Interactive Fly, Drosophila

Hedgehog (Hh) and Decapentaplegic (Dpp) direct anteroposterior patterning in the developing Drosophila wing by functioning as short- and long-range morphogens, respectively. The activity of Dpp is graded and is directly regulated by a novel Hh-dependent mechanism. Dpp activity is monitored by visualizing the activated form of Mothers against dpp (Mad), a cytoplasmic transducer of Dpp signaling. Activated Mad levels are highest near the source of Dpp but are unexpectedly low in the cells that express dpp. Hh induces dpp in these cells; it also attenuates their response to Dpp by downregulating expression of the Dpp receptor thick veins (tkv). It has been suggested that regulation of tkv by Hh is a key part of the mechanism that controls the level and distribution of Dpp (Tanimoto, 2000).

To determine whether the low levels of phosphorylated Mad (p-MAD) in dpp-expressing cells reflect an autoregulatory influence on Dpp signaling that functions only in dpp-expressing cells, or whether p-MAD levels are controlled by another signal such as Hh, p-MAD was monitored in wing discs carrying clones that ectopically express hh or dpp. If Dpp has the potential to attenuate its own signal transduction, the level of p-MAD would be expected to decrease cell autonomously in cells that express dpp. However, the level of p-MAD is elevated around the clones with no obvious reduction within the clones. This observation is not consistent with an autoregulatory mechanism. In contrast, clones expressing hh in the A compartment cause both a nonautonomous reduction of p-MAD level as well as ectopic elevation of p-MAD around the clones, which is due to ectopic induction of dpp by Hh. No changes in p-MAD levels are observed when Hh is expressed in the P compartment. These observations suggest that Hh attenuates Dpp signal transduction by regulating the type I receptor-dependent phosphorylation of MAD. Thus, the activity of Dpp depends on both the concentration of Dpp and Hh (Tanimoto, 2000).

It was next asked whether Hh directly controls p-MAD levels. First, clones that ectopically express HhCD2, a membrane-tethered form of Hh, were compared to clones that express a diffusible form of Hh. P-MAD levels are reduced both in cells that expressed HhCD2 and in cells that are immediately adjacent. In contrast, the levels of p-MAD are reduced more broadly when cells express diffusible Hh. The distribution of p-MAD was examined when clones of cells mutant for either Protein kinase A (Pka) alone or both Pka and dpp were induced. Pka functions to antagonize Hh signaling: Pka^- clones in the A compartment fail to repress Hh signaling in a cell-autonomous manner. Pka^- clones in the A compartment have reduced levels of p-MAD. Moreover, p-MAD accumulates to high levels in cells surrounding Pka^- clones, due, presumably, to the ectopic induction of Dpp by constitutive Hh signaling in the mutant cells. In clones mutant for both Pka and dpp, the reduction was evident, but it was not accompanied by elevated levels in the surrounding cells. Outside the double-mutant clones, p-MAD appears to respect the endogenous gradient of Dpp. Autonomous reduction in the level of Spalt is also seen in both types of mutant clones, confirming both that p-MAD accurately manifests the active state of Dpp signaling and that the reduction of p-MAD leads to the decrease of target gene expression. It is concluded that Hh signaling directly attenuates Dpp signal transduction regardless of the level of endogenous Dpp (Tanimoto, 2000).

The contribution of Cubitus interruptus (Ci) to Hh-dependent attenuation of Dpp signaling was examined. ci is expressed in the A compartment only. In clones that ectopically express Ci in the P compartment where Hh is abundant, the levels of p-MAD were reduced in a cell-autonomous manner. Levels of Sal are similarly reduced in these cells. Clones that ectopically express ci in A compartment regions that receive little or no Hh have no effect on p-MAD levels. It is concluded that Hh both induces dpp expression and downregulates Dpp signal transduction in the same cells (Tanimoto, 2000).

Because Ci is involved in regulating p-MAD levels, it is possible that Hh controls the expression of a component that functions upstream of Mad phosphorylation. The possibiliy that Hh regulates the transcription of the Dpp receptors was therefore investigated. Dpp preferentially signals through the Tkv receptor and also negatively regulates tkv expression. Therefore, the correlation between tkv expression and the activity of Dpp was examined. The level of tkv expression is higher in cells located peripherally and is lower in the central region. In addition, a sharp reduction in expression at the A/P border was observed, a pattern very similar to that of p-MAD. The level of tkv expression in the area between the peripheral region and the A/P border is referred to as 'basal' and the reduced level at the A/P border as 'hyperrepression'. Interestingly, the basal level in the P compartment is higher than it is in the A compartment. This may account for the steeper gradient of p-MAD in the P compartment, since high levels of Tkv limit the movement of Dpp; since the spread of Dpp would be less in the P compartment, its gradient of activity would be expected to be steeper (Tanimoto, 2000).

In order to investigate the role of Dpp in generating the complex pattern of tkv expression, tkv and p-MAD were monitored in discs that ubiquitously express dpp. These discs exhibit significant overgrowth. tkv-lacZ at the A/P border remains hyperrepressed, but the level of peripheral tkv is significantly reduced, apparently to the basal level. This suggests that the level of tkv in the peripheral regions is directly regulated by Dpp but that the level at the A/P compartment border is not. The basal level in the P compartment remains higher than in the A compartment. Distribution of p-MAD is consistent with the expression pattern of tkv: overexpression of dpp caused the ubiquitous elevation of p-MAD, except at the A/P border. In contrast, phosphorylation of Mad at the A/P border is unchanged in the presence of excess Dpp. This suggests that the level of tkv along the A/P border is limiting. When constitutively active Tkv (tkv*) is ubiquitously expressed, peripheral tkv expression is reduced to the basal level, comparable to Dpp overexpression. Unlike the discs in which Dpp is overexpressed, no reduction in p-MAD is observed at the A/P border in these discs. These results suggest that in middle regions of the A and P compartments in normal discs, Dpp signaling reduces tkv expression from the levels at the periphery to the basal level. However, Dpp signaling is not responsible for the hyperrepression at the A/P border or for the difference between the basal levels in the A and P compartments. Given that hyperrepression of p-MAD along the A/P border is not observed in the presence of TKV*, it is more likely that in this region, Hh modulates p-MAD levels by regulating tkv (Tanimoto, 2000).

To ask whether Hh controls tkv expression directly at the A/P border, clones of cells mutant for patched (ptc), expressed in all A cells, were examined. The Hh signal transduction is constitutively active in the absence of the ptc activity. p-MAD and tkv-lacZ were monitored in ptc^- clones. The clones in the A compartment ectopically activate Hh signaling in a cell-autonomous manner; they also caused cell-autonomous repression of tkv. Outside of the clone, the level of tkv is reduced to the basal level, but this level is higher than within the clone. This behavior is likely due to ectopic expression of dpp. P-MAD levels are also reduced in the clone and are higher around the clone. This establishes that Hh signaling directly represses tkv and, as a consequence, represses phosphorylation of MAD. This conclusion is confirmed by examining discs carrying clones of cells in the P compartment that ectopically express ci. tkv is autonomously repressed in these clones, indicating that Ci-mediated Hh signaling directly represses tkv (Tanimoto, 2000).

In order to understand the significance of Hh-dependent repression of tkv, the level of tkv expression was changed. In the wing disc, when overexpressing tkv in the dorsal compartment under the control of apterous (ap) enhancer, the levels of the dorsal p-MAD and Spalt expression at the A/P border are elevated, and their distribution is significantly narrower than in the ventral compartment. This is probably due to the sequestration of Dpp protein by the elevated Tkv. In addition, the adult wing misexpressing tkv was examined in dpp-expressing cells where tkv is hyperrepressed. The overexpression caused small wings with abnormal patterning in the central region of the wing. These results are consistent with the proposal that Hh, but not Dpp, patterns the central wing region. It should be noted, however, that the level of tkv expression in the experimental clones is probably at least several fold higher than normal, since these experiments utilized the Gal4/UAS system (Tanimoto, 2000).

The activities of Dpp were examined when tkv expression differed from wild type by only 2-fold. Clones mutant for tkv were generated in a heterozygous background such that both mutant (0 copies of the wild-type tkv) and fully wild-type sister clones (2 copies of wild-type tkv) were produced. However, since clones of cells with no Tkv activity do not survive in the wing pouch because they need Tkv activity to grow, only their sister clones survive. Homozygous (+/+) clones at the A/P border increase p-MAD and Spalt levels autonomously. The same analysis was performed using a null sax allele: differences in the levels of p-MAD and Spalt between clones carrying two wild-type sax and cells lacking one copy of sax were negligible. Taken together, it is proposed that the precise regulation of the Tkv receptor level by Hh signal is necessary for Dpp morphogen to shape the correct activity gradient (Tanimoto, 2000).

Formation of the trachea occurs by the migration and fusion of clusters of ectodermal cells specified in each side of ten embryonic segments. Morphogenesis of the tracheal tree requires the activity of many genes, among them breathless (btl) and ventral veinless (vvl), whose mutations abolish tracheal cell migration. Activation of the btl receptor by branchless (bnl), its putative ligand, exerts an instructive role in the process of guiding tracheal cell migration. decapentaplegic determines vvl expression along the embryonic dorsoventral axis; expansion of dpp expression results in an increased recruitment of cells to express vvl. These cells are allocated in the expanded tracheal placodes, indicating that expansion of dpp expression causes a concomitant enlargement of the traceal placodes and of vvl expression. vvl is also required for the maintenance of btl expression during tracheal migration (Llimargas, 1997).

vvl is independently required for the specific expression in the tracheal cells of thick veins (tkv) and rhomboid (rho), two genes whose mutations disrupt only particular branches of the tracheal system. Expression in the tracheal cells of an activated form of tkv, the Decapentaplegic receptor, induces shifts in the migration of these cells, asserting the role of the dpp pathway in establishing the branching pattern of the tracheal tree. In addition, by ubiquitous expression of the btl and tkv genes in vvl mutants it is shown that both genes contribute to vvl function. These results indicate that through activation of its target genes, vvl makes the tracheal cells competent to further signaling and suggest that the btl transduction pathway could collaborate with other transduction pathways also regulated by vvl to specify the tracheal branching pattern (Llimargas, 1997).

The Drosophila tracheal system is a network of epithelial tubes that arises from the tracheal placodes, lateral clusters of ectodermal cells in ten embryonic segments. The cells of each cluster invaginate and subsequent formation of the tracheal tree occurs by cell migration and fusion of tracheal branches, without cell division. The combined action of the Decapentaplegic (Dpp), Epidermal growth factor (EGF) and breathless/ branchless pathways are thought to be responsible for the pattern of tracheal branches. It is asked how these transduction pathways regulate cell migration and the consequences on cell behaviour of the Dpp and EGF pathways is examined. rhomboid (rho) mutant embryos display defects not only in tracheal cell migration but also in tracheal cell invagination unveiling a new role for EGF signaling in the formation of the tracheal system. These results indicate that the transduction pathways that control tracheal cell migration are active in different steps of tracheal formation, beginning at invagination (Llimargas, 1999).

These observations also illustrate the role of vvl in tracheal formation. Since btl expression is normally initiated in vvl mutants, early but not sustained activity of the Btl pathway could cause the tracheal phenotype in vvl mutant embryos. Since vvl is also required for the tracheal expression of tkv and rho, failure to activate the Dpp and EGF pathways could also be the source of the cell shape phenotypes in vvl mutant embryos. This latter possibility is substantiated by the observation that vvl and rho mutant embryos show abnormalities in tracheal invagination that are not present in btl mutant embryos. Finally, the tkv;rho double mutant tracheal phenotype is very similar to the vvl phenotype (Llimargas, 1999).

Multiple signaling pathways interact to determine the formation of the different tracheal branches. However, even though they all affect the directed migration of the tracheal cells, they are active in different steps in the morphogenesis of the tracheal tree. In particular, the results show that while the Bnl/Btl pathway is specifically required for migration, EGF signaling is active in tracheal cell invagination. These observations also indicate that the accurate invagination of the tracheal cells inside the embryo is an important factor in order to follow a particular direction of migration. In particular, different levels of invagination could predetermine whether cells would migrate in one or the other direction. In this regard, it is worth noting that while in rho mutant embryos some cells remain at the embryonic surface and do not invaginate, in tkv mutant embryos some cells remain in an intermediate position, indicating that they are able to invaginate but do not reach their final location. Altogether, these observations suggest that the precise topology of the invaginating cells controlled by EGF and Dpp signaling could be determining how the tracheal cells will respond to guiding cues, such as Bnl (Llimargas, 1999).

The Drosophila tracheal system arises from clusters of ectodermal cells that invaginate and migrate to originate a network of epithelial tubes. Genetic analyses have identified several genes that are specifically expressed in the tracheal cells and are required for tracheal development. Among them, trachealess (trh) is able to induce ectopic tracheal pits and therefore it has been suggested that it would act as an inducer of tracheal cell fates; however, this capacity appears to be spatially restricted. The expression of the tracheal specific genes in the early steps of tracheal development and their crossinteractions have been examined. There is a set of primary genes including trh and ventral veinless (vvl) whose expression does not depend on any other tracheal gene and a set of downstream genes whose expression requires different combinations of the primary genes. The combined expression of primary genes is sufficient to induce some downstream genes but not others. While tracheal expression of tkv depends on vvl, it appears to be independent of trh. The opposite appears to be the case for two other tracheal genes, tracheal defective (tdf) and pebbled (peb) [also known as hindsight (hnt)], which code for two putative transcription factors. Both genes appear to be targets of trh but they are present in the tracheal cells of vvl mutant embryos. Thus, some tracheal genes seem to be common targets of vvl and trh but others seem to depend only on one of them (Boube, 2000).

In addition to essential myogenic functions, mutant Mef2 adult females are weakly fertile and produce defective eggs. Mef2 is expressed in nurse and follicle cells of the wild-type egg chamber. The Mef2 oogenic phenotype has been analyzed and it has been shown that the gene is required for the normal patterning and differentiation of the centripetally migrating follicle cells (CMFCs) that are crucial for development of the anterior chorionic structures. Mef2 alleles exhibit a genetic interaction with a dominant-negative allele of thick veins (tkv), which encodes a type I receptor of the Decapentaplegic-signaling pathway. TKV mRNA is overexpressed in Mef2 mutant egg chambers, and, conversely, forced expression of Mef2 represses tkv expression. These results indicate roles for Mef2 in the regulation of tkv gene expression and Decapentaplegic signal transduction that are essential for proper determination and/or differentiation of the anterior follicle cells. Mef2 is also expressed in both nurse and follicle cells. No defects have been observed in the germ line, either the number of germ cells or the location of the oocyte within the egg chamber. Therefore, a possible requirement for Mef2 in germ-line cells remains to be elucidated (Mantrova, 1999).

Mef2 appears to function in the somatic follicle cells, particularly in subpopulations of the oocyte-associated follicle cells (O-FCs), by negatively regulating TKV mRNA levels. It is not known whether Mef2 directly represses tkv gene transcription. Curiously, the expression patterns of Mef2 and TKV RNA are not mutually exclusive. Whereas Mef2 is expressed in all follicle cells, TKV is absent only in different populations of follicle cells at different times. Perhaps subtle changes in Mef2 levels can have different effects on tkv expression. For example, at stage 10A, Mef2 is more abundant in the leading CMFC than in the other O-FCs, whereas tkv is not expressed in CMFCs and expressed at a low level in the rest of the follicle cells. Alternatively, Mef2 may be a constitutive repressor of tkv, whereas other tissue-specific factors can counteract Mef2 and induce tkv expression (Mantrova, 1999).

In wild type, tkv expression is dynamic during oogenesis and appears to highlight a specific group of follicle cells, the leading front of the CMFCs. At stage 10A just before the commencement of centripetal migration, these cells form a ring marking the boundary between the oocyte and the nurse cell complex. After stage 10B, this ring of cells migrates inward until it reaches the border cells located at the center of the oocyte anterior. At stage 10A, tkv is expressed in O-FC but not in the leading CMFCs. This pattern is opposite that of the dpp expression pattern, which is highly expressed in the leading CMFCs but not in the rest of the O-FCs. It will be of interest to examine whether or not tissue-specific expression of dpp and tkv in the egg chamber is autoregulated by DPP signaling (Mantrova, 1999).

At stage 10B, tkv is expressed in the ventral half of the CMFC in addition to two short stripes in the dorsal region of the oocyte-associated follicular epithelium. This expression pattern appears to be complementary to that of the Egfr blocker argos, which forms a T-shaped pattern along the dorsal CMFCs and dorsal midline. argos expression is induced by the highest level of Egfr signaling; Egfr in turn, reduces the signaling strength by blocking the interaction between the receptor and its ligands. Thus, the initial graded distribution of Egfr signaling, extending laterally from the anterodorsal midline of the O-FCs, is transformed into two ridges of the Egfr-signaling level just lateral to the dorsal midline. These two ridges define the two lines of O-FCs that ultimately produce the two dorsal appendages. Interestingly, argos expression is diminished in the Mef2 mutant, consistent with the observed mutant egg chambers possessing broad and fused appendages. Although the notion is favored that argos expression is modulated by Mef2 through the action of Tkv, it cannot be ruled out that Mef2 may directly control the transcription of argos (Mantrova, 1999).

In addition to regulating the expression pattern of argos, Mef2 may play a more general role in modulating the Egfr-signaling level. This is suggested by the presence of Mef2 mutant egg chambers with reduced and fused dorsal appendages, a phenotype typical of hypomorphic Egfr-signaling pathway mutants. Indeed, reduced expression of Egfr-signaling components such as rhomboid has been observed in Mef2 mutants. More detailed and expansive studies are needed to elucidate the possible interaction between the Dpp- and Egfr-signaling pathways with Mef2 as a potential mediator (Mantrova, 1999).

Nevertheless, this report does demonstrate that the dpp-expressing CMFCs are poorly defined in D-mef2 mutant egg chambers. CMFCs are responsible for forming the operculum and, together with the border cells, specifying the construction of the micropile. Formation of these structures is also essential to closing the anterior end of the egg chamber. Because Dpp is critical for specifying anterior chorion production, the disrupted patterning of CMFCs in the Mef2 mutant may explain, at least in part, the chorion phenotypes observed (Mantrova, 1999).

One of the pleiotropic functions of scribbler (sbb) is an effect on wing morphogenesis. This function has been addressed by Funakoshi (2001), who shows that sbb shapes the activity gradient of the Dpp morphogen through regulation of thickveins. Drosophila wings are patterned by Decapentaplegic, which is expressed along the anterior and posterior compartment boundary. The distribution and activity of Dpp signaling is controlled in part by the level of expression of its major type I receptor, thickveins. The level of tkv is dynamically regulated by Engrailed and Hedgehog. sbb, termed master of thickveins (mtv) by Funakoshi, downregulates expression of tkv in response to Hh and En. mtv expression is controlled by En and Hh, and is complementary to tkv expression. mtv integrates the activities of En and Hh that shape tkv expression pattern. Thus, mtv plays a key part of regulatory mechanism that makes the activity gradient of the Dpp morphogen (Funakoshi, 2001).

Dpp signaling activity can be visualized by using the antibody against phosphorylated Mothers against dpp (p-Mad): the distribution of the Dpp morphogen activity largely depends on the levels of the Tkv receptor. tkv expression, which is monitored by expression of beta-galactosidase in the tkv-lacZ enhancer trap line, is downregulated by Hh along the A/P border where dpp expression is induced by the same signal. The basal level of tkv is higher in the P compartment than it is in the A compartment. This complex pattern appears to shape the activity gradient of Dpp directly. The p-Mad level is low along the A/P border where tkv is downregulated. The gradient of the p-Mad distribution is steeper in the P compartment than it is in the A compartment, probably because high levels of Tkv limit the movement of Dpp; since the spread of Dpp would be less in the P compartment, its gradient of activity would be expected to be steeper (Funakoshi, 2001).

mtv was identified by characterizing the enhancer trap lines, 1E1 and l(2)k00702, that generate expression patterns largely complementary to that of tkv in wing discs except at the dorsoventral compartment border in the peripheral region, where both genes are expressed at high levels. Distribution of the transcript revealed by in situ hybridization with a probe prepared from the corresponding cDNA is consistent with the pattern of the enhancer trap lines. Only the longer form of bks/sbb/mtv mRNA is predominantly detected in imaginal discs (Funakoshi, 2001).

In order to know whether mtv has a role in regulating tkv, a deletion mutant allele, mtv⁶, was made by imprecise excision of the P-element and used for clonal analysis. It is believed that mtv⁶ is a strong hypomorphic allele, because its transcript can only encode a 19 amino acid polypeptide, which lacks most of putative functional domains of the Mtv protein. In mtv⁶ clones, tkv-lacZ levels are autonomously upregulated indicating that Mtv represses tkv. When a large mtv clone is induced in the area including the A/P border, tkv-lacZ levels become uniform within the clone, suggesting that mtv plays an important role in regulating a dynamic pattern of tkv expression throughout the wing pouch. p-Mad levels are also upregulated in a graded manner. This is consistent with the fact that tkv is derepressed within mtv mutant clones because ectopically induced Tkv upregulates p-Mad levels. No significant changes in dpp transcription levels were observed within mtv mutant clones, thus it is concluded that mtv shapes p-Mad spatial distribution through regulation of Tkv levels (Funakoshi, 2001).

The development of the Drosophila wing is governed by the action of morphogens encoded by decapentaplegic and wingless that promote cell proliferation and pattern the wing. Along the anterior/posterior (A/P) axis, the precise expression of dpp and its receptors is required for the transcriptional regulation of specific target genes. The function of the T-box gene optomotor-blind (omb), a dpp target gene, was analyzed. The wings of omb mutants have two apparently opposite phenotypes: the central wing is severely reduced and shows massive cell death, mainly in the distal-most wing, and the lateral wing shows extra cell proliferation. Genetic evidence is presented that omb is required to establish the graded expression of the Dpp type I receptor encoded by the gene thick veins (tkv) to repress the expression of the gene master of thick veins and also to activate the expression of spalt (sal) and vestigial (vg), two Dpp target genes. optomotor-blind plays a role in wing development downstream of dpp by controlling the expression of its receptor thick veins and by mediating the activation of target genes required for the correct development of the wing. The lack of omb produces massive cell death in its expression domain, which leads to the mis-activation of the Notch pathway and the overproliferation of lateral wing cells (del Alamo Rodriguez, 2004).

Hox control of organ size by regulation of morphogen production and mobility: Ubx restricts Dpp's distribution in the haltere by increasing the amounts of the Dpp receptor, thickveins

Selector genes modify developmental pathways to sculpt animal body parts. Although body parts differ in size, the ways in which selector genes create size differences are unknown. This study investigated how the Drosophila Hox gene Ultrabithorax (Ubx) limits the size of the haltere, which, by the end of larval development, has ~fivefold fewer cells than the wing. It was found that Ubx controls haltere size by restricting both the transcription and the mobility of the morphogen Decapentaplegic (Dpp). Ubx restricts Dpp's distribution in the haltere by increasing the amounts of the Dpp receptor, thickveins. Because morphogens control tissue growth in many contexts, these findings provide a potentially general mechanism for how selector genes modify organ sizes (Crickmore, 2006).

Changes in body part sizes have been critical for diversification and specialization of animal species during evolution. The beaks of Darwin's finches provide a famous example for how adaptation can produce variations in size and shape that allowed these birds to take advantage of specialized ecological niches and food supplies. Sizes also vary between homologous structures within an individual. For example, vertebrate digits and ribs vary in size, likely due to the activities of selector genes such as the Hox genes. Although the control of organ growth by selector genes is likely to be common in animal development, little is known about the mechanisms underlying this control (Crickmore, 2006).

The two flight appendages of Drosophila, the wing and the haltere, provide a classic example of serially homologous structures of different sizes. Halteres, appendages used for balance during flight, are thought to have been modified from full-sized hindwings during the evolution of two-winged flies from their four-winged ancestors. All aspects of haltere development that distinguish it from a wing, including its reduced size, are under the control of the Hox gene Ultra-bithorax (Ubx), which is expressed in all haltere imaginal disc cells but not in wing imaginal disc cells. At all stages of development, haltere and wing primordia (imaginal discs) are different sizes. In the embryo, the wing primordium has about twice as many cells as the haltere primordium. By the end of larval development, the wing disc has ~five times more cells (~50,000) than the haltere disc (~10,000). The wing and haltere appendages will form from the pouch region of these mature discs. The final step that contributes to wing and haltere size differences occurs during metamorphosis, when wing, but not haltere, cells flatten, thus increasing the surface area of the final appendage (Crickmore, 2006).

To confirm that Ubx has a postembryonic role in limiting the size of the haltere disc, Ubx^– clones were generated midway through larval development. Haltere discs–bearing large Ubx^– clones generated at this time become much larger than wild-type discs. Ubx could limit haltere size cell-autonomously by, for example, slowing the cell cycle of haltere cells relative to wing cells. This was tested by comparing the sizes of isolated Ubx^– clones in the haltere with those of their simultaneously generated wild-type twin clones. Contrary to the prediction of a cell-autonomous function for Ubx in size control, Ubx mutant clones did not grow larger than their twins, a result that is consistent with earlier experiments suggesting that wing and haltere cells have similar mitotic rates during development. Hence, Ubx limits the size of the haltere during larval development by modifying pathways that control organ growth cell-nonautonomously (Crickmore, 2006).

In the fly wing, Decapentaplegic (Dpp) [a long-range morphogen of the bone morphogenetic protein (BMP) family] has been shown to promote growth. In both the wing and the haltere, Dpp is produced and secreted from a specialized stripe of cells called the AP organizer, which is induced by the juxtaposition of anterior (A) and posterior (P) compartments, two groups of cells that have separate cell lineages. The AP organizer is a stripe of A cells that are instructed to synthesize Dpp by the short-range morphogen Hedgehog (Hh) secreted from adjacent P compartment cells. Dpp has a positive role in appendage growth. When more Dpp is supplied to the wing disc, either ectopically or within the AP organizer, more cells are incorporated into the developing wing field. Conversely, mutations that reduce the amount of Dpp lead to smaller wings (Crickmore, 2006).

A comparison of the expression patterns of Dpp pathway components in the wing and the haltere demonstrates that Ubx is modifying this pathway. Compared with the wing, the stripe of dpp expression in the haltere was reduced in both its width and intensity, as reported by a lacZ insertion into the dpp locus (dpp-lacZ). There was also a difference in the profile of Dpp pathway activation, as visualized by an antibody that detects P-Mad, the activated form of the Dpp pathway transcription factor Mothers against Dpp (Mad). In the wing, P-Mad staining was low in the cells that transcribe dpp. Immediately anterior and posterior to this activity trough, P-Mad labeling peaked in intensity and then gradually decayed further from the Dpp source, revealing a bimodal activity gradient. In contrast, in the haltere intense P-Mad staining was detected only in a single stripe of cells that overlaps with Dpp-producing cells of the AP organizer (Crickmore, 2006).

Because of the coincidence between dpp transcription and peak P-Mad staining in the haltere, it was hypothesized that Dpp might be less able to move from haltere cells that secrete this ligand. This idea was tested by generating clones of cells in both wing and haltere discs in which the actin5c promoter drove the expression of a green fluorescent protein (GFP)–tagged version of Dpp (Dpp:GFP). By using an extracellular staining protocol to analyze simultaneously generated clones, Dpp:GFP and P-Mad were observed much further from producing cells in the wing than in the haltere. These observations strongly suggest that, compared with the wing, Dpp's mobility—and consequently the range of Dpp pathway activation—is reduced in the haltere (Crickmore, 2006).

Whether the decreased production of Dpp in the haltere contributes to the different pattern of pathway activation observed in this tissue compared with the wing was tested. This is unlikely because, even in haltere discs that overexpress Dpp in its normal expression domain, peak P-Mad staining was still observed close to Dpp-expressing cells. Despite increased dpp expression, no P-Mad activity trough was observed in these haltere discs. Further, although they become larger, these discs remained smaller than wild-type wing discs. It is concluded that the decreased Dpp production in the haltere contributes to its reduced growth, but there must be mechanisms that also limit the extent of Dpp pathway activation, even in the presence of increased Dpp production (Crickmore, 2006).

One way in which Dpp's activation profile can be modified is by varying the production of the type I Dpp receptor, Thick veins (Tkv). In the wing, tkv expression is low within and around the source of Dpp, resulting in low Dpp signal transduction in these cells and robust Dpp diffusion. Low tkv expression in the medial wing is due to repression by both Hh and Dpp. Accordingly, tkv expression is highest in lateral regions of the wing disc, where Hh and Dpp signaling are low. In contrast to the wing, tkv transcription and protein levels were high in all cells of the haltere. Thus, the more restricted Dpp mobility and P-Mad pattern in the haltere may result from a failure to repress tkv medially. To test this idea, all cells of the wing disc were supplied with uniform UAS-tkv⁺ expression, to mimic the haltere pattern. The resulting P-Mad pattern in these wing discs was very similar to that found in the wild-type haltere: The P-Mad trough was gone, and the activity gradient was compacted into a single stripe that coincides with Dpp-producing cells. Conversely, lowering the amount of Tkv in the haltere by expressing an RNA interference (RNAi) hairpin construct directed against tkv (UAS-tkvRNAi) in Dpp-producing cells induced a bimodal pattern of P-Mad staining similar to that of the wild-type wing disc. Thus, different amounts of Tkv result in qualitative differences in the P-Mad profiles of the wing and the haltere (Crickmore, 2006).

It was hypothesized that the more limited pathway activation in the haltere might contribute to its smaller size. If correct, increasing tkv expression in the wing should reduce its size. Adult wings from flies expressing uniform UAS-tkv⁺ were ~30% smaller than control wings; however, wing cell size remained the same. Similar results were seen in staged imaginal discs and when UAS-tkv⁺ expression was limited to the wing and the haltere. Conversely, reducing Tkv amounts by uniformly expressing UAS-tkvRNAi in wings and halteres increased haltere size by 30 to 60%. In a complementary experiment, tkv transcription was reduced in the haltere by expressing a known tkv repressor, master of thickveins (mtv). In this experiment, haltere discs were measured instead of the adult appendage; it was consistently found that the appendage-generating region of these discs increased in size by ~40%. Thus, different amounts of Tkv not only affect Dpp pathway activation but also affect organ size. The fact that manipulating only Tkv production does not fully transform the sizes of these appendages suggests that additional mechanisms, such as the reduced amounts of dpp transcription and the modulation of other morphogen pathways by Ubx, also contribute to size regulation. Consistently, when Dpp production is decreased in wing discs that uniformly express UAS-tkv⁺, wing size was reduced more than it was by either single manipulation (Crickmore, 2006).

Next, how Ubx up-regulates tkv in the haltere was addressed. tkvlacZ expression and amounts of Tkv protein were cell-autonomously reduced in medial Ubx^– clones, whereas lateral Ubx mutant tissue retained high amounts of Tkv. Because tkv is repressed by Dpp and Hh signaling in the wing, these results suggest that, in the haltere, these signals are not able to repress tkv. Consistently, activation of the Dpp pathway by expressing a constitutively active form of Tkv (Tkv^QD) resulted in cell-autonomous tkv-lacZ repression in the wing pouch, whereas repression is not observed in the corresponding region of the haltere disc (Crickmore, 2006).

In Ubx mosaic haltere discs, it was also found that medial Ubx⁺ tissue showed stronger P-Mad staining than Ubx^– tissue at the same distance from the Dpp source. This observation is interpreted as evidence that Ubx⁺ tissue is more effective at trapping and transducing Dpp than Ubx^– tissue because of higher Tkv production in Ubx⁺ cells (Crickmore, 2006).

To further understand the control of tkv by Ubx, the known tkv repressor, mtv, was examined. In medial wing disc cells, mtv expression is approximately complementary to tkv expression, and mtv^– clones in this region of the wing disc cell autonomously derepressed tkv. In the haltere, very low mtv-lacZ expression was detected in the cells that stained strongly for P-Mad, suggesting that mtv is repressed by Dpp in this appendage. Accordingly, strong repression of mtv-lacZ was seen in UAS-tkv^QD-expressing haltere pouch clones, whereas weak or no repression was seen in analogous wing clones. It was also found that, as expected, Ubx^– clones in the medial haltere cell autonomously derepressed mtv-lacZ (Crickmore, 2006).

In the wing, Dpp and mtv are mandatory repressors of tkv: In the absence of either, tkv expression is high. In the haltere in the presence of Ubx, Dpp is a repressor of mtv. Consequently, high levels of these obligate tkv repressors (Dpp signaling and mtv) do not coexist in the haltere, resulting in tkv derepression. Consistent with this model, when mtv expression was forced in the medial haltere, where it coexists with Dpp signaling, it repressed tkv-lacZ. It is noted, however, that Ubx is likely to control tkv through additional means, because mtv mutant wing clones did not derepress tkv-lacZ expression to haltere levels, and ectopic mtv in the haltere did not repress tkv-lacZ expression to the extent seen in the medial wing (Crickmore, 2006).

Because of high Tkv production in the wild-type haltere disc, peak Dpp signal transduction occurs in the AP organizer, the same cells that transduce the Hh signal. Thus, in the haltere, the activity profiles for these two signal transduction pathways coincide with each other. In contrast, low tkv expression in the wing AP organizer results in two peaks of Dpp signaling that are on either side of Hh-transducing cells. This difference will have important consequences for the expression of genes that are targets of both pathways. For example, dpp is activated by Hh and repressed by Dpp signaling. In the haltere, these two conflicting inputs occur in the same cells, possibly contributing to reduced dpp expression compared with the wing. Ubx^– clones cell-autonomously up-regulated dpp-lacZ in the haltere. To test whether Ubx lowers dpp transcription in part by aligning Dpp and Hh signaling, uniform UAS-tkv⁺ was expressed in the dorsal half of the wing disc. As a result, in this region of the wing disc both signals peaked in the same cells, and dpp-lacZ expression was reduced compared with the ventral half of these wing discs. Conversely, expressing tkvRNAi in dorsal haltere cells increased dpplacZ expression. Thus, Ubx reduces dpp transcription in part by changing where peak Dpp signaling occurs in the disc. Ubx is likely to reduce dpp expression in additional ways, because increasing tkv expression does not lower dpplacZ expression to that observed in wild-type haltere. Nevertheless, varying the relative spatial relationships between signal transduction pathways is a potentially powerful mechanism for modifying the outputs from commonly used pathways. It is suggested that selector genes may work through molecules that control ligand distribution to vary the spatial relationships between these and other signal transduction pathways in diverse contexts during development (Crickmore, 2006).

The finding that increased tkv expression results in decreased dpp transcription reveals an unexpected link between Dpp mobility and Dpp production. Because of this link, the above experiments do not discriminate between growth effects due to differences in Dpp mobility per se as opposed to secondary consequences on Dpp production. To distinguish between these scenarios, use was made of a compartment-specific Ubx regulatory allele, posterior bithorax (pbx), that lacks detectable Ubx in the P compartment when paired with a Ubx null allele but still has normal Ubx expression in the A compartment. Consequently, in pbx/Ubx^– haltere discs, the P compartment increased in size such that the P:A size ratio was 1.45; the P:A ratio of +/Ubx^– haltere discs was ~0.35. It is suggested that Dpp more readily diffuses into and through the P compartments of pbx/Ubx^– discs because of the wing-like expression pattern of tkv and that this wing-like diffusion results in its robust growth (Crickmore, 2006).

To test whether differences in Tkv-regulated Dpp diffusion affect tissue growth independently of an effect on Dpp production, the consequences of expressing UAS-tkv⁺ uniformly in pbx/Ubx^– haltere discs were examined. If Tkv's effect on growth is mediated only by lowering Dpp production, both compartments should be reduced in size and thus maintain the same size ratio. However, if reducing Dpp mobility directly affects growth, the P compartment should be reduced in size more than the A compartment, which, in pbx/Ubx^– discs, already has high tkv expression. It was found that expressing uniform tkv⁺ in pbx/Ubx^– discs decreased the size of the P compartment more than the A compartment, resulting in a P:A ratio of 0.83. Because uniform tkv⁺ returned the P:A ratio back to the wild-type ratio by ~56%, these results suggest that this single variable is sufficient to provide ~50% rescue of the size of an otherwise Ubx mutant P compartment (Crickmore, 2006).

This study has investigated the mechanism underlying a classic yet poorly understood phenomenon in biology: how size variations are genetically programmed in animal development. Many experiments show that organ size is not governed by counting cell divisions but instead depends on disc-intrinsic yet cell-nonautonomous mechanisms, possibly relying on morphogen signaling. The results support this idea by showing that alterations in a morphogen gradient contribute to size differences between appendages. In the example investigated here, Ubx limits the size of the haltere by reducing both Dpp production and Dpp mobility. Moreover, both of these effects are due, in part, to higher tkv expression in the medial haltere. In many morphogen systems, the receptors themselves have been shown to control the distribution of the ligand and, consequently, pathway activation. This study shows that a selector gene exploits this phenomenon to modify organ size (Crickmore, 2006).

Although the mechanism by which Dpp controls proliferation is not fully understood, recent results argue that, in the medial wing disc, cells may compare the amount of Dpp transduction with their neighbors, whereas lateral cells proliferate in response to absolute Dpp levels. The results suggest several ways in which the altered Dpp gradient in the haltere could limit its growth. First, proliferation of lateral haltere cells may be limited because they perceive less Dpp. Second, the narrower Dpp gradient results in fewer cells exposed to the gradient in the medial haltere. Another notable difference is that, because there are two peaks of Dpp signaling in the wing but only one in the haltere, the wing has four distinct slopes whereas the haltere has only two. The less complex Dpp activity landscape of the haltere may also contribute to its reduced growth (Crickmore, 2006).

On the basis of these results, it is suggested that altering the shape and intensity of morphogen gradients may be a general mechanism by which selector genes affect tissue sizes in animal development. Consistent with this view, wingless (wg), another long-range morphogen in the wing, is partially repressed in the haltere. Intriguingly, some of the size and shape differences in the beaks of Darwin's finches are controlled by alterations in the production of the Dpp ortholog BMP4. The results suggest that differences in the diffusion of this ligand may also contribute to the range of beak morphologies that have evolved in these species (Crickmore, 2006).

Targets of Activity

In the embryonic midgut, mutations affecting thickveins block the expression of two decapentaplegic-responsive genes, dpp and labial (Penton, 1994).

While maternal tkv product allows largely normal dorsoventral patterning of the embryo, zygotic tkv activity is indispensable for the dorsal closure of the embryo after germ band retraction. Furthermore, tkv activity is crucial for patterning the visceral mesoderm; in the absence of functional tkv gene product, visceral mesoderm parasegment 7 cells fail to express Ultrabithorax, but instead accumulate Antennapedia protein. The TKV receptor is therefore involved in delimiting the expression domains of homeotic genes in the visceral mesoderm.

Interestingly, tkv mutants fail to establish a proper tracheal network. Tracheal braches formed by cells migrating in dorsal or ventral directions are absent in tkv mutants. The requirements for tkv in dorsal closure, visceral mesoderm and trachea development assign novel functions to DPP or a closely related member of the TGF beta superfamily (Affolter, 1994).

Decapentaplegic, through its receptors Thickveins and Punt targets optimotor blind and spalt transcription in the wing imaginal disc. The range of DPP action is wide, affecting spalt and omb expression on both sides of the anterior-posterior compartment boundary. The finding of an extended range of action for DPP is unexpected, yet DPP diffusion away from its site of expression may be limited by its tendency to be sequestered by components of the extracellular matrix. spalt and omb respond differently to the DPP concentration gradient, with omb showing a wider range of response due to its greater sensitivity to low DPP concentrations (Nellen, 1996)

brinker expression in the imaginal discs is not uniform but shows complementarity to regions of Dpp signaling. In wing discs, brk is highly expressed in lateral regions that are distant from the Dpp source in the center of the disc. In leg discs, brk expression is lowest in the dorsal compartment, which is specified by high levels of Dpp signaling. Double stainings for brk-lacZ and Omb protein demonstrate the complementarity between high levels of brk transcription and the expression of a low-threshold target gene of Dpp in wing and leg imaginal discs. They also reveal a narrow zone of overlap between low brk levels and omb expression in the wing pouch, suggesting that brk expression extends into regions of low-level Dpp signaling. In this region of overlap between Omb and brk, brk levels are declining in a graded fashion and become undetectable at positions where Sal expression starts. The complementarity between brk expression and regions of Dpp signaling may reflect a negative regulation of brk by Dpp. Consistent with this view, clones of mutant cells missing the Dpp receptor Tkv express high levels of brk, irrespective of their location within the wing pouch. Thus, brk expression would occur evenly throughout the wing pouch in the absence of a Dpp gradient emanating from the center of the disc. An important function of Dpp signaling in the wing disc might be to generate the asymmetric distribution of a repressor (such as brk) of Dpp's target genes (Jazwinska, 1999).

The identification of mutations in Tgfbeta-60A as dominant enhancers of tkv 6 in the imaginal discs raises the possibility that Tgfbeta-60A is required for optimal signaling by the dpp pathway. To determine if there is a general requirement for Tgfbeta-60A in dpp signaling, the effects of Tgfbeta-60A mutations were examined on dpp signaling in the visceral mesoderm where both dpp and Tgfbeta-60A are expressed. dpp is expressed in two discrete domains in the visceral mesoderm. The anterior domain of dpp coincides with the gastric caecae primordia, which are immediately anterior to the expression domain of Sex combs reduced (Scr) in parasegment (ps) 4. The failure to initiate dpp expression in ps3 in dpp shv mutants results in anterior expansion of Scr expression and arrested outgrowth of the gastric caecae, indicating a role for dpp in repressing Scr in ps3. tkv 6 homozygotes are homozygous viable, so it is not surprising that all the midgut gene expression patterns examined are essentially normal. Scr expression in tkv 6 and Tgfbeta-60A mutants is normal. However, in tkv 6 and Tgfbeta-60A double mutants, the Scr expression extends anteriorly into ps3 as it does in dpp shv mutants, suggesting that Tgfbeta-60A activity is required in ps3 for optimal dpp signaling (Chen, 1998).

During Drosophila embryogenesis the two halves of the lateral epidermis migrate dorsally over a surface of flattened cells, the amnioserosa, and meet at the dorsal midline in order to form the continuous sheet of the larval epidermis. During this process of epithelial migration, known as dorsal closure, signaling from a Jun-amino-terminal-kinase cascade causes the production of the secreted Tgf-beta-like ligand, Decapentaplegic. Binding of Decapentaplegic to the putative Tgf-beta-like receptors Thickveins and Punt activates a Tgf-beta-like pathway that is also required for dorsal closure. Mutations in genes involved in either the Jun-amino-terminal-kinase cascade or the Tgf-beta-like signaling pathway can disrupt dorsal closure. Although these pathways are linked they are not equivalent in function. Signaling by the Jun-amino-terminal-kinase cascade may be initiated by the small Ras-like GTPase Drac1 and acts to assemble the cytoskeleton and specify the identity of the first row of cells of the epidermis prior to the onset of dorsal closure. Signaling in the Tgf-beta-like pathway is mediated by Dcdc42, and acts during the closure process to control the mechanics of the migration process, most likely via its putative effector kinase DPAK (Ricos, 1999).

Thick veins is likely to target p38b, a MAP kinase implicated in Dpp signal transduction. Two Drosophila homologs of p38, Mpk2 (also known as p38a or simply p38) and p38b, have been identified on the basis of their homology to mammalian p38 and to one another. p38b is maternally expressed and is present ubiquitously during embryonic development (Han, 1998). The chromosomal region around the p38b locus has been well characterized genetically. However, a p38b transgene was unable to rescue any of the known mutations mapping to this region. Likewise, attempts to isolate a mutant of p38b were unsuccessful. These failures are possibly due to the functional redundancy of the two p38 homologs. Various alternative methods were therefore use to interfere with endogenous p38(s) in order to investigate its function. A dominant-negative allele of p38b, designated D-p38b^DN, was generated by replacing the Thr-183 of the MAPKK target site with Ala, analogous to the change in ERK2 that produces a dominant-negative allele (Adachi-Yamada, 1999).

Two lines were prepared which express D-p38b^DN at different levels: D-p38b^DN-S (Strong), which expresses high levels, and D-p38b^DN-W (Weak), which expresses low levels. When two copies of the D-p38b^DN-S transgene are expressed in the wing, a certain fraction of adult flies that escape death exhibit ectopic vein fragments around the end of the longitudinal vein L2 and a reduction in the distance between L4 and L5. Both of these features have also been observed with some mutant alleles of decapentaplegic and thick veins. This wing phenotype is rescued by coexpression of the wild type p38b⁺ transgene. When two copies of the D-p38b^DN-S transgene are weakly expressed in the wing of a dpp mutant, the vein phenotype of dpp is strongly enhanced. These phenotypes suggest the involvement of Drosophila p38(s) in Dpp function in the early and late stages of wing pattern development. Dpp is known to play a dual role during wing development, acting as a morphogen and mitogen at early stages, while activating vein differentiation at later stages (Adachi-Yamada, 1999).

To examine whether p38(s) functions in the Dpp signaling pathway, the genetic interaction was examined between p38(s) and a constitutively active mutant of Tkv (Tkv^CA). Two classes of tkv^CA insertions, tkv^CA-S (Strong) and tkv^CA-W (Weak), were used. When tkv^CA-S is expressed, normal wing venation is severely distorted and extensive production of fragments of vein material is observed. The abdominal-cuticle pattern also appears irregular. This wing phenotype suggests that Tkv^CA may influence Dpp action during vein formation. Ectopic coexpression of dpp⁺ and tkv⁺ causes similar phenotypes, indicating that these Tkv^CA-induced aberrations are indeed the result of an increase in Dpp signaling. It was thus expected that reducing the levels of downstream components would suppress tkv^CA. In fact, reducing by one-half the gene dosage of Mothers against dpp (Mad), a well-documented Dpp-signaling factor, significantly suppresses the tkv^CA wing phenotype (Adachi-Yamada, 1999).

The effect of the imidazole compound SB203580, a p38 inhibitor, was tested on the tkv^CA wing phenotype. SB203580 has been reported to inhibit both p38a and p38b (Z. Han, 1998), and penetration of various imidazole compounds through the insect epidermis is well known. Exposure of growing larvae to SB203580 indeed results in suppression of the phenotype. Tests were performed to see whether endogenous p38 genes are involved in the tkv^CA wing phenotype by reducing endogenous gene dosage using chromosomal hemizygosity. Interestingly, reduction of p38b suppresses the tkv^CA wing phenotype, while reduction of p38a is not effective. Suppression by reduction of the p38b gene dosage is abrogated by the introduction of a transgene for p38b⁺. Thus, the gene within the deficiency that suppresses tkv^CA is indeed p38b. These results suggest that p38b plays a major role in this morphogenetic process, and attention was focussed on this gene in further analyses (Adachi-Yamada, 1999).

Antisense RNA can often be used to mimic the effects of mutation. When antisense p38d RNA is coexpressed with Tkv^CA-S, the tkv^CA-S phenotype is markedly suppressed. Four of five independently established p38b^antisense lines showed significant suppression. Suppression affects the various pleiotropic phenotypes associated with the tkv^CA allele, including wing blade morphology, abdominal-cuticle morphology, and wing posture. Similar suppression of the tkv^CA phenotype is also achieved by coexpression of p38b^DN-W in a dose-dependent manner. This suppression is greater when the strong dominant negative p38b (p38b^DN-S) is coexpressed instead of p38b^DN-W. Furthermore, this suppression is abrogated by simultaneous coexpression of wild type p38d, demonstrating that p38b^DN and wild type p38b competitively sequester endogenous factors essential to signaling. These results suggest either that p38b functions downstream of Tkv or that inhibition of p38b causes a reduction in endogenous dpp activity. Since the expression pattern of dpp in the developing wing of the D-p38b^DN-S producer has been found to be indistinguishable from that of the wild type, and reduction in the gene dosage of dpp is not effective in suppressing the tkv^CA phenotype, it is concluded that p38b does not affect Dpp production per se but rather acts as a downstream component of the Dpp-Tkv signaling pathway, operating late in wing development. The fact that the weak phenotype of tkv^CA-W is significantly enhanced by wild type p38b is also consistent with this conclusion (Adachi-Yamada, 1999).

The effect of p38b on optomotor blind transcription was examined in order to study the involvement of p38b in the Dpp signaling pathway. The omb gene encodes a T-box family transcription factor, and its expression in the wing imaginal disc is dependent on early Dpp-Tkv signaling. In the wing discs of flies ectopically expressing tkv^CA-5, the omb expression domain is greatly expanded and overgrowth of the disc is evident. Expression of p38b^DN or p38b^antisense markedly suppresses both omb expression and disc overgrowth. Induction of omb in the tkv^CA-expressing clones in regions outside those where dpp is expressed is also inhibited by coexpression of p38b^DN, consistent with the possibility that p38b functions downstream of Tkv. Furthermore, while p38b^DN slightly affects omb expression in a tkv⁺ genetic background, the wing phenotype of a hypomorphic omb allele is clearly enhanced by expression of p38b^DN or p38b^antisense, as observed in the wing phenotype of severe omb alleles. These results suggest that p38b is also involved in early Dpp-Tkv signaling in wing development to activate omb transcription. Evidence is presented that p38b, or possibly both p38s, are phosphorylated in vivo downstream of ectopically expressed constitutively active Tkv (Adachi-Yamada, 1999).

To investigate whether p38b is activated by Tkv signaling, a preliminary biochemical characterization of p38b was carried out. Immediately after heat treatment of flies, the amount of p38b immunoprecipitated by anti-p-Tyr antibody was found to increase considerably, demonstrating that p38b is tyrosine phosphorylated following heat shock, like mammalian p38. The site of tyrosine phosphorylation is expected to be in the 'activation loop' region recognized by MAPKK, as is the case in mammalian p38. Thus, a test was performed to see whether an anti-phospho-p38 (anti-p-p38) antibody raised against a phosphorylated peptide from the activation loop of mammalian p38 could cross-react with p38b. This anti-p-p38 antibody detects a protein with a calculated size of 42 kDa whose amount increases immediately after heat shock. This protein is also more abundant in the flies overproducing p38b regardless of heat treatment. Therefore, it has been concluded that anti-phospho-p38 can cross-react with the phosphorylated from of p38b and can be used to assay recombinant p38b phosphorylation in vitro. Treatment of p38b with recombinant human MKK6, a MAPKK that activates p38, causes a marked increase in the level of p38b, as detected with anti-phospho-Tyr and anti-p-p38 antibodies, and a drastic increase in the level of Drosophila p38-dependent phosphorylation of recombinant human activating transcription factor 2 (ATF2), a physiological substrate for mammalian p38. The correlation between the phosphorylation state and kinase activity of p38b indicates that the anti-p-p38 antibody recognizes the active form of p38b. This allowed activation of p38b by Tkv^CA to be examined in vivo. The amount of active p38b was found to be slightly but significantly higher in larvae carrying ectopically expressed tkv^CA relative to that in wild-type Canton-S larvae. However, it has been reported that p38a protein expressed in yeast, which was presumed to have the same molecular mass as p38b, is also recognized by anti-p-p38 antibody. It is therefore possible that p38b, or both D-p38's, may be activated by Tkv signaling in vivo (Adachi-Yamada, 1999).

The Drosophila wing is divided into two compartments along its anteroposterior (A/P) axis. The compartment boundary between these regions serves as the source of an organizing activity that patterns both anterior and posterior compartments. This activity is mediated, at least in part, by the long-range action of Dpp, which is expressed by cells along the A/P compartment boundary. Dpp is thought to act as a morphogen to inform target cells of their position along the A/P axis, but as yet, little is known about how cells interpret the distribution of Dpp protein. An enhancer trap screen was conducted to identify genes whose transcription is controlled by Dpp. Two enhancer trap lines in the same locus (89E/F), P1883 and 1(3)1E4, were identified whose expression patterns are similar to those of Dpp during embryonic and imaginal development. The gene whose expression is reflected in these enhancer traps has been named Daughters against dpp (Dad). In these enhancer trap lines, beta-galactosidase is expressed in a wide stripe that straddles the A/P compartment boundary of the imaginal discs, in contrast to Dpp, whose expression is confined to the anterior side. This pattern of expression suggests that Dad expression is positively regulated by the secreted Dpp molecule. To test whether Dad responds to Dpp signaling, its expression has been examined in P1883 wing discs in which a UAS-dpp transgene was transcribed in a ring around a wing pouch under the control of a Gal4 driver. Ectopic Dpp expression results in abnormally large discs and in ectopic expression of Dad in a broad ring around a wing pouch. Identical results were obtained when another transgene was used -- UAS-tkv ^Q253D -- which encodes a constitutively active form of the major type-I Dpp receptor, Thick veins. In addition, expression of Dad is not detected in cells that lack a functional Tkv Dpp receptor. These results indicate that Dpp signaling is necessary and sufficient for Dad expression in the developing wing (Tsuneizumi, 1997).

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