietic cells. The Sl locus encodes stem cell factor (SCF), which is the ligand of c-kit, a receptor tyrosine kinase encoded by the W locus. One allele of the Sl mutation, Sl17H, exhibits minor hematopoietic defects, sterility only in males, and a complete absence of coat pigmentation. The Sl17H gene encodes SCF protein which exhibits an altered cytoplasmic domain due to a splicing defect. In this paper we analyzed the mechanism by which the pigmentation phenotype in Sl17H mutant mice occurs. We show that in embryos homozygous for Sl17H the number of melanocyte precursors is severely reduced on the lateral neural crest migration pathway by e11.5 and can no longer be detected by e13.5 when they would enter the epidermis in wildtype embryos. The reduced number of dispersing melanocyte precursors correlates with a reduction of SCF immunoreactivity in mutant embryos in all tissues examined. Regardless of the reduced amount, functional SCF is present at the cell surface of fibroblasts transfected with Sl17H mutant SCF cDNA. Since SCF immunoreactivity normally accumulates in basolateral compartments of SCF-expressing embryonic epithelial tissues, we analyzed the localization of wildtype and Sl17H mutant SCF protein in transfected epithelial (MDCK) cells in vitro. As expected, wildtype forms of SCF localize to and are secreted from the basolateral compartment. In contrast, mutant forms of SCF, which either lack a membrane anchor or exhibit the Sl17H altered cytoplasmic tail, localize to and are secreted from the apical compartment of the cultured epithelium. We suggest, therefore, that the loss of melanocyte precursors prior to epidermal invasion, and the loss of germ cells from mature testis, can be explained by the inability of Sl17H mutant SCF to be targeted to the basolateral compartment of polarized epithelial keratinocytes and Sertoli cells, respectively.     

Fetal erythropoiesis in steel mutant mice : I. A morphological study of erythroid cell development in fetal liver

A method of definitive identification of mutant (S1/S1^d) and wild-type (+/+) mouse embryos in segregating litters is described, based on the total number of circulating erythrocytes in a unit volume of embryonic blood and the relative proportion of nonnucleated vs. nucleated red blood cells. Evidence is presented that from days 13–17 of gestation, S1/S1^d embryos have many fewer fetal liver derived nonnucleated erythrocytes whereas the number of yolk sac-derived nucleated red blood cells is similar between S1/S1^d and +/+. Erythroid precursor cells at various stages of maturation in mutant fetal livers are studied by light and electron microscopy, and their fine structure is found to be identical to those present in normal embryos. The number of hemoglobin-containing mature erythroblasts in mutant fetal livers is far fewer than that of the normal, whereas the number of immature erythroid precursors present in a unit area of fetal liver is not significantly different between S1/S1^d and +/+. It is suggested that the mutant S1 gene product(s) interferes with or fails to support the differentiation of immature erythroid precursors into hemoglobin synthesizing cells.     

A role for Lys-His-Gly-NH2 in avian and murine B cell development

Lys-His-Gly-NH2 has been claimed to selectively induce B cell precursors to differentiate into mature B lymphocytes. In the present study, the effects of this tripeptide and a control compound having the reverse sequence (Gly-His-Lys-NH2) on growth and differentiation of chicken and mouse B cell precursors were investigated. When chicken bone marrow (BM) cells from 15-day-old embryos were treated for 18 hr with either of the tripeptides, the frequency of Bu-1 antigen-bearing cells increased. Moreover, when embryonic bursa cells were stimulated in vitro with phorbol myristate acetate, which induces them to proliferate and undergo terminal differentiation into immunoglobulin (Ig)-secreting cells, these compounds caused a 10-fold increase in the number of Ig-secreting cells but did not increase cell proliferation. They had no effect on neonatal or adult bursa cells. Embryonic bursa cells were cultured in the presence of either of the tripeptides and metabolically labeled with [35S]methionine. When immunoprecipitated Ig was analyzed by two-dimensional gel electrophoresis, no differences in mu heavy or lambda light chain diversity patterns could be detected, indicating that neither of these compounds enhances Ig diversification. The effect of these tripeptides on murine B cell precursors was assayed in cultures of BM cells depleted of mature B cells by 5-fluorouracil. When precursor cells were incubated without adherent BM stromal cells, they did not respond to the tripeptides. However, after incubation of precursors with adherent stromal BM cells for 2 days, followed by treatment with either of the two tripeptides, differentiation into lipopolysaccharide-reactive mature B cells took place. Incubation of precursors with adherent stromal BM cells in the absence of tripeptides was not sufficient to allow the precursors to complete differentiation. In addition, both tripeptides acted synergistically with interleukin 1 or interleukin 3. In conclusion, these tripeptides seem to enhance precursor B cell differentiation in a lineage-nonspecific manner rather than to function as lineage-specific differentiation hormones.     

The splicing factor Prp43p, a DEAH box ATPase, functions in ribosome biogenesis

Biogenesis of the small and large ribosomal subunits requires modification, processing, and folding of pre-rRNA to yield mature rRNA. Here, we report that efficient biogenesis of both small- and large-subunit rRNAs requires the DEAH box ATPase Prp43p, a pre-mRNA splicing factor. By steady-state analysis, a cold-sensitive prp43 mutant accumulates 35S pre-rRNA and depletes 20S, 27S, and 7S pre-rRNAs, precursors to the small- and large-subunit rRNAs. By pulse-chase analysis, the prp43 mutant is defective in the formation of 20S and 27S pre-rRNAs and in the accumulation of 18S and 25S mature rRNAs. Wild-type Prp43p immunoprecipitates pre-rRNAs and mature rRNAs, indicating a direct role in ribosome biogenesis. The Prp43p-Q423N mutant immunoprecipitates 27SA2 pre-rRNA threefold more efficiently than the wild type, suggesting a critical role for Prp43p at the earliest stages of large-subunit biogenesis. Consistent with an early role for Prp43p in ribosome biogenesis, Prp43p immunoprecipitates the majority of snoRNAs; further, compared to the wild type, the prp43 mutant generally immunoprecipitates the snoRNAs more efficiently. In the prp43 mutant, the snoRNA snR64 fails to methylate residue C2337 in 27S pre-rRNA, suggesting a role in snoRNA function. We propose that Prp43p promotes recycling of snoRNAs and biogenesis factors during pre-rRNA processing, similar to its recycling role in pre-mRNA splicing. The dual function for Prp43p in the cell raises the possibility that ribosome biogenesis and pre-mRNA splicing may be coordinately regulated.     

The mystique of irreversibility in cyanobacterial heterocyst formation: parallels to differentiation and senescence in eukaryotic cells

The formation of cyanobacterial heterocysts is unique in the prokaryotic world: it is the only irreversible collective process. This terminal differentiation resembles senescence and differentiation in the eukaryotic urkingdom. During their cell cycle eukaryotic cells at the restriction point may reversibly proceed from a vegetative phase (G1) into a quiescent state (G0), and then may irreversibly enter the way towards differentiated or senescent cells. In parallel, at commitment point 1 vegetative cells from filamentous cyanobacteria may reversibly form proheterocysts, and then may proceed irreversibly towards mature heterocysts at commitment point 2. While the signals paving the path for differentiation or senescence in eukaryotes are largely unknown, heterocyst development is clearly triggered by nitrogen starvation. The reasons for the irreversibility in both systems are poorly understood. We discuss these questions, especially in the light of recent advances in the molecular biology of cyanobacteria, with emphasis on self-stabilizing autocatalytic cycles.     

Neurogenesis of the peripheral nervous system in Drosophila embryos: DNA replication patterns and cell lineages

Cell lineages that give rise to the PNS were studied using the thymidine analog 5-bromo-2'-deoxyuridine (BrdU) to visualized DNA replication immunocytochemically. The precursors of the PNS in the body segments of Drosophila embryos replicate their DNA in a spatially and temporally stereotyped pattern. The sequence of DNA replication within developing sensory organs suggests particular lineage relationships of the cells that constitute a sensory organ, i.e., neuron and associated support cells. In embryos that are mutant for the achaete-scute complex or daughterless, in which most or all of the PNS is missing, no BrdU-labeled cells were found in the appropriate regions, suggesting that these PNS precursors either do not form or fail to replicate. Thus, the BrdU technique allows determination as to whether a mutation affects the PNS precursors or terminal differentiation.     

GFR alpha3, a component of the artemin receptor, is required for migration and survival of the superior cervical ganglion.

GFR alpha3 is a component of the receptor for the neurotrophic factor artemin. The role of GFR alpha3 in nervous system development was examined by generating mice in which the Gfr alpha3 gene was disrupted. The Gfr alpha3-/- mice exhibited severe defects in the superior cervical ganglion (SCG), whereas other ganglia appeared normal. SCG precursor cells in the mutant embryos failed to migrate to the correct position, and they subsequently failed to innervate the target organs. In wild-type embryos, Gfr alpha3 was expressed in migrating SCG precursors, and artemin was expressed in and near the SCG. After birth, SCG neurons in the mutant mice underwent progressive cell death. These observations suggest that GFR alpha3-mediated signaling is required both for the rostral migration of SCG precursors and for the survival of mature SCG neurons.