Van Gogh: a new Drosophila tissue polarity gene.

Mutations in the Van Gogh gene result in the altered polarity of adult Drosophila cuticular structures. On the wing, Van Gogh mutations cause an altered polarity pattern that is typical of mutations that inactivate the frizzled signaling/signal transduction pathway. The phenotype however, differs from those seen previously, as the number of wing cells forming more than one hair is intermediate between that seen previously for typical frizzled-like or inturned-like mutations. Consistent with Van Gogh being involved in the function of the frizzled signaling/signal transduction pathway, Van Gogh mutations show strong interactions with mutations in frizzled and prickle. Mitotic clones of Van Gogh display domineering cell nonautonomy. In contrast to frizzled clones, Van Gogh clones alter the polarity of cells proximal (and in part anterior and posterior) but not distal to the clone. In further contrast to frizzled clones, Van Gogh clones cause neighboring wild-type hairs to point away from rather than toward the clone. This anti-frizzled type of domineering nonautonomy and the strong genetic interactions seen between frizzled and Van Gogh suggested the possibility that Van Gogh was required for the noncell autonomous function of frizzled. As a test of this possibility we induced frizzled clones in a Van Gogh mutant background and Van Gogh clones in a frizzled mutant background. In both cases the domineering nonautonomy was suppressed consistent with Van Gogh being essential for frizzled signaling.     

Cell interactions and planar polarity in the abdominal epidermis of Drosophila

The integument of the Drosophila adult abdomen bears oriented hairs and bristles that indicate the planar polarity of the epidermal cells. We study four polarity genes, frizzled (fz), prickle (pk), Van gogh/strabismus (Vang/stbm) and starry night/flamingo (stan/fmi), and note what happens when these genes are either removed or overexpressed in clones of cells. The edges of the clones are interfaces between cells that carry different amounts of gene products, interfaces that can cause reversals of planar polarity in the clone and wild-type cells outside them. To explain, we present a model that builds on our earlier picture of a gradient of X, the vector of which specifies planar polarity and depends on two cadherin proteins, Dachsous and Fat. We conjecture that the X gradient is read out, cell by cell, as a scalar value of Fz activity, and that Pk acts in this process, possibly to determine the sign of the Fz activity gradient. We discuss evidence that cells can compare their scalar readout of the level of X with that of their neighbours and can set their own readout towards an average of those. This averaging, when it occurs near the edges of clones, changes the scalar response of cells inside and outside the clones, leading to new vectors that change polarity. The results argue that Stan must be present in both cells being compared and acts as a conduit between them for the transfer of information. And also that Vang assists in the receipt of this information. The comparison between neighbours is crucial, because it gives the vector that orients hairs--these point towards the neighbour cell that has the lowest level of Fz activity. Recently, it has been shown that, for a limited period shortly before hair outgrowth in the wing, the four proteins we study, as well as others, become asymmetrically localised in the cell membrane, and this process is thought to be instrumental in the acquisition of cell polarity. However, some results do not fit with this view--we suggest that these localisations may be more a consequence than a cause of planar polarity.     

Nonautonomous planar polarity patterning in Drosophila: dishevelled-independent functions of frizzled

The frizzled (fz) gene of Drosophila is required for planar polarity establishment in the adult cuticle, acting both cell autonomously and nonautonomously. We demonstrate that these two activities of fz in planar polarity are temporally separable in both the eye and wing. The nonautonomous function is dishevelled (dsh) independent, and its loss results in polarity phenotypes that resemble those seen for mutations in dachsous (ds). Genetic interactions and epistasis analysis suggest that fz, ds, and fat (ft) act together in the long-range propagation of polarity signals in the eye and wing. We also find evidence that polarity information may be propagated by modulation of the binding affinities of the cadherins encoded by the ds and ft loci.     

Inturned localizes to the proximal side of wing cells under the instruction of upstream planar polarity proteins

Planar polarity development in the Drosophila wing is under the control of the frizzled (fz) pathway. Recent work has established that the planar polarity (PP) proteins become localized to either the distal, proximal, or both sides of wing cells. Fz and Dsh distal accumulation is thought to locally activate the cytoskeleton to form a hair . Planar polarity effector (PPE) genes such as inturned (in) are not required for the asymmetric accumulation of PP proteins, but they are required for this to influence hair polarity. in mutations result in abnormal hair polarity and are epistatic to mutations in the PP genes. We report that In localizes to the proximal side of wing cells in a PP-dependent and PP-instructive manner. We further show that the function of two other PPE genes (fuzzy and fritz) is essential for In protein localization, a finding consistent with previous genetic data that suggested these three genes function in a common process. These data indicate that accumulation of proteins at the proximal side of wing cells is a key event for the distal activation of the cytoskeleton to form a hair.     

The Drosophila tissue polarity gene starry night encodes a member of the protocadherin family.

The tissue polarity genes control the polarity of hairs, bristles and ommatidia in the adult epidermis of Drosophila. We report here the identification of a new tissue polarity gene named starry night (stan). Mutations in this essential gene alter the polarity of cuticular structures in all regions of the adult body. The detailed polarity phenotype of stan on the wing suggested that it is most likely a component of the frizzled (fz) pathway. Consistent with this hypothesis, stan appears to be downstream of and required for fz function. We molecularly cloned stan and found that it encodes a huge protocadherin containing nine cadherin motifs, four EGF-like motifs, two laminin G motifs, and seven transmembrane domains. This suggests that Stan functions in signal reception, perhaps together with Fz.     

The frizzled extracellular domain is a ligand for Van Gogh/Stbm during nonautonomous planar cell polarity signaling

The Frizzled (Fz) receptor is required cell autonomously in Wnt/beta-catenin and planar cell polarity (PCP) signaling. In addition to these requirements, Fz acts nonautonomously during PCP establishment: wild-type cells surrounding fz(-) patches reorient toward the fz(-) cells. The molecular mechanism(s) of nonautonomous Fz signaling are unknown. Our in vivo studies identify the extracellular domain (ECD) of Fz, in particular its CRD (cysteine rich domain), as critical for nonautonomous Fz-PCP activity. Importantly, we demonstrate biochemical and physical interactions between the FzECD and the transmembrane protein Van Gogh/Strabismus (Vang/Stbm). We show that this function precedes cell-autonomous interactions and visible asymmetric PCP factor localization. Our data suggest that Vang/Stbm can act as a FzECD receptor, allowing cells to sense Fz activity/levels of their neighbors. Thus, direct Fz-Vang/Stbm interactions represent an intriguing mechanism that may account for the global orientation of cells within the plane of their epithelial field.     

frizzled Gene expression and development of tissue polarity in the Drosophila wing

Almost every cell in the Drosophila pupal wing forms a single, distally pointing cuticular hair. The function of the frizzled (fz) gene is essential for the elaboration of the normal wing hair pattern. In the absence of fz function hairs develop, but they display an abnormal polarity. We have examined the developmental expression of the fi gene at the RNA level via in situ hybridization and at the protein level via Western blotting. We have found that fz is expressed in all regions of the epidermis before, during, and after the fz cold sensitive period. We have also found that fz function is not required for normal fi expression. We have further found that mutations in several other tissue polarity genes do not noticeably alter the expression or the modification state of the Fz protein. © 1994 Wiley-Liss, Inc.     

Tissue polarity points from cells that have higher Frizzled levels towards cells that have lower Frizzled levels

Background: The frizzled (fz) gene of Drosophila encodes the founding member of the large family of receptors for the Wnt family of signaling molecules. It was originally studied in the adult epidermis, where it plays a key role in the generation of tissue polarity. Mutations in components of the fz signal transduction pathway disrupt tissue polarity; on the wing, hairs normally point distally but their polarity is altered by these mutations.Results: We devised a method to induce a gradient of fz expression with the highest levels near the distal wing tip. The result was a large area of proximally pointing hairs in this region. This reversal of polarity was seen when fz expression was induced just before the start of hair morphogenesis when polarity is established, suggesting that the gradient of Fz protein acted fairly directly to reverse hair polarity. A similar induction of the dishevelled (dsh) gene, which acts cell autonomously and functions downstream of fz in the generation of tissue polarity, resulted in a distinct tissue polarity phenotype, but no reversal of polarity; this argues that fz signaling was required for polarity reversal. Furthermore, the finding that functional dsh was required for the reversal of polarity argues that the reversal requires normal fz signal transduction.Conclusions: The data suggest that cells sense the level of Fz protein on neighboring cells and use this information in order to polarize themselves. A polarizing signal is transmitted from cells with higher Fz levels to cells with lower levels. Our observations enable us to propose a general mechanism to explain how Wnts polarize target cells.     

The function of the frizzled pathway in the Drosophila wing is dependent on inturned and fuzzy

The Drosophila epidermis is characterized by a dramatic planar or tissue polarity. The frizzled pathway has been shown to be a key regulator of planar polarity for hairs on the wing, ommatidia in the eye, and sensory bristles on the notum. We have investigated the genetic relationships between putative frizzled pathway downstream genes inturned, fuzzy, and multiple wing hairs (inturned-like genes) and upstream genes such as frizzled, prickle, and starry night (frizzled-like genes). Previous data showed that the inturned-like genes were epistatic to the frizzled-like genes when the entire wing was mutant. We extended those experiments and examined the behavior of frizzled clones in mutant wings. We found the domineering nonautonomy of frizzled clones was not altered when the clone cells were simultaneously mutant for inturned, multiple wing hairs, or dishevelled but it was blocked when the entire wing was mutant for inturned, fuzzy, multiple wing hairs, or dishevelled. Thus, for the domineering nonautonomy phenotype of frizzled, inturned and multiple wing hairs are needed in the responding cells but not in the clone itself. Expressing a number of frizzled pathway genes in a gradient across part of the wing repolarizes wing cells in that region. We found inturned, fuzzy, and multiple wing hairs were required for a gradient of frizzled, starry night, prickle, or spiny-legs expression to repolarize wing cells. These data argue that inturned, fuzzy, and multiple wing hairs are downstream components of the frizzled pathway. To further probe the relationship between the frizzled-like and inturned-like genes we determined the consequences of altering the activity of frizzled-like genes in wings that carried weak alleles of inturned or fuzzy. Interestingly, both increasing and decreasing the activity of frizzled and other upstream genes enhanced the phenotypes of hypomorphic inturned and fuzzy mutants. We also examined the relationship between the frizzled-like and inturned-like genes in other regions of the fly. For some body regions and cell types (e.g., abdomen) the inturned-like genes were epistatic to the frizzled-like genes, but in other body regions (e.g., eye) that was not the case. Thus, the genetic control of tissue polarity is body region specific.     

The inturned protein of Drosophila melanogaster is a cytoplasmic protein located at the cell periphery in wing cells

The inturned (in) gene is a component of the frizzled (fz) signaling pathway that controls the polarity of hairs and bristles in the epidermis of Drosophila. It appears to act downstream of fz, which encodes a putative receptor for a tissue polarity signal. The in gene encodes a novel protein that had been suggested to contain two potential transmembrane domains. It has been suggested that the In protein interacts with the actin cytoskeleton to regulate the formation of the pupal wing prehairs that become adult hairs. The initiation of prehairs is normally restricted to the vicinity of the distal most vertex along the apical surface of the pupal wing cells. In an in mutant, prehairs initate at a variety of locations along the apical cell periphery. We have used immunofluorescence to study the subcellular localization of the In protein. When expressed in cultured cells, we found that In is a cytoplasmic protein. However, we found that it is localized in the vicinity of plasma membrane and the cortical actin cytoskeleton of Drosophila wing disc and pupal wing cells. Thus, in wing cells the In protein is localized to the region of the cell where it appears to function. This subcellular localization presumably requires the function of other proteins and may represent a regulatory mechanism. Our data suggest that fz does not play a major role in the subcellular localization of In. The In protein is notably insoluble in buffers containing high salt and nonionic detergents. This lack of solubility is significantly reduced in fz and mwh mutants, implying that it may be related to the mechanism of in function.     

Molecular Analysis of Ems-Induced Frizzled Mutations in Drosophila Melanogaster

The frizzled (fz) gene of Drosophila is essential for the development of normal tissue polarity in the adult cuticle of Drosophila. In fz mutants the parallel array of hairs and bristles that decorate the cuticle is disrupted. Previous studies have shown that fz encodes a membrane protein with seven putative transmembrane domains, and that it has a complex role in the development of tissue polarity, as there exist both cell-autonomous and cell nonautonomous alleles. We have now examined a larger number of alleles and found that 15 of 19 alleles display cell nonautonomy. We have examined these and other alleles by Western blot analysis and found that most fz mutations result in altered amounts of Fz protein, and many also result in a Fz protein that migrates aberrantly in SDS-PAGE. We have sequenced a subset of these alleles. Cell nonautonomous fz alleles were found to be associated with mutations that altered amino acids in all regions of the Fz protein. Notably, the four cell-autonomous mutations were all in a proline residue located in the presumptive first cytoplasmic loop of the protein. We have also cloned and sequenced the fz gene from D. virilis. Conceptual translation of the D. virilis open reading frame indicates that the Fz protein is unusually well conserved. Indeed, in the putative cytoplasmic domains the Fz proteins of the two species are identical.     

The genetic control of tissue polarity in Drosophila.

The cuticular surface of Drosophila is decorated by parallel arrays of polarized structures such as hairs and sensory bristles; for example, on the wing each cell produces a distally pointing hair. These patterns are termed 'tissue polarity'. Several genes are known whose activity is essential for the development of normal tissue polarity. Mutations in these genes alter the orientation of the hair or bristle with respect to neighboring cells and the body as a whole. The phenotypes of mutations in these genes allows them to be placed in three phenotypic groups. Based on their behavior in genetic mosaics, it has proved possible to determine that individual genes are required either for the generation of an intercellular polarity signal and/or the transduction of that signal to the cytoskeleton.     

Hair growth in mouse mutants affecting coat texture

The genetic control of hair growth has been studied in mice carrying the following coat texture genes: fz (fuzzy), soc (soft coat), hid (hair interior defect), sa (satin), It (lustrous), Ve (velvet), wa-1 (waved-1), Re (rex), Re ^wc (wavy coat) and pk (plucked).
A general effect on cells of epidermal origin, found in soc/soc and Ve /+ skin samples illustrates how common factors control developmental potential in both the stratum germinativum and the follicle bulb. A direct influence on follicle bulb development is also seen in fz/fz homozygotes in which the dermal papilla functions abnormally. The role of the bulb cells and the dermal papilla in the control of hair shaft calibre is discussed.
hid is a new gene, found in homozygous condition in all mice of the AKR inbred strain. hid and sa appear primarily to be concerned in the differentiation of the medulla.
In the hair waving mutants, waved-1, rex and wavy coat, the processes controlling hair movement within the follicle are disturbed. These genes appear to regulate internal root sheath function. When the normal relationship between internal root sheath and developing hair shaft is disturbed, shaft movement slows, with the subsequent development of shaft calibre abnormalities.
pk acts at the level of the sebaceous gland, disturbing the normal process of hair eruption. The roles of the internal root sheath, external root sheath and the sebaceous gland in hair eruption are discussed.
The abnormal epidermal layer in soc/soc and Ve /+ skin also disturbs hair eruption to a small extent. The resulting abnormalities this causes in hair shaft formation are compared with those found pk/pk samples and also with the similar effects of faulty hair movement in the hair waving mutants. An effect on pigmentation is also described.
The chemistry of keratinization appears to be normal in all these mutants.     

The Drosophila STE20-like kinase misshapen is required downstream of the Frizzled receptor in planar polarity signaling.

The Drosophila misshapen (msn) gene is a member of the STE20 kinase family. We show that msn acts in the Frizzled (Fz) mediated epithelial planar polarity (EPP) signaling pathway in eyes and wings. Both msn loss- and gain-of-function result in defective ommatidial polarity and wing hair formation. Genetic and biochemical analyses indicate that msn acts downstream of fz and dishevelled (dsh) in the planar polarity pathway, and thus implicates an STE20-like kinase in Fz/Dsh-mediated signaling. This demonstrates that seven-pass transmembrane receptors can signal via members of the STE20 kinase family in higher eukaryotes. We also show that Msn acts in EPP signaling through the JNK (Jun-N-terminal kinase) module as it does in dorsal closure. Although at the level of Fz/Dsh there is no apparent redundancy in this pathway, the downstream effector JNK/MAPK (mitogen-activated protein kinase) module is redundant in planar polarity generation. To address the nature of this redundancy, we provide evidence for an involvement of the related MAP kinases of the p38 subfamily in planar polarity signaling downstream of Msn.     

Asymmetric homotypic interactions of the atypical cadherin flamingo mediate intercellular polarity signaling

Acquisition of planar cell polarity (PCP) in epithelia involves intercellular communication, during which cells align their polarity with that of their neighbors. The transmembrane proteins Frizzled (Fz) and Van Gogh (Vang) are essential components of the intercellular communication mechanism, as loss of either strongly perturbs the polarity of neighboring cells. How Fz and Vang communicate polarity information between neighboring cells is poorly understood. The atypical cadherin, Flamingo (Fmi), is implicated in this process, yet whether Fmi acts permissively as a scaffold or instructively as a signal is unclear. Here, we provide evidence that Fmi functions instructively to mediate Fz-Vang intercellular signal relay, recruiting Fz and Vang to opposite sides of cell boundaries. We propose that two functional forms of Fmi, one of which is induced by and physically interacts with Fz, bind each other to create cadherin homodimers that signal bidirectionally and asymmetrically, instructing unequal responses in adjacent cell membranes to establish molecular asymmetry.     

Wingless transduction by the Frizzled and Frizzled2 proteins of Drosophila.

Wingless (Wg) protein is a founding member of the Wnt family of secreted proteins which have profound organizing roles in animal development. Two members of the Frizzled (Fz) family of seven-pass transmembrane proteins, Drosophila Fz and Fz2, can bind Wg and are candidate Wg receptors. However, null mutations of the fz gene have little effect on Wg signal transduction and the lack of mutations in the fz2 gene has thus far prevented a rigorous examination of its role in vivo. Here we describe the isolation of an amber mutation of fz2 which truncates the coding sequence just after the amino-terminal extracellular domain and behaves genetically as a loss-of-function allele. Using this mutation, we show that Wg signal transduction is abolished in virtually all cells lacking both Fz and Fz2 activity in embryos as well as in the wing imaginal disc. We also show that Fz and Fz2 are functionally redundant: the presence of either protein is sufficient to confer Wg transducing activity on most or all cells throughout development. These results extend prior evidence of a ligand-receptor relationship between Wnt and Frizzled proteins and suggest that Fz and Fz2 are the primary receptors for Wg in Drosophila.     

Flamingo, a seven-pass transmembrane cadherin, regulates planar cell polarity under the control of Frizzled.

We identified a seven-pass transmembrane receptor of the cadherin superfamily, designated Flamingo (Fmi), localized at cell-cell boundaries in the Drosophila wing. In the absence of Fmi, planar polarity was distorted. Before morphological polarization of wing cells along the proximal-distal (P-D) axis, Fmi was redistributed predominantly to proximal and distal cell edges. This biased localization of Fmi appears to be driven by an imbalance of the activity of Frizzled (Fz) across the proximal/distal cell boundary. These results, together with phenotypes caused by ectopic expression of fz and fmi, suggest that cells acquire the P-D polarity by way of the Fz-dependent boundary localization of Fmi.     

Planar cell polarity and tissue design: Shaping the Drosophila wing membrane

Planar cell polarity (PCP) describes the orientation of a cell within the plane of an epithelial cell layer. During tissue development, epithelial cells normally align their PCP so that they face in the same direction. This alignment allows cells to move in a common direction, or to generate structures with a common orientation. A classic system for studying the coordination of epithelial PCP is the developing Drosophila wing. The alignment of epithelial PCP during pupal wing development allows the production of an array of cell hairs that point towards the wing tip. Multiple studies have established that the Frizzled (Fz) PCP signaling pathway coordinates wing PCP. Recently, we have found that the same pathway also controls the formation of ridges on the Drosophila wing membrane. However, in contrast to hair polarity, ridge orientation differs between the anterior and posterior wing. How can the Fz PCP pathway generate a different relationship between hair and ridge orientation in different parts of the wing? In this Extra View article, we discuss membrane ridge development drawing upon our recent PLoS Genetics paper and other, published and unpublished, data. We also speculate upon how our findings impact the ongoing debate concerning the interaction of the Fz PCP and Fat/Dachsous pathways in the control of PCP.     

Mitotic internalization of planar cell polarity proteins preserves tissue polarity

Planar cell polarity (PCP) is the collective polarization of cells along the epithelial plane, a process best understood in the terminally differentiated Drosophila wing. Proliferative tissues such as mammalian skin also show PCP, but the mechanisms that preserve tissue polarity during proliferation are not understood. During mitosis, asymmetrically distributed PCP components risk mislocalization or unequal inheritance, which could have profound consequences for the long-range propagation of polarity. Here, we show that when mouse epidermal basal progenitors divide PCP components are selectively internalized into endosomes, which are inherited equally by daughter cells. Following mitosis, PCP proteins are recycled to the cell surface, where asymmetry is re-established by a process reliant on neighbouring PCP. A cytoplasmic dileucine motif governs mitotic internalization of atypical cadherin Celsr1, which recruits Vang2 and Fzd6 to endosomes. Moreover, embryos transgenic for a Celsr1 that cannot mitotically internalize exhibit perturbed hair-follicle angling, a hallmark of defective PCP. This underscores the physiological relevance and importance of this mechanism for regulating polarity during cell division.     

Planar cell polarity and tissue design

Planar cell polarity (PCP) describes the orientation of a cell within the plane of an epithelial cell layer. During tissue development, epithelial cells normally align their PCP so that they face in the same direction. This alignment allows cells to move in a common direction, or to generate structures with a common orientation. A classic system for studying the coordination of epithelial PCP is the developing Drosophila wing. The alignment of epithelial PCP during pupal wing development allows the production of an array of cell hairs that point towards the wing tip. Multiple studies have established that the Frizzled (Fz) PCP signaling pathway coordinates wing PCP. Recently, we have found that the same pathway also controls the formation of ridges on the Drosophila wing membrane. However, in contrast to hair polarity, ridge orientation differs between the anterior and posterior wing. How can the Fz PCP pathway generate a different relationship between hair and ridge orientation in different parts of the wing? In this Extra View article, we discuss membrane ridge development drawing upon our recent PLoS Genetics paper and other, published and unpublished, data. We also speculate upon how our findings impact the ongoing debate concerning the interaction of the Fz PCP and Fat/Dachsous pathways in the control of PCP.