Subtype determination of Drosophila embryonic external sensory organs by redundant homeo box genes BarH1 and BarH2

The human BARX2 gene: genomic structure, chromosomal localization, and single nucleotide polymorphisms

The BARX genes 1 and 2 are Bar class homeobox genes expressed in craniofacial structures during development. In this report, we present the genomic structure, chromosomal localization, and polymorphic markers in BARX2. The gene has four exons, ranging in size from 85 to 1099 bp. BARX2 is localized on human chromosome 11q25, as determined by radiation hybrid mapping. In the mouse, Barx2 is coexpressed with Pitx2 in several tissues. Based on the coexpression, BARX2 was assumed to be a candidate gene for those cases of Rieger syndrome that cannot be associated with mutations of PITX2. Mutations in PITX2 cause some cases of Rieger syndrome, an autosomal dominant disorder affecting eyes, teeth, and umbilicus. DNA from Rieger patients was subjected to single-strand conformation polymorphism screening of the BARX2 coding region. Three single nucleotide polymorphisms were found in a normal population, although no etiologic mutations were detectable in over 100 cases of Rieger syndrome or in individuals with related ocular disorders.

Prospero distinguishes sibling cell fate without asymmetric localization in the Drosophila adult external sense organ lineage

The adult external sense organ precursor (SOP) lineage is a model system for studying asymmetric cell division. Adult SOPs divide asymmetrically to produce IIa and IIb daughter cells; IIa generates the external socket (tormogen) and hair (trichogen) cells, while IIb generates the internal neuron and sheath (thecogen) cells. Here we investigate the expression and function of prospero in the adult SOP lineage. Although Prospero is asymmetrically localized in embryonic SOP lineage, this is not observed in the adult SOP lineage: Prospero is first detected in the IIb nucleus and, during IIb division, it is cytoplasmic and inherited by both neuron and sheath cells. Subsequently, Prospero is downregulated in the neuron but maintained in the sheath cell. Loss of prospero function leads to ‘double bristle’ sense organs (reflecting a IIb-to-IIa transformation) or ‘single bristle’ sense organs with abnormal neuronal differentiation (reflecting defective IIb development). Conversely, ectopic prospero expression results in duplicate neurons and sheath cells and a complete absence of hair/socket cells (reflecting a IIa-to-IIb transformation). We conclude that (1) despite the absence of asymmetric protein localization, prospero expression is restricted to the IIb cell but not its IIa sibling, (2) prospero promotes IIb cell fate and inhibits IIa cell fate, and (3) prospero is required for proper axon and dendrite morphology of the neuron derived from the IIb cell. Thus, prospero plays a fundamental role in establishing binary IIa/IIb sibling cell fates without being asymmetrically localized during SOP division. Finally, in contrast to previous studies, we find that the IIb cell divides prior to the IIa cell in the SOP lineage.

An essential role for the Drosophila Pax2 homolog in the differentiation of adult sensory organs

The adult peripheral nervous system of Drosophila includes a complex array of mechanosensory organs (bristles) that cover much of the body surface of the fly. The four cells (shaft, socket, sheath, and neuron) which compose each of these organs adopt distinct fates as a result of cell-cell signaling via the Notch (N) pathway. However, the specific mechanisms by which these cells execute their conferred fates are not well understood. Here we show that D-Pax2, the Drosophila homolog of the vertebrate Pax2 gene, has an essential role in the differentiation of the shaft cell. In flies bearing strong loss-of-function mutations in the shaven function of D-Pax2, shaft structures specifically fail to develop. Consistent with this, we find that D-Pax2 protein is expressed in all cells of the bristle lineage during the mitotic (cell fate specification) phase of bristle development, but becomes sharply restricted to the shaft and sheath cells in the post-mitotic (differentiative) phase. Two lines of evidence described here indicate that D-Pax2 expression and function is at least in part downstream of cell fate specification mechanisms such as N signaling. First, we find that the lack of late D-Pax2 expression in the socket cell (the sister of the shaft cell) is controlled by N pathway activity; second, we find that loss of D-Pax2 function is epistatic to the socket-to-shaft cell fate transformation caused by reduced N signaling. Finally, we show that misexpression of D-Pax2 is sufficient to induce the production of ectopic shaft structures. From these results, we propose that D-Pax2 is a high-level transcriptional regulator of the shaft cell differentiation program, and acts downstream of the N signaling pathway as a specific link between cell fate determination and cell differentiation in the bristle lineage.

Bar homeobox genes are latitudinal prepattern genes in the developing Drosophila notum whose expression is regulated by the concerted functions of decapentaplegic and wingless

In Drosophila notum, the expression of achaete-scute proneural genes and bristle formation have been shown to be regulated by putative prepattern genes expressed longitudinally. Here, we show that two homeobox genes at the Bar locus (BarH1 and BarH2) may belong to a different class of prepattern genes expressed latitudinally, and suggest that the developing notum consists of checker-square-like subdomains, each governed by a different combination of prepattern genes. BarH1 and BarH2 are coexpressed in the anterior-most notal region and regulate the formation of microchaetae within the region of BarH1/BarH2 expression through activating achaete-scute. Presutural macrochaetae formation also requires Bar homeobox gene activity. Bar homeobox gene expression is restricted dorsally and posteriorly by Decapentaplegic signaling, while the ventral limit of the expression domain of Bar homeobox genes is determined by wingless whose expression is under the control of Decapentaplegic signaling.

Cloning, sequencing and expression of a novel homeobox gene AxNox-1 from the Mexican axolotl

We have cloned and sequenced a cDNA containing a homeobox gene, AxNox-1, from a stage 18 axolotl embryonic cDNA library which shows only moderate levels of similarity to other known homeobox genes. The nucleotide sequence of the cDNA has an open reading frame for 335 amino acids and besides the homeodomain, there is an acidic domain and a proline-rich domain present in the protein. The transcripts for this gene are detectable at stage 4 of embryonic development and, hence, there is a good possibility that the transcripts are maternally contributed. Expression levels for AxNox-1 reach maximum levels by stage 12 of development and thereafter decline to very low levels by stage 25. High levels of the transcript for AxNox-1 are later found in the brains of both neotenous and metamorphosing adult axolotls. Low amounts of the message are also found to be present in a number of other organs that were tested. In situ hybridization studies on whole mounts and sections suggest that this gene is expressed predominantly in neural tissue during development.

Specification of primary pigment cell and outer photoreceptor fates by BarH1 homeobox gene in the developing Drosophila eye

In the developing Drosophila eye, BarH1 and BarH2, paired homeobox genes expressed in R1/R6 outer photoreceptors and primary pigment cells, are essential for normal eye morphogenesis. Here, we show evidence that BarH1 ectopically expressed under the control of the sevenless enhancer (sev-BarH1) causes two types of cone cell transformation: transformation of anterior/posterior cone cells into outer photoreceptors and transformation of equatorial/polar cone cells into primary pigment cells. sev-BarH1repressed the endogenous expression of the rough homeobox gene in R3/R4 photoreceptors, while the BarH2 homeobox gene was activated by sev-BarH1 in an appreciable fraction of extra outer photoreceptors. In primary pigment cells generated by cone cell transformation, the expression of cut, a homeobox gene specific to cone cells, was completely replaced with that of Bar homeobox genes. Extra outer photoreceptor formation was suppressed and enhanced, respectively, by reducing the activity of Ras/MAPK signaling and by dosage reduction of yan, a negative regulator of the pathway, suggesting interactions between Bar homeobox genes (cell fate determinants) and Ras/MAPK signaling in eye development.

Mammalian BarH homologue is a potential regulator of neural bHLH genes

Vertebrate neurogenesis involves sequential actions of transcription factors. neurogenins, encoding Atonal-related bHLH transcription factors, function as neuronal determination genes in Xenopus. neurogenins and antother bHLH factor gene, Mash1, are expressed in distinct subsets or areas of cells giving rise to neurons, suggesting that these genes play important roles to generate distinct populations of neurons. A mammalian homologue of BarH (MBH1) is expressed in a complementary pattern to Mash1 expression in the developing nervous system like neurogenins. Forced expression of MBH1 down-regulates expression of Mash1 and up-regulates neurogenin2/Math4A, a member of neurogenins, in P19 cells during neuronal differentiation. This suggests that MBH1 is a potential regulator of mammalian neural bHLH genes, thereby establishing distinct pathways of neuronal differentiation.

The Drosophila sanpodo gene controls sibling cell fate and encodes a tropomodulin homolog, an actin/tropomyosin-associated protein

Notch signaling is required in many invertebrate and vertebrate cells to promote proper cell fate determination. Mutations in sanpodo cause many different neuronal peripheral nervous system precursor cells to generate two identical daughter neurons, instead of a neuron and sibling cell. This phenotype is similar to that observed when Notch function is lost late in embryonic development and opposite to the numb loss-of-function phenotype. Genetic interaction studies show that sanpodo is epistatic to numb. sanpodo encodes a homolog of tropomodulin, an actin/tropomyosin-associated protein. Loss of sanpodo leads to an aberrant F-actin distribution and causes differentiation defects of actin-containing sensory structures. Our data suggest that an actin-based process is involved in Notch signaling.

Pattern, time of birth, and morphogenesis of sensillum progenitors in Drosophila

In this paper we describe the spatiotemporal pattern of sensillum progenitors (SOPs), as well as the way in which these cells segregate from the ectoderm and proliferate. The birthdate of SOPs was determined by applying short heat pulses to embryos carrying the Nintra construct [Struhl et al. (1993), Cell, 74:331-345] which allows the overexpression of the active Notch protein at defined developmental stages and thereby eliminates SOPs which would normally segregate during these stages. Our results show that sensillum progenitors appear in several waves which to some degree respect sensillum modality, as well as dorsoventral sensillum location. The four early SOPs (stage 10) give rise exclusively to multiply innervated sensilla, chordotonal organs, and some multidendritic neurons. The second wave (early stage 11) produces the remaining chordotonal organs, some multidendritic neurons, and the dorsal singly innervated mechanosensilla. The third wave (late stage 11), in a dorsal-to-ventral succession, gives rise to the lateral and ventral singly innervated hair and papilla sensilla. Labeling developing SOPs with specific markers demonstrates that only progenitors of subepidermally located chordotonal organs and multidendritic neurons delaminate, whereas progenitors of external sensilla are born and proliferate within the ectodermal layer.

Structure and spatial pattern of the sensilla of the body segments of insect larvae

We describe the types and patterns of sensilla present on the thorax and abdomen of newly hatched larvae of representative species of several insect orders, among them Saltatoria, Mantodea, Blattaria, Heteroptera, Lepidoptera, and Diptera. Sensilla of non-Dipteran species almost exclusively comprise mechanoreceptive hairs or bristles (trichoid sensilla) of various sizes and numbers. In higher Dipterans, peg sensilla (sensilla basiconica, sensilla coeloconica) and so-called papilla sensilla predominate. The pattern of early larval sensilla falls into three main classes, which can be described as 1) fixed pattern, 2) variable pattern, and 3) variable pattern with fixed elements. In larvae exhibiting a fixed sensillum pattern (found in all Dipteran species investigated), sensilla are invariant in number; they are precisely placed in relationship to each other and typically form a single row behind the middle of each segment. A variable pattern (common in most insect groups) typically consists of several rows of relatively evenly spaced sensilla encircling the middle of each segment. In animals with a variable pattern including fixed elements, some sensilla, recognizable by their size or shape, are precisely placed, whereas other sensilla surrounding them are variable.

The Pax2 homolog sparkling is required for development of cone and pigment cells in the Drosophila eye

A new Drosophila Pax gene, sparkling (spa), implicated in eye development, was isolated and shown to encode the homolog of the vertebrate Pax2, Pax5, and Pax8 proteins. It is expressed in the embryonic nervous system and in cone, primary pigment, and bristle cells of larval and pupal eye discs. In spa(pol) mutants, a deletion of an enhancer abolishes Spa expression in cone and primary pigment cells and results in a severely disturbed development of non-neuronal ommatidial cells. Spa expression is further required for activation of cut in cone cells and of the Bar locus in primary pigment cells. We suggest close functional analogies between Spa and Pax2 in the development of the insect and vertebrate eye.

Genetic basis of the formation and identity of type I and type II neurons in Drosophila embryos

The embryonic peripheral nervous system of Drosophila contains two main types of sensory neurons: type I neurons, which innervate external sense organs and chordotonal organs, and type II multidendritic neurons. Here, we analyse the origin of the difference between type I and type II in the case of the neurons that depend on the proneural genes of the achaete-scute complex (ASC). We show that, in Notch- embryos, the type I neurons are missing while type II neurons are produced in excess, indicating that the type I/type II choice relies on Notch-mediated cell communication. In contrast, both type I and type II neurons are absent in numb- embryos and after ubiquitous expression of tramtrack, indicating that the activity of numb and the absence of tramtrack are required to produce both external sense organ and multidendritic neural fates. The analysis of string- embryos reveals that when the precursors are unable to divide they differentiate mostly into type II neurons, indicating that the type II is the default neuronal fate. We also report a new mutant phenotype where the ASC-dependent neurons are converted into type II neurons, providing evidence for the existence of one or more genes required for maintaining the alternative (type I) fate. Our results suggest that the same mechanism of type I/type II specification may operate at a late step of the ASC-dependent lineages, when multidendritic neurons arise as siblings of the external sense organ neurons and, at an early step, when other multidendritic neurons precursors arise as siblings of external sense organ precursors.

Requirements of DFR1/Heartless, a mesoderm-specific Drosophila FGF-receptor, for the formation of heart, visceral and somatic muscles, and ensheathing of longitudinal axon tracts in CNS

DFR1 encodes a mesoderm-specific fibroblast growth factor receptor in Drosophila. Here, we identified and characterized a protein-null mutant of DFR1 and examined DFR1 expression in embryos using anti-DFR1 antibody. Mutant phenotypes were completely rescued by a genomic fragment from the DFR1 locus. After invagination, mesodermal cells expressing DFR1 undergo proliferation and spread out dorsally to form a monolayer beneath the ectoderm. In mutant embryos, however, the mesoderm is not capable of extending to the normal dorsal limit and consequently mesodermal cells fail to receive ectodermal signals and thus rendered incapable of differentiating into primordia for the heart, visceral and somatic muscles. DFR1 is also required for normal development of the central nervous system. The absence of DFR1 resulted in the failure of longitudinal glia to enwrap longitudinal axon tracts. DFR1 mutant phenotypes were partially mimicked by the targeted expression of activated Yan, thus demonstrating the MAP kinase pathway to be involved in differentiation of mesoderm.

Barx2, a new homeobox gene of the Bar class, is expressed in neural and craniofacial structures during development

Homeobox genes are regulators of place-dependent morphogenesis and play important roles in controlling the expression patterns of cell adhesion molecules (CAMs). To identify proteins that bind to a regulatory element common to the genes for two neural CAMs, Ng-CAM and L1, we screened a mouse cDNA expression library with a concatamer of the sequence CCATTAGPyGA and found a new homeobox gene, which we have called Barx2. The homeodomain encoded by Barx2 is 87% identical to that of Barx1, and both genes are related to genes at the Bar locus of Drosophila melanogaster. Barx1 and Barx2 also encode an identical stretch of 17 residues downstream of the homeobox; otherwise, they share no appreciable homology. In vitro, Barx2 stimulated activity of an L1 promoter construct containing the CCATTAGPyGA motif but repressed activity when this sequence was deleted. Localization studies showed that expression of Barx1 and Barx2 overlap in the nervous system, particularly in the telencephalon, spinal cord, and dorsal root ganglia. Barx2 was also prominently expressed in the floor plate and in Rathke's pouch. During craniofacial development, Barx1 and Barx2 showed complementary patterns of expression: whereas Barx1 appeared in the mesenchyme of the mandibular and maxillary processes, Barx2 was observed in the ectodermal lining of these tissues. Intense expression of Barx2 was observed in small groups of cells undergoing tissue remodeling, such as ectodermal cells within indentations surrounding the eye and maxillo-nasal groove and in the first branchial pouch, lung buds, precartilagenous condensations, and mesenchyme of the limb. The localization data, combined with Barx2's dual function as activator and repressor, suggest that Barx2 may differentially control the expression of L1 and other target genes during embryonic development.

Canalization: a molecular genetic perspective

The phenomenon of canalization--the genetic capacity to buffer developmental pathways against mutational or environmental perturbations--was first characterized in the late 1930s and early 1940s. Despite enormous subsequent progress in understanding the nature of the genetic material and the molecular basis of gene expression, there have been few attempts to interpret the classical work on canalization in molecular genetic terms. Some recent findings, however, bear on one form of canalization, 'genetic canalization', the stabilization of development against mutational effects. These data indicate that co-expressed paralogous genes can function as mutual 'back-up' elements in developmental processes. Paralogues, however, are far from the only basis of canalization: other genetic sources can be readily envisaged and some of these are described here. The evolutionary questions about genetic canalization and the mechanistic questions about developmental instability that still need to be addressed are also briefly discussed.

Defects in sensory and autonomic ganglia and absence of locus coeruleus in mice deficient for the homeobox gene Phox2a

Phox2a is a vertebrate homeodomain protein expressed in subsets of differentiating neurons. Here, we show that it is essential for proper development of the locus coeruleus, a subset of sympathetic and parasympathetic ganglia and the VIIth, IXth, and Xth cranial sensory ganglia. In the sensory ganglia, we have identified two differentiation blocks in Phox2a-/- mice. First, the transient expression of dopamine-beta-hydroxylase in neuroblasts is abolished, providing evidence that Phox2a controls noradrenergic traits in vivo. Second, the expression of the GDNF receptor subunit Ret is dramatically reduced, and there is a massive increase in apoptosis of ganglion cells, which are known to depend on GDNF in vivo. Therefore, Phox2a appears to regulate conventional differentiation traits and the ability of neurons to respond to essential survival factors.

Xom: a Xenopus homeobox gene that mediates the early effects of BMP-4

Bone morphogenetic protein-4 (BMP-4) is thought to play an important role in early Xenopus development by acting as a ‘ventralizing factor’ and as an epidermal determinant: local inhibition of BMP-4 function in whole embryos causes the formation of an additional dorsal axis, and inhibition of BMP-4 function in isolated ectodermal cells causes the formation of neural tissue. In this paper we describe a homeobox-containing gene whose expression pattern is similar to that of BMP-4, whose expression requires BMP-4 signalling and which, when over-expressed, causes a phenotype similar to that caused by over-expression of BMP-4. We suggest that this gene, which we call Xom, acts downstream of BMP-4 to mediate its effects.

Redundant control of Ultrabithorax by zeste involves functional levels of zeste protein binding at the Ultrabithorax promoter

Many biological processes appear to be controlled by functionally redundant genes or pathways, but it has proven difficult to understand the nature of this redundancy. Here, we have analyzed a redundant regulatory interaction between the Drosophila transcription factor zeste and the homeotic gene Ultrabithorax. Mutations in zeste do not affect the cis-regulation of the endogenous Ultrabithorax gene; however, the expression of small Ultrabithorax promoter constructs is strongly dependent upon zeste. We show that this difference is due to redundant cis-regulatory elements in the Ultrabithorax gene, which presumably contain binding sites for factors that share the function of zeste. We also provide evidence suggesting that zeste and the gene encoding the GAGA factor have an overlapping function in regulating Ultrabithorax. Furthermore, we show that the zeste protein is bound at equal levels in vivo to a Ultrabithorax promoter construct, which zeste strongly activates, and to the identical promoter region in the endogenous Ultrabithorax gene, which zeste redundantly regulates. These results suggest that zeste is significantly active in the wild-type animal and not simply a factor that is induced as a back-up when other activators fail.

eagle, a member of the steroid receptor gene superfamily, is expressed in a subset of neuroblasts and regulates the fate of their putative progeny in the Drosophila CNS

We isolated and characterized the eagle gene, encoding a member of the steroid receptor superfamily in Drosophila. In the central nervous system eagle RNA was expressed in a limited number of cells. During stages 10 and 11, eagle RNA expression was observed in four neuroblasts, NB2-4, NB3-3, NB6-4 and NB7-3. Except for NB6-4, eagle RNA expression reached a maximum at the very beginning of expression or in the period of neuroblast delamination. Weak eagle RNA expression was also observed in a few putative progeny of NB7-3 during stages, late 11 and 12. All eagle RNA in abdominal segments disappeared at stage 13. Using an eagle-kinesin-lacZ fusion gene as a reporter, the division, migration, and axonogenesis in eagle-positive cells and their derivatives were examined. At stage 14, several types of neural or glial cells were detected which include EG and EW interneurons joining to the anterior and posterior commissures, respectively. Lack of eagle expression caused altered axonogenesis in an appreciable fraction of eagle-Kinesin-LacZ-positive neurons. Some EG cells failed to acquire the neural fate or underwent an extremely delayed differentiation, while EW neurons produced neurites in abnormal directions, suggesting that eagle may play a critical role in development of the progeny of eagle-positive neuroblasts.

On the functional overlap between two Drosophila POU homeo domain genes and the cell fate specification of a CNS neural precursor

The approximately 200 distinct neurons comprising each hemisegment of the Drosophila embryonic CNS are derived from a stereotypic array of approximately 30 progenitor stem cells, called neuroblasts (NBs). Each NB undergoes repeated asymmetric divisions to produce several smaller ganglion mother cells (GMCs), each of which, in turn, divides to produce two neurons and/or glia cells. To understand the process by which cell type diversity is generated in the CNS, we are focusing on identifying genes that affect cell identity in the NB4-2 lineage from which the RP2 motoneuron is derived. We show here that within the early part of the NB4-2 lineage, two closely linked and structurally related POU homeo domain genes, pdm-2 (dPOU28) and pdm-1 (dPOU19), both encode proteins that accumulate to high levels only in the first GMC (GMC4-2a) and not in its progeny, the RP2 motoneuron. Our results from the genetic and developmental analysis of pdm-1 and pdm-2 demonstrate that these genes are not required for the birth of GMC4-2a; however, they are both involved in specifying the identity of GMC4-2a and, ultimately, in the genesis of RP2 neurons, with pdm-2 being the more dominant player in this process. In mutant animals where both pdm-1 and pdm-2 functions are removed, GMC4-2a fails to express markers consistent with a GMC4-2a identity and no mature (Eve protein expressing) RP2 neurons are produced. We demonstrate that in some mutant combinations in which no mature RP2 neurons are produced, some GMC4-2a cells can nevertheless divide. Hence, the failure of the POU mutants to produce mature RP2 neurons is not attributable to a block in GMC4-2a cell division per se but, rather, because the GMC4-2a cells fail to acquire their correct cellular identity.

Barx1, a new mouse homeodomain transcription factor expressed in cranio-facial ectomesenchyme and the stomach

In the process of cloning murine proteins capable of binding to a regulatory module of the Ncam promoter, we isolated a novel homeobox gene, Barx1, the first vertebrate member of the structural subclass defined by Drosophila BarH1. Here we report its sequence, chromosomal localisation and embryonic expression pattern. Barx1 was strongly expressed in restricted areas of head and neck mesenchyme and in the wall of the developing stomach and at weaker levels in the proximal fore- and hindlimbs. At embryonic day 10.5, expression in the head region is detected in spatially restricted areas of the first and second branchial arches, before any apparent cellular or morphological differentiation. Later in development, all expressing tissues in this region, which include the mesenchyme underlying the olfactory epithelium, the primary and secondary palate, the molar tooth papillae and the stroma of the submandibular gland, appear derived from ectomesenchyme of neural crest origin. At day 16.5, all locations other than the developing molars had become Barx1-negative. An intriguing feature is the restriction of Barx1 expression to the molars suggesting a role in the differentiation of molars from incisors. Barx1 already marks the future stomach region of the primitive gut at embryonic day 9.5 and is present in the mesenchymal wall of the stomach up to day 16.5. These results thus direct a search for its function to a number of inductive epithelial-mesenchymal interactions during craniofacial development and to stomach organogenesis.

Transposon-induced rearrangements in the duplicated locus ph of Drosophila melanogaster can create new chimeric genes functionally identical to the wild type

Variation in the number of gene copies can play a major role in changing the coding capacities of eukaryotic genomes. Different mechanisms, such as unequal recombination or transposon-induced chromosome rearrangements, are believed to be responsible for these events. We have used the direct tandem duplication at the complex locus polyhomeotic (ph) of Drosophila melanogaster as a model system to study functional redundancy associated with chromosomal rearrangements, such as duplications or deletions. The locus covers 28.6 kb and comprises two independent units, ph proximal and ph distal, which are not only similar on the molecular level, but appear to be functionally redundant [Dura et al., Cell 51 (1987) 829-839; Deatrick et al., Gene 105 (1991) 185-195]. We present a molecular and phenotypic analysis of two hypomorphic ph mutants, ph2 and ph4, induced during hybrid dysgenesis. Each corresponds to an internal deletion in the ph locus that overlaps both transcription units. We show that the deletions are likely due to a P/M hybrid dysgenesis-induced rearrangement between proximal and distal ph, that created a single new chimerical ph gene. At least one of the breakpoints must be located in a 1247-bp region that is rich in single sequence, and 100% identical between proximal and distal ph. Junction points between units are in the protein-coding regions, but could not be exactly localized on the genomic sequence of either mutant, because of the precise molecular mechanism that caused the deletions. Protein products of the hybrid genes contain the same functional domains as either wild-type (wt) product.(ABSTRACT TRUNCATED AT 250 WORDS)

Redundant functions of the genes knirps and knirps-related for the establishment of anterior Drosophila head structures

Developmental gene functions of Drosophila are typically characterized by a recognizable mutant phenotype. When molecular probes of such genes were used to isolate homologues, distinct spatially and temporally restricted expression patterns were observed in vertebrates as well. However, corresponding "gene knock-outs" often revealed subtle or no scorable phenotypes, a phenomenon attributed to redundant gene functions. We found that the evolutionarily related genes knirps (kni) and knirps-related (knrl) contribute to a similar phenomenon in Drosophila. The two closely situated genes show identical expression patterns in the developing embryo, including the posterior and anterior expression domains in the blastoderm. Here we show that the two biochemically equivalent gene products are both functional in the head anlage and that the lack of one gene activity can be overcome by the activity of the other. Whereas kni is also required for abdominal segmentation, knrl is nonfunctional in its posterior expression domain. Thus, the kni/knrl pair of genes provides a region-specific buffering system, rather than a case of global functional redundancy.

Mutations affecting the pattern of the PNS in Drosophila reveal novel aspects of neuronal development

Through a systematic genetic screen, we have identified 55 mutations that affect the development of the PNS of Drosophila embryos. These mutations specify 13 novel and 5 previously characterized genes and define new phenotypes for 2 other known genes. Five classes of mutant phenotypes were identified in the screen: gain of neurons, loss of neurons, abnormal position of chordotonal neurons, aberrant neuronal trajectories, and abnormal morphology of neurons. Phenotypic analyses of mutations identified in this study revealed three novel aspects of PNS development. First, we have identified a novel gene that may be required to define glial versus neuronal cell identity. Second, our data indicate that neuronal migration plays an important role in pattern formation in the embryonic PNS. Third, we have identified mutations that cause a lack of sensory organs, but unlike mutations in proneural genes, do not affect the formation of sensory organ precursors. These genes may be required for key aspects of neuronal differentiation. Our studies suggest that approximately 70 essential genes are required for proper PNS development in Drosophila embryos.

Functional redundancy: the respective roles of the two sloppy paired genes in Drosophila segmentation

The sloppy paired (slp) locus consists of two genes, slp1 and slp2, both of which encode proteins containing a forkhead domain (a DNA-binding motif). Previous work has shown that a severe segmentation phenotype is obtained only when both slp genes are deleted. Here we examine the functional redundancy of the locus in more detail. The phenotypes of embryos containing various combinations of functional slp genes suggest that for early slp function, until gastrulation, only slp1 is required. At later times, there is still a greater requirement for slp1, but in many respects the two slp genes are completely redundant. Both slp genes produce similar phenotypes when ubiquitously expressed via a heat shock promoter. We propose that the slp proteins are biochemically equivalent and that the greater requirement for slp1 in some functions can be explained in large part by its earlier expression.

Asymmetric distribution of numb protein during division of the sensory organ precursor cell confers distinct fates to daughter cells

The four cells of an external sense organ in the Drosophila peripheral nervous system, the neuron, its sheath cell, and two "outer support cells" that form the hair and socket, are derived from a common precursor, the sensory organ precursor (SOP), after two rounds of division. We determined by immunocytochemistry that numb is a membrane-associated protein which localizes asymmetrically to one-half of the predivisional SOP cell. Upon division, numb segregates differentially to one daughter. Loss of numb function causes the descendants of the SOP to differentiate inappropriately, producing four outer support cells and no neuron or sheath. Ectopic expression of numb during the time of SOP division results in a transformation that is opposite to the null mutant transformation. Thus, numb functions to determine the fates of the secondary precursors; the differential distribution of numb as the SOP divides generates an asymmetric division in which the daughter cells acquire distinct identities.

Thinking about genetic redundancy

Partial functional redundancy among genes is frequently observed in a wide range of organisms and processes, but the selective value of such redundancy is not immediately apparent. Any fully redundant function should be evolutionarily unstable: unless selection acts to maintain the redundancy it will tend to be lost by mutational drift. I discuss four possible mechanisms by which selection might act to maintain genetic redundancy.

Neural fate specification in Drosophila

The specification of cell fates, particularly in the nervous system where cell diversity is highest, is a basic problem in developmental biology. Mutational and molecular analyses in Drosophila are uncovering families of genes, many of them transcription factors, that regulate the progressive acquisition of neural traits. These comprise the initial selection of neural precursors from the ectoderm, the implementation of a basic neural fate common to all precursors and the concomitant endowment of each precursor and its progeny with specific fates.

Analysis of the antennal phenotype in the Drosophila mutant lozenge

Previous work on the lozenge (lz) gene complex of D. melanogaster has focused on the compound eye. Here we study the effects of 22 lz mutations on the antennal sensilla. The antenna of strong lz alleles is characterized by a lack of basiconic sensilla and by a significantly increased density of coeloconic sensilla. Intermediate alleles have few basiconic sensilla, they exhibit a highly increased density of trichoid sensilla, but a normal coeloconic density. Basiconic sensilla on the maxillary palps are weakly affected even by strong lz alleles. The antennal phenotype for most of the strong and intermediate mutants is partially dominant over wild type. Although this complicates the interpretation of complementation data, 12 selected mutants that were studied in heteroallelic combinations seem to define a single cistron. Temperature shifts of the lztsl allele showed that gene activity is crucial from about 87% of the third larval instar up to 7% of pupal life. Applying restrictive temperature early during this period results in a 'novel' phenotype that is characterized by a dramatic decrease in the density of trichoid sensilla, whereas a late pulse of restrictive temperature leads to a 'normal' intermediate phenotype. Our data suggest that the lz gene controls at least five different functions in the antenna: the size of the third antennal segment, the overall number and density of sensilla, the proportions of the 3 types of sensilla, and the generation of basiconic sensilla.

Mechanism of induction of Bar-like eye malformation by transient overexpression of Bar homeobox genes in Drosophila melanogaster

The Bar locus of Drosophila is known to be a small complex consisting of two similar homeobox genes, BarH1 and BarH2. Using egr as an ommatidium marker, possible mechanisms of formation of malformed eyes were examined. As in the case of BarH1, overexpression of BarH2 was found to be capable of inducing Bar-like eye malformation. It was suggested that suppression of the anterior progression of the morphogenetic furrow and inhibition of reinitiation of normal ommatidial differentiation were mandatory to formation of the reduced eye morphology in Bar mutants.

Regulation of expression domains and effects of ectopic expression reveal gap gene-like properties of the linked pdm genes of Drosophila

The closely linked POU domain genes pdm-1 and pdm-2 are first expressed early during cellularization in the presumptive abdomen in a broad domain that soon resolves into two stripes. This expression pattern is regulated by the same mechanisms that define gap gene expression domains. The borders of pdm-1 expression are set by the terminal system genes torso and tailless, and the gradient morphogen encoded by hunchback. The resolution into two stripes is controlled by the gap gene knirps. Ectopic expression of pdm-1 at the cellular blastoderm stage leads to disruptions in pair rule gene expression and in anterior segmentation. The broad abdominal domain of pdm-1 protein is lacking in nanos- mutant embryos, and ectopic pdm-1 expression in nanos- embryos leads to a partial restoration of abdominal segmentation. These data suggest that the pdm genes may act in segmentation near the level of the zygotic gap genes.

The specification of sensory neuron identity in Drosophila

Different types of sense organs are present on the larva of Drosophila. Several genes that specify the type of sense organ that will form at a particular position have been recently identified. Here we review the functional and molecular analyses of these genes, and summarize the evidence which supports a role in the choice of which type of organ will be formed. Most or all of these genes are required for the appropriate specification of adult as well as larval sense organs, suggesting that the larval and adult systems share many gene requirements. Interestingly, the specifying genes identified so far in the peripheral nervous system are also expressed in subsets of cells in the central nervous system, where they might have similar roles.

The role of the cut gene in the specification of central projections by sensory axons in Drosophila

Mutations in the cut gene transform sense organs in Drosophila embryos from external sensory (es) receptors to chordotonal (ch) organs. We have investigated whether their central axonal projections are also transformed. Following Lucifer yellow injection of the sensory neuron, wild-type es and ch organs show characteristic, different projection patterns in the CNS. Transformed es neurons in cut embryos are variable in their projection patterns: some resemble wild-type es neurons, others ch neurons, while yet others are unlike either of these. We conclude that the cut gene influences axonal projections, although its action as a simple modality switch is open to question. Additional genes could be involved in the specification of the central axonal projection of the transformed neurons.

Two FGF-receptor homologues of Drosophila: one is expressed in mesodermal primordium in early embryos

The fibroblast growth factor (FGF)/receptor system is thought to mediate various developmental events in vertebrates. We examined molecular structures and expression of DFR1 and DFR2, two Drosophila genes closely related to vertebrate FGF-receptor genes. DFR1 and DFR2 proteins contain two and five immunoglobulin-like domains, respectively, in the extracellular region, and a split tyrosine kinase domain in the intracellular region. In early embryos, DFR1 RNA expression, requiring both twist and snail proteins, is specific to mesodermal primordium and invaginated mesodermal cells. At later stages, putative muscle precursor cells and cells in the central nervous system (CNS) express DFR1. DFR2 expression occurs in endodermal precursor cells, CNS midline cells and certain ectodermal cells such as those of trachea and salivary duct. FGF-receptor homologues in Drosophila would thus appear essential for generation of mesodermal and endodermal layers, invaginations of various types of cells, and CNS formation.