Cell determination in Drosophila with paradoxical genotypes

A paradoxical genotype for Drosophila melanogaster is constructed by combining two homeotic mutations, which cause contradictory transformations of the first abdominal segment to metathorax and second abdominal segment. The resulting conflict in genetic instructions is resolved by the individual cells which normally give rise to the first abdominal segment. Each cell elects to follow only one set of instructions and determines to either metathorax or second abdominal segment. The choice between pathways can be characterized by the “determination equilibrium,” which is a measure of the probability that no cell in a presumptive first abdominal histoblast determines to second abdominal segment. The determination equilibrium allows a quantitative assessment of genotypic and physiological factors which can influence the probability of a determinative decision. These results are discussed from the point of view of the abstract nature of determinative decisions and from the point of view of the mechanisms involved.     

Role of abd-A and Abd-B in Development of Abdominal Epithelia Breaks Posterior Prevalence Rule

Hox genes that determine anteroposterior body axis formation in all bilaterians are often found to have partially overlapping expression pattern. Since posterior genes dominate over anterior Hox genes in the region of co-expression, the anterior Hox genes are thought to have no function in such regions. In this study we show that two Hox genes have distinct and essential functions in the same cell. In Drosophila, the three Hox genes of the bithorax complex, Ubx, abd-A and Abd-B, show coexpression during embryonic development. Here, we show that in early pupal abdominal epithelia, Ubx does not coexpress with abd-A and Abd-B, while abd-A and Abd-B continue to coexpress in the same nuclei. The abd-A and Abd-B are expressed in both histoblast nest cells and larval epithelial cells of early pupal abdominal epithelia. Further functional studies demonstrate that abd-A is required in histoblast nest cells for their proliferation and suppression of Ubx to prevent first abdominal segment like features in posterior segments while in larval epithelial cells it is required for their elimination. We also observed that these functions of abd-A are required in its exclusive as well as the coexpression domain with that of Abd-B. The expression of Abd-B is required in histoblast nest cells for their identity while it is dispensable in the larval epithelial cells. The higher level of Abd-B in the seventh abdominal segment, that down-regulates abd-A expression, leads this segment to be absent in males or of smaller size in females. We also show that abd-A in histoblast nest cells positively regulates expression of wingless for the formation of the abdominal epithelia. Our study reveals an exception to the rule of posterior prevalence and shows that two different Hox genes have distinct functions in the same cell, which is essential for the development of abdominal epithelia.     

The development of ommatidial patterning in metamorphosed eye imaginal discs implants ofDrosophila melanogaster

Summary The development of the rhabdomeric pattern in the compound eye ofDrosophila has been studied using combined transplantation and electron microscope techniques. In a first series of experiments eye imaginal discs of increasing age were implanted into larvae ready to pupate, thus losing variable amounts of the normal time for development. A sequence of differentiative abilities was found in the metamorphosed test pieces. As far as the photoreceptor cells are concerned, the most prominent steps of this sequence are: ability to form groups with other similar elements, anatomical polarization of microvilli, establishment of the rhabdomeric pattern and formation of an equator line. The stability of determination of the equator line was tested in a second experimental series. Fragment of different topographical origin within the mature eye anlage were brought to metamorphosis by implantation into larvae ready to pupate. It was found that an equator line differentiates only in those pieces which according to the published anlage maps contain the prospective equator region prior to metamorphosis. The mitotic abilities of implanted eye imaginal discs were investigated by means of in vitro³H-thymidine pulse-labelling and light microscope autoradiography of the differentiated test pieces. During the third larval stage the eye anlage is traversed by two consecutive mitotic waves, each one of them producing different categories of receptor cells. The first, anterior wave predominantly produces cells oriented toward the poles of the eye within the ommatidia, while the second, posterior wave gives rise to elements exclusively in an equatorial position. The dynamics of this proliferation are discussed in relation to the findings in the implantation experiments. Silver-grain counts support the possibility that at least two successive cell divisions occur in the eye anlage between labeling with tritiated thymidine and beginning of morphological differentiation. The relevance of this finding for the understanding of the concept of acquisition of competence is discussed.     

Pattern regulation during the development of the dorsal abdomen in the flesh fly,Sarcophaga agryostoma

Summary In dipteran flies the adult abdominal epidermis is formed from small nests of diploid histoblast cells which spread out and replace the larval epidermis during metamorphosis. The pattern of nest outgrowth and fusion in Sarcophaga shows that the large dorsal hemitergite is normally formed by the two dorsal nests, the spiracle nest and part of the ventral nest (which also forms the hemisternite). By rotating the dorsal histoblast nests, we demonstrate that the adult segment border lies between the flexible intersegmental membrane (ISM) and the naked anterior strip of tergite, the acrotergite. Deletion of histoblast nests often results in a corresponding deletion of adult structures, accompanied by enlargement of adjacent structures within the segment and in neighbouring segments. Pattern formation is not strictly coupled to cell division (as in imaginal discs), since the nests remaining after an ablation, in spreading to fill vacant areas, generate more cells and larger structures than normal. Nest deletions can also result in regeneration, with remaining nests forming additional structures in the dorsal-ventral or anterior-posterior axis of the segment. The deletion of strips of anterior and intersegmental larval epidermis without histoblasts results in the formation of double-posterior duplications of the adult hemitergite. Although these operations damage adjacent histoblast nests, several features of the results suggest that the duplications arise from the interaction (after healing) of histoblasts with larval cells which they would not normally encounter, leading to the intercalation of histoblast cells bearing intervening anterior-posterior positional values. A similar process of intercalation may occur in normal development, as the histoblasts spread from their local origins across the larval epidermal sheet, replacing the larval cells to form the entire epidermis of the adult segment. Offprint requests to: V. French     

Negative growth control of mitotically active imaginal cells (histoblasts) of the abdominal epidermis during metamorphosis of the housefly

On the ventral side of each pupal abdominal segment of the housefly, there is a pair of histoblast nests, each containing about 600 diploid cells. These cells, during adult development, divide, replace intervening polytene larval epidermal cells (LEC), and form both the median sternite and the surrounding pleura of the adult segment. Since the histoblast nests and the LEC form a contiguous layer, we examined the role of these two types of cells in regulating the mitotic potential of the histoblasts during development of the median sternite. Two experimental approaches were used: deletion of one of the nests by thermocautery; and by disturbance of the continuity of the monolayered epidermis by thermocautery of, or topical application of heptanol on, the midventral LEC. Ablation of one of the contralateral nests resulted in a mirror image duplication of the hemisternite and pleura by the surviving nest. Disturbance of the continuity of the LEC produced mirror image duplication of the hemisternal pattern by each of the contralateral nests. From these results, we propose that the contralateral ventral nests mutually downregulate their mitotic potential by secreting regulatory factor(s) to produce the normal median sternite pattern and surrounding pleura. We also suggest that these chemicals act in a paracrine fashion, possibly through gap junctions in the LEC. © 1994 Wiley-Liss, Inc.     

Nonautonomous apoptosis is triggered by local cell cycle progression during epithelial replacement in Drosophila

Tissue remodeling involves collective cell movement, and cell proliferation and apoptosis are observed in both development and disease. Apoptosis and proliferation are considered to be closely correlated, but little is known about their coordinated regulation in physiological tissue remodeling in vivo. The replacement of larval abdominal epidermis with adult epithelium in Drosophila pupae is a simple model of tissue remodeling. During this process, larval epidermal cells (LECs) undergo apoptosis and are replaced by histoblasts, which are adult precursor cells. By analyzing caspase activation at the single-cell level in living pupae, we found that caspase activation in LECs is induced at the LEC/histoblast boundary, which expands as the LECs die. Manipulating histoblast proliferation at the LEC/histoblast boundary, either genetically or by UV illumination, indicated that local interactions with proliferating histoblasts triggered caspase activation in the boundary LECs. Finally, by monitoring the spatiotemporal dynamics of the S/G₂/M phase in histoblasts in vivo, we found that the transition from S/G₂ phases is necessary to induce nonautonomous LEC apoptosis at the LEC/histoblast boundary. The replacement boundary, formed as caspase activation is regulated locally by cell-cell communication, may drive the dynamic orchestration of cell replacement during tissue remodeling.     

The Ultrabithorax gene of Drosophila and the specification of abdominal histoblasts.

Separation of the imaginal and larval developmental pathways in Drosophila occurs early in embryogenesis, resulting in the formation of imaginal discs and abdominal histoblast nests along the larval body wall. The dorsal and ventral histoblast nests within the first abdominal (A1) segment are shown not to be segmentally homologous with the metathoracic (T3) haltere and leg discs, respectively, since they occur at distinct dorso-ventral locations during normal development and can be found together within the same segment in mutants of the Bithorax complex (BX-C) where T3 is transformed towards A2-A4 or A1 towards T3. Several patterning abnormalities are also observed in BX-C mutants. A ventral shift in the A1 ventral nest occurs in partially transformed larvae harboring weak bithoraxoid (bxd) mutations; in more fully transformed larvae (Ubx1/Df) both the anterior dorsal and ventral nests are lost and instead a dorsal and ventral disc bud are formed. Dorso-ventral inversions in the pattern of the ventral nest occur in a random fashion throughout A1-A7 in response to an increase or decrease in the gene dosage of the BX-C. In gain-of-function mutants anterior dorsal histoblast cells form in the homologous anterior as well as the nonhomologous posterior portion of T3. Based on these and other findings it appears that the Ultrabithorax (Ubx) locus (and possibly abdominal-A and Abdominal-B) is required to steer ectodermal cells toward an imaginal histoblast rather than a larval cell fate at specific regions within the first abdominal segment.     

Pattern regulation in the ventral histoblasts of the housefly: induction of sternal pattern abnormalities by mechanical wounding of larval epidermal cells

In higher Diptera, two nests of diploid cells called the ventral histoblasts, located one on either side of each abdominal segment among the polytene larval epidermal cells, give rise to the sternite and its surrounding pleura. During metamorphosis of the insect, these two groups of cells migrate and meet with each other in the midventral region of the developing adult. The cuticular pattern elements and pigmentation in the fifth sternite of the male housefly, when compared to those of other segments as well as the tergites of both sexes, are quite distinct. The above-mentioned features, coupled with the smaller number and predictable occurrence of one of the pattern elements in this sternite, viz, the primary forceps, help one to determine the developmental potential of the histoblast nest and the regulation of its potential which occur at the time of fusion of the two contralateral nests of this segment. A simple operation of slitting the larval epidermal cells (LEC) in a hemisegment in the vicinity of the histoblast nest or extirpation or rotation of a small rectangular piece of LEC between the ventral nest and the midventral line produced pattern abnormalities including mirror image duplication in the hemisternite. An analysis of these pattern abnormalities in the different segments and, in particular, in the fifth segment provides a dynamic picture of the formation of the median sternite. Further, these abnormalities indicate the significance of the presence of the intervening pleural cells between the confronting hemisternites under experimental conditions. Thus, each of the fifth ventral nests has the developmental potential to form more than half of the final sternite pattern. Possible mechanisms for the formation of the normal median sternite during metamorphosis and for the formation of duplicated hemisternites and their fusion products under experimental conditions are discussed in light of current models of pattern regulation.     

Developmental analysis of some mutants of the bithorax system ofDrosophila

Summary Mutants in the bithorax system ofDrosophila produce homeotic transformations that affect the mesothoracic, metathoracic and first abdominal segments. In the present report we describe a clonal analysis of the development of those mutants transforming the metathorax and first abdominal segments into mesothorax.The main results indicate that (1) The normal dorsal metathoracic (haltere) disk has similar developmental parameters to the dorsal mesothoracic disk. The main difference is that the initial and final numbers of cells are different in both disks. (2) In flies mutant forBithorax andpostbithorax (which transform the haltere into wing) the transformed haltere disk has the same initial and final number of cells as the normal wing disk. (3) In morphogenetic mosaics homozygousbithorax (andpostbithorax) clones express their genotype autonomously regardless of the genotype of surrounding haltere cells. This autonomy is expressed in a regulation of the number of adult cells per compartment, typical cell affinities and final cuticular differentiation.     

Cyclic AMP and genetic sterility of a male restricted (H re /+) mutant of Rattus

Restricted (H ^re /+) male rats marked by a coat color pattern have normal testes at birth. By 9 days postpartum, testes of the mutant animals are smaller than normal and by approximately 90 days of age the animals are sterile. The genetically sterile testes are totally devoid of spermatogonial cells, spermatocytes, spermatids, and spermatozoa, with only Sertoli cells remaining in the seminiferous tubules. Cyclic AMP concentrations in the whole testes (and the seminiferous tubules) of the mutant males are approximately 10–35% greater than in testes of control males when tested at intervals from 5 to 120 days of age. The possible role of excess cyclic AMP in reducing the rate of mitotic division of spermatogonial cells while enhancing differentiation of spermatogonial cells into spermatozoa is discussed. Such a change in the respective rates of mitotic and meiotic divisions would ultimately deplete the mutant testes of all spermatogonial cells.     

A yeast strain for simultaneous detection of induced mitotic crossing over,mitotic gene conversion and reverse mutation

A diploid yeast strain is described which can be used to study induction of mitotic crossing over, mitotic gene conversion and reverse mutation.Mitotic crossing over can be detected visually as pink and red twin sectored colonies which are due to the formation of homozygous cells of the genotype ade240/ade240 (deep red) and ade-2-119/ade2-119 (pink) from the originally heteroallelic condition ade2-40/ade2-119 which forms white colonies.Mitotic gene conversion is monitored by the appearance of tryptophan non-requiring colonies on selective media. The alleles involved are tryp5-12 and trp5-27 derived from the widely used strain D4.Mutation induction can be followed by the appearance of isoleucine non-requiring colonies on selective media. D7 is homoallelic ilv1-92/ilv1-92. The isoleucine requirement caused by ilv1-92 can be alleviated by true reverse mutation and allele non-specific suppressor mutation.The effects of ethyl methanesulfonate (EMS), nitrous acid, ultraviolet light and hycanthone methanesulfonate were studied with D7 stationary phase cells. Mitotic crossing over as monitored by red/pink twin sectored colonies was almost equally frequent among normal and convertant cells. This showed again that mitotic recombination is not due to the presence fo a few cells committed to meiosis in an otherwise mitotic cell population.The dose-response curves for induction of mitotic gene conversion and reversion of the isoleucine requirement were exponential. In contrast to this, the dose-response curve for induction of twin sectored red and pink colonies reached a plateau at doses giving about 30% cell killing. This could partly be due to lethal segregation in the progeny of treated cells.None of the agents tested would induce only one type of mitotic recombination, gene conversion or crossing over. There was, however, some mutagen specificity in the induction of isoleucine prototrophs.     

Establishment of imaginal discs and histoblast nests in Drosophila

In Drosophila the homeotic genes of the bithorax-complex (BX-C) and Antennapedia-complex (ANT-C) specify the identity of segments. Adult segment primordia are established in the embryo as the histoblast nests of the abdomen and the imaginal discs of the head, thorax and terminalia. We have used a molecular probe for the limb primordia and in vivo culture to describe the nature of the adult primordia in mutants in which the pattern of homeotic gene expression was altered. The results suggest that the histoblast or disc 'mode' of development is initiated by the extended germ band stage through activity of the BX-C and ANT-C and is relatively inflexible thereafter [corrected].     

rap gene encodes Fizzy-related protein (Fzr) and regulates cell proliferation and pattern formation in the developing Drosophila eye-antennal disc

The rap (retina aberrant in pattern) gene encodes the Fizzy-related protein (Fzr), which as an activator of the ubiquitin ligase complex; APC/C (anaphase promoting complex/cyclosome) facilitates the cell cycle stage-specific degradation of cyclins. Loss-of-function mutations in rap cause unscheduled accumulation of cyclin B in the developing eye imaginal disc, resulting in additional mitotic cycles and defective patterning of the developing Drosophila eye. Targeted mis-expression of rap/fzr in the eye primordial cells causes precocious cell cycle exit, and smaller primordial eye fields, which either eliminate or drastically reduce the size of the adult eye. Although mitosis is inhibited in the mis-expression animals, cells with abnormally large nuclei form tumor-like structures from continued endoreplication, cell growth and retinal differentiation. Interestingly, overexpression of Rap/Fzr in the eye primordia also increases the size of the antennal primordium resulting in the induction of ectopic antennae. These results suggest that Rap/Fzr plays an essential role in the timely exit of precursor cells from mitotic cycles and indicate that mechanisms that regulate cell cycle exit are critical during pattern formation and morphogenesis.     

Chromatin insulator and the promoter targeting sequence modulate the timing of long-range enhancer-promoter interactions in the Drosophila embryo

The homeotic genes are essential to the patterning of the anterior-posterior axis along the developing Drosophila embryo. The expression timing and levels of these genes are crucial for the correct specification of segmental identity. The Abdominal-B (Abd-B) gene is first detected in the most posterior abdominal segments at high levels and gradually appears in progressively anterior abdominal segments in lower amounts. Regulatory mutations affecting this expression pattern produce homeotic transformations in the abdomen. The promoter targeting sequences (PTS) from Abd-B locus overcome the enhancer blocking effect of insulators and facilitate long-range enhancer-promoter interactions in transgenic flies (1, 2). In this study, we found that transgene activation by the IAB5 enhancer can be delayed by inserting a 9.5 kb 3′ Abd-B regulatory region containing the Frontabdominal-8 (Fab-8) insulator and the PTS element. We found that the delay is caused by the PTS and an insulator, and it is not specific to the enhancer or the promoter tested. Based on these findings, we hypothesize that the delay of remote enhancers is responsible for the Abd-B expression pattern, which is at least in part due to the regulatory activities of the PTS elements and chromatin boundaries.     

The development of the imaginal abdomen of Drosophila melanogaster

The development of the imaginal Drosophila melanogaster was investigated by an analysis of clones of cells marked by somatic crossing-over. The results showed that each abdominal half tergite is initiated by about 11 cells which fail to divide during late embryonic and larval stages. Cell division commences only at the time of pupariation, and continues for the next 32 hr. The spatial pattern of marked clones indicated that each tergite consists of a left and right side—marked cells do not cross the midline. Twin spots were examined and indicated that two daughter cells are aligned preferentially in the transverse orientation. These results are contrasted to data obtained for other imaginal anlage, particularly with regard to the time of cessation of cell division.     

Maternal effect mutations affecting macronuclear determination and development in Paramecium tetraurelia

Gene mutations that interfere with macronuclear development in Paramecium were obtained by selecting lines that failed to produce normal macronuclear anlagen following the second autogamy after mutagenesis. The mutants fell into several complementation groups. There was one case of apparent intragenic noncomplementation among the eight mutants examined. In the stronger mutants, macronuclear anlagen were not formed, and all four mitotic products of the posfzygotic divisions of the synkaryon remained as micronuclei. Under semirestrictive conditions, cells often contained a single anlage, suggesting that determination of anlagen was a discrete event for each nucleus. The missing anlagen trait was recessive and associated with a strong maternal effect. The phenocritical period of one of the stronger alleles, aal^a, began at the second postzygotic division and ended with the first morphological differentiation of macronuclear anlagen. Nuclear migration in this mutant was abnormal. Under restrictive conditions, the posterior products of the second postzygotic division reached a posterior-most position, which was 8% of cell length more anterior than that of the most posterior nuclei in wild-type cells. Under permissive conditions, the pattern of migration was intermediate between that of wild-type cells and mutants under fully restrictive conditions. The patterns of nuclear migration were consistent with the nuclear growth kinetics.     

Inhibition of DNA synthesis in embryonic mouse retina as a result of gene interaction.

It has been shown by autoradiography using ³H-thymidine that 11-day mouse embryos doubly homozygous for the autosomal recessive genes fidget (gene symbol fi) and ocular retardation (or), have three to five times fewer labelled nuclei in their retina anlages as do normal (genotype +/+ +/+) embryos singly homozygous for fidget (+/+ $\text{fi}\text{fi}$) or ocular retardation (+/+ $\text{or}\text{or}$). In 11-day embryos of +/+ +/+, +/+ $\text{fi}\text{fi}$ and +/+ $\text{or}\text{or}$ genotypes the labelled nuclei are localized mainly in the inner zone of the retina anlage. However, in double homozygotes the indices of labelled nuclei were not significantly different in the inner and outer zones of the retina anlage. The retina anlage of 12-day double homozygote, $\text{fi}\text{fi}\text{or}\text{or}$, has practically no nuclei synthesizing DNA. Consequently, the mutant genes fi and or which prolong the G₁ period of the cell cycle in single homozygotes, act synergetically to stop DNA synthesis in the retina anlage cells of 12-day $\text{fi}\text{fi}\text{or}\text{or}$ embryos.     

The central projections of mesothoracic sensory neurons in wild-type Drosophila and bithorax mutants

Sensory axons entering the CNS from large campaniform sensilla on the normal, mesothoracic wings of four-winged flies of the genotype $\text{bx}{}^3\text{pbx}\text{Ubx}{}^{130}$ follow the same two tracts as do the corresponding axons in wild-type flies. However, they produce more branches along the ventromedial tract (including some in the mesothoracic neuromere), more fibers crossing the midline in the metathorax, and several other modifications of the wild-type pattern. No morphological differences between the receptors in normal and mutant flies could be detected, even with the SEM. The extra branching and other altered characteristics are present in bithorax flies which are also genetically wingless and do not form the homeotic appendages, so they appear to be due to the $\text{bx}{}^3\text{pbx}\text{Ubx}{}^{130}$ or $\text{bx}{}^3\text{Ubx}{}^{130}$ genotype and not to some effect of the axons from the homeotic wings.     

Exportin1 genes are essential for development and function of the gametophytes in Arabidopsis thaliana

Gametes are produced in plants through mitotic divisions in the haploid gametophytes. We investigated the role of EXPORTIN1 (XPO1) genes during the development of both female and male gametophytes of Arabidopsis. Exportins exclude target proteins from the nucleus and are also part of a complex recruited at the kinetochores during mitosis. Here we show that double mutants in Arabidopsis XPO1A and XPO1B are gametophytic defective. In homozygous–heterozygous plants, 50% of the ovules were arrested at different stages according to the parental genotype. Double-mutant female gametophytes of xpo1a-3/+; xpo1b-1/xpo1b-1 plants failed to undergo all the mitotic divisions or failed to complete embryo sac maturation. Double-mutant female gametophytes of xpo1a-3/xpo1a-3; xpo1b-1/+ plants had normal mitotic divisions and fertilization occurred; in most of these embryo sacs the endosperm started to divide but an embryo failed to develop. Distortions in male transmission correlated with the occurrence of smaller pollen grains, poor pollen germination, and shorter pollen tubes. Our results show that mitotic divisions are possible without XPO1 during the haploid phase, but that XPO1 is crucial for the maternal-to-embryonic transition.     

Spatial distribution of the RABBIT EARS protein and effects of its ectopic expression in Arabidopsis thaliana flowers

In many flowering plants, flowers consist of two peripheral organs, sepals and petals, occurring in outer two whorls, and two inner reproductive organs, stamens and carpels. These organs are arranged in a concentric pattern in a floral meristem, and the organ identity is established by the combined action of floral homeotic genes expressed along the whorls. Floral organ primordia arise at fixed positions in the floral meristem within each whorl. The RABBIT EARS (RBE) gene is transcribed in the petal precursor cells and primordia, and regulates petal initiation and early growth in Arabidopsis thaliana. We investigated the spatial and temporal expression pattern of a RBE protein fused to the green fluorescent protein (GFP). Expression of the GFP:RBE fusion gene under the RBE cis-regulatory genomic fragment rescues the rbe petal defects, indicating that the fusion protein is functional. The GFP signal is located to the cells where RBE is transcribed, suggesting that RBE function is cell-autonomous. Ectopic expression of GFP:RBE under the APETALA1 promoter causes the homeotic conversion of floral organs, resulting in sterile flowers. In these plants, the class B homeotic genes APETALA3 and PISTILLATA are down-regulated, suggesting that the restriction of the RBE expression to the petal precursor cells is crucial for flower development.