Developmental analysis and squamous morphogenesis of the peripodial epithelium in Drosophila imaginal discs

Imaginal discs of Drosophila provide an excellent system with which to study morphogenesis, pattern formation and cell proliferation in an epithelium. Discs are sac-like in structure and are composed of two epithelial layers: an upper peripodial epithelium and lower disc proper. Although development of the disc proper has been studied extensively in terms of cell proliferation, cell signaling mechanisms and pattern formation, little is known about these same processes in the peripodial epithelium. We address this topic by focusing on morphogenesis, compartmental organization, proliferation and cell lineage of the PE in wing, second thoracic leg (T2) and eye discs. We show that a subset of peripodial cells in different imaginal discs undergo a cuboidal-to-squamous cell shape change at distinct larval stages. We find that this shape change requires both Hedgehog and Decapentapelagic, but not Wingless, signaling. Additionally, squamous morphogenesis shifts the anteroposterior (AP) compartment boundary in the peripodial epithelium relative to the stationary AP boundary in the disc proper. Finally, by lineage tracing cells in the PE, we surprisingly find that peripodial cells are displaced into the disc proper during larval development and this movement leads to Ubx repression.     

Apical accumulation of the Drosophila PDGF/VEGF receptor ligands provides a mechanism for triggering localized actin polymerization

Epithelial tissue functions depend largely on a polarized organization of the individual cells. We examined the roles of the Drosophila PDGF/VEGF receptor (PVR) in polarized epithelial cells, with specific emphasis on the wing disc epithelium. Although the receptor is broadly distributed in this tissue, two of its ligands, PVF1 and PVF3 are specifically deposited within the apical extracellular space, implying that polarized apical activation of the receptor takes place. The apical localization of the ligands involves a specialized secretion pathway. Clones for null alleles of Pvr or expression of RNAi constructs showed no phenotypes in the wing disc or pupal wing, suggesting that Pvr plays a redundant role in this tissue. However, when uniform expression of a constitutively dimerizing receptor was induced, loss of epithelial polarity, formation of multiple adherens and septate junctions, and tumorous growth were observed in the wing disc. Elevation of the level of full-length PVR also gave rise to prominent phenotypes, characterized by higher levels of actin microfilaments at the basolateral areas of the cells and irregular folding of the tissue. Together, these results suggest that polarized PVR activation is necessary for the proper organization of the wing disc epithelium, by regulating the apical assembly of the actin cytoskeleton.     

Incorporating chemical signalling factors into cell-based models of growing epithelial tissues

In this paper we present a comprehensive computational framework within which the effects of chemical signalling factors on growing epithelial tissues can be studied. The method incorporates a vertex-based cell model, in conjunction with a solver for the governing chemical equations. The vertex model provides a natural mesh for the finite element method (FEM), with node movements determined by force laws. The arbitrary Lagrangian-Eulerian formulation is adopted to account for domain movement between iterations. The effects of cell proliferation and junctional rearrangements on the mesh are also examined. By implementing refinements of the mesh we show that the finite element (FE) approximation converges towards an accurate numerical solution. The potential utility of the system is demonstrated in the context of Decapentaplegic (Dpp), a morphogen which plays a crucial role in development of the Drosophila imaginal wing disc. Despite the presence of a Dpp gradient, growth is uniform across the wing disc. We make the growth rate of cells dependent on Dpp concentration and show that the number of proliferation events increases in regions of high concentration. This allows hypotheses regarding mechanisms of growth control to be rigorously tested. The method we describe may be adapted to a range of potential application areas, and to other cell-based models with designated node movements, to accurately probe the role of morphogens in epithelial tissues.     

Mechanical Cell–Cell Communication in Fibrous Networks: The Importance of Network Geometry

Cells contracting in extracellular matrix (ECM) can transmit stress over long distances, communicating their position and orientation to cells many tens of micrometres away. Such phenomena are not observed when cells are seeded on substrates with linear elastic properties, such as polyacrylamide (PA) gel. The ability for fibrous substrates to support far reaching stress and strain fields has implications for many physiological processes, while the mechanical properties of ECM are central to several pathological processes, including tumour invasion and fibrosis. Theoretical models have investigated the properties of ECM in a variety of network geometries. However, the effects of network architecture on mechanical cell–cell communication have received little attention. This work investigates the effects of geometry on network mechanics, and thus the ability for cells to communicate mechanically through different networks. Cell-derived displacement fields are quantified for various network geometries while controlling for network topology, cross-link density and micromechanical properties. We find that the heterogeneity of response, fibre alignment, and substrate displacement fields are sensitive to network choice. Further, we show that certain geometries support mechanical communication over longer distances than others. As such, we predict that the choice of network geometry is important in fundamental modelling of cell–cell interactions in fibrous substrates, as well as in experimental settings, where mechanical signalling at the cellular scale plays an important role. This work thus informs the construction of theoretical models for substrate mechanics and experimental explorations of mechanical cell–cell communication.     

Mutations in the polycomb group gene polyhomeotic lead to epithelial instability in both the ovary and wing imaginal disc in Drosophila

Background

Most human cancers originate from epithelial tissues and cell polarity and adhesion defects can lead to metastasis. The Polycomb-Group of chromatin factors were first characterized in Drosophila as repressors of homeotic genes during development, while studies in mammals indicate a conserved role in body plan organization, as well as an implication in other processes such as stem cell maintenance, cell proliferation, and tumorigenesis. We have analyzed the function of the Drosophila Polycomb-Group gene polyhomeotic in epithelial cells of two different organs, the ovary and the wing imaginal disc.

Results

Clonal analysis of loss and gain of function of polyhomeotic resulted in segregation between mutant and wild-type cells in both the follicular and wing imaginal disc epithelia, without excessive cell proliferation. Both basal and apical expulsion of mutant cells was observed, the former characterized by specific reorganization of cell adhesion and polarity proteins, the latter by complete cytoplasmic diffusion of these proteins. Among several candidate target genes tested, only the homeotic gene Abdominal-B was a target of PH in both ovarian and wing disc cells. Although overexpression of Abdominal-B was sufficient to cause cell segregation in the wing disc, epistatic analysis indicated that the presence of Abdominal-B is not necessary for expulsion of polyhomeotic mutant epithelial cells suggesting that additional POLYHOMEOTIC targets are implicated in this phenomenon.

Conclusion

Our results indicate that polyhomeotic mutations have a direct effect on epithelial integrity that can be uncoupled from overproliferation. We show that cells in an epithelium expressing different levels of POLYHOMEOTIC sort out indicating differential adhesive properties between the cell populations. Interestingly, we found distinct modalities between apical and basal expulsion of ph mutant cells and further studies of this phenomenon should allow parallels to be made with the modified adhesive and polarity properties of different types of epithelial tumors.     

Freeze-fracture replica studies of tight junctions in normal human bronchial epithelium

Using freeze-fracture techniques, tight junctional networks were observed in the human normal bronchial epithelium. They were morphologically classified into three types: type I was a loosely interconnected, most complicated network consisting of 7-11 roughly parallel wavy strands and situated between ciliated cells; type II was a randomly anastomosing, simple network made up of 2-4 strands and present between goblet cells; type III was an irregularly anastomosing network composed of 4-7 strands and located between a ciliated cell and a goblet cell. Type III junctions, when a goblet cell was strongly bulged, were located on the swollen ridge, the upper surface of which was separated by a deep groove from the bulged apical surface, around the lateral surface of the cell at the level of the luminal surface. The possible relation between the orientation of strands of these networks and extra- or intracellular stress was discussed.     

Dynamics and mechanical stability of the developing dorsoventral organizer of the wing imaginal disc

Shaping the primordia during development relies on forces and mechanisms able to control cell segregation. In the imaginal discs of Drosophila the cellular populations that will give rise to the dorsal and ventral parts on the wing blade are segregated and do not intermingle. A cellular population that becomes specified by the boundary of the dorsal and ventral cellular domains, the so-called organizer, controls this process. In this paper we study the dynamics and stability of the dorsal-ventral organizer of the wing imaginal disc of Drosophila as cell proliferation advances. Our approach is based on a vertex model to perform in silico experiments that are fully dynamical and take into account the available experimental data such as: cell packing properties, orientation of the cellular divisions, response upon membrane ablation, and robustness to mechanical perturbations induced by fast growing clones. Our results shed light on the complex interplay between the cytoskeleton mechanics, the cell cycle, the cell growth, and the cellular interactions in order to shape the dorsal-ventral organizer as a robust source of positional information and a lineage controller. Specifically, we elucidate the necessary and sufficient ingredients that enforce its functionality: distinctive mechanical properties, including increased tension, longer cell cycle duration, and a cleavage criterion that satisfies the Hertwig rule. Our results provide novel insights into the developmental mechanisms that drive the dynamics of the DV organizer and set a definition of the so-called Notch fence model in quantitative terms.     

Differential proliferation rates generate patterns of mechanical tension that orient tissue growth

Orientation of cell divisions is a key mechanism of tissue morphogenesis. In the growing Drosophila wing imaginal disc epithelium, most of the cell divisions in the central wing pouch are oriented along the proximal–distal (P–D) axis by the Dachsous‐Fat‐Dachs planar polarity pathway. However, cells at the periphery of the wing pouch instead tend to orient their divisions perpendicular to the P–D axis despite strong Dachs polarization. Here, we show that these circumferential divisions are oriented by circumferential mechanical forces that influence cell shapes and thus orient the mitotic spindle. We propose that this circumferential pattern of force is not generated locally by polarized constriction of individual epithelial cells. Instead, these forces emerge as a global tension pattern that appears to originate from differential rates of cell proliferation within the wing pouch. Accordingly, we show that localized overgrowth is sufficient to induce neighbouring cell stretching and reorientation of cell division. Our results suggest that patterned rates of cell proliferation can influence tissue mechanics and thus determine the orientation of cell divisions and tissue shape.     

Lattice-Based Model of Ductal Carcinoma In Situ Suggests Rules for Breast Cancer Progression to an Invasive State

Ductal carcinoma in situ (DCIS) is a heterogeneous group of non-invasive lesions of the breast that result from abnormal proliferation of mammary epithelial cells. Pathologists characterize DCIS by four tissue morphologies (micropapillary, cribriform, solid, and comedo), but the underlying mechanisms that distinguish the development and progression of these morphologies are not well understood. Here we explored the conditions leading to the emergence of the different morphologies of DCIS using a two-dimensional multi-cell lattice-based model that incorporates cell proliferation, apoptosis, necrosis, adhesion, and contractility. We found that the relative rates of cell proliferation and apoptosis governed which of the four morphologies emerged. High proliferation and low apoptosis favored the emergence of solid and comedo morphologies. In contrast, low proliferation and high apoptosis led to the micropapillary morphology, whereas high proliferation and high apoptosis led to the cribriform morphology. The natural progression between morphologies cannot be investigated in vivo since lesions are usually surgically removed upon detection; however, our model suggests probable transitions between these morphologies during breast cancer progression. Importantly, cribriform and comedo appear to be the ultimate morphologies of DCIS. Motivated by previous experimental studies demonstrating that tumor cells behave differently depending on where they are located within the mammary duct in vivo or in engineered tissues, we examined the effects of tissue geometry on the progression of DCIS. In agreement with our previous experimental work, we found that cells are more likely to invade from the end of ducts and that this preferential invasion is regulated by cell adhesion and contractility. This model provides additional insight into tumor cell behavior and allows the exploration of phenotypic transitions not easily monitored in vivo.     

The force and effect of cell proliferation

EMBO J 32: 2790–2803 doi:10.1038/emboj.2013.197; published online September102013The spatiotemporal control of cell divisions is a key factor in epithelial morphogenesis and patterning. Mao et al (2013) now describe how differential rates of proliferation within the Drosophila wing disc epithelium give rise to anisotropic tissue tension in peripheral/proximal regions of the disc. Such global tissue tension anisotropy in turn determines the orientation of cell divisions by controlling epithelial cell elongation.Oriented cell divisions play important roles in the establishment of the animal body plan by both influencing tissue morphogenesis and generating cellular diversity. Generally, the direction of the cell division plane is determined by the orientation of the mitotic spindle prior to cytokinesis. The observation that the mitotic spindle in most animal cell types aligns with the cell''s longest axis has led to the formulation of the ‘long-axis-rule'', postulating that cell shape anisotropy is the main determinant of spindle orientation (Minc et al, 2011). However, cell shape anisotropy is unlikely to be the only determinant since many cell types round up during mitosis, thereby losing their shape anisotropy and others do not follow the long-axis-rule at all. In such cases, division orientation is determined by the polarizing activity of biochemical signals originating from the environment (reviewed in Morin and Bellaïche, 2011). In addition, externally applied forces have also been suggested to control division orientation of single cells in culture independently from their effect on cell shape (Fink et al, 2011).Epithelial growth implies that cells divide parallel to the tissue plane with both daughter cells remaining integrated within the tissue. Although it has been recognized that defects in apico-basal polarity lead to spindle misalignment and disruption of epithelial architecture, the molecular mechanisms underlying this regulation are still unknown. Recent work in the Drosophila wing disc epithelium uncovered that the junctional proteins Scribbled and Discs large 1 (Dlg1) are required for proper spindle alignment parallel to the tissue plane (Nakajima et al, 2013). Similarly, in the Drosophila follicular epithelium, spindle orientation is dependent on the lateral localization of Dlg1, independently of its role in apico-basal polarity (Bergstralh et al, 2013). While such mechanisms ensure that cells divide parallel to the epithelial plane, other mechanisms must still be present to determine the orientation of the mitotic spindle within this plane.In the Drosophila wing disc epithelium, symmetric cell divisions preferentially align with the proximal-distal (PD) axis, thus elongating the organ along this axis (Baena-López et al, 2005). This preferential cell division orientation is determined by the Fat-Dachsous pathway, which promotes accumulation of the atypical myosin Dachs at PD cellular junctions. The polarized activity of Dachs in turn drives cell elongation along the PD axis, leading to a preferential orientation of the mitotic spindle along this axis (Mao et al, 2011). In this issue of The EMBO Journal, Mao et al (2013) report that while mitotic cells located in central regions of the wing disc indeed elongate and divide along the PD axis, cells located in the periphery (proximal edge) elongate and divide orthogonally to the PD axis (Figure 1). These results suggested some type of global planar tissue polarization in proximal regions of the wing disc overriding the local effects of Dachs on spindle orientation. By using laser ablation to reveal tissue tension, the authors showed that in peripheral/proximal regions of the wing disc, junctions oriented orthogonal to the PD axis (PD junctions) are under higher tension than junctions oriented along this axis (lateral junctions; Figure 1). This led them to hypothesize that anisotropic tissue tension might control division orientation of proximal wing cells. Through a combination of elegant genetic experiments and theoretical modelling, the authors then demonstrated that this global tension anisotropy in the proximal wing disc arises from higher cell division rates observed in central versus proximal regions of the wing disc. Furthermore, this apparent tension anisotropy causes concentric elongation of proximal wing disc cells orienting their mitotic spindle orthogonal to the PD axis (Figure 1).Open in a separate windowFigure 1Differential rates of cell division between distal (green) and proximal (red) regions of the Drosophila wing disc epithelium (1) give rise to global patterns of tension anisotropy within the tissue (2). This tension anisotropy promotes cell elongation along the main axis of tension, thereby controlling the orientation of cell division via cell shape anisotropies in proximal regions of the wing disc (3); D, distal; P, proximal.Collectively, these results demonstrate that differential proliferation rates within a tissue can generate global tension anisotropies, which promote cell shape changes that again influence cell division orientation. Further dissection of the mechanisms by which tissue tension controls cell division orientation will clarify if anisotropic tension controls division orientation solely through cell elongation, or if additional mechanosensing mechanisms exist that more directly convey tissue tension information to the mitotic spindle. It might also be worth exploring whether cell divisions along the main axis of tension within the wing disc affect global tension anisotropy, and whether the formation of anisotropic tension around areas of cell proliferation affects the rate of cell division therein. Such interplay between tissue tension anisotropy and cell division orientation/rate will likely be critical for maintaining physiological degrees of tissue tension and growth.In general, the work by Mao et al (2013) provides compelling evidence for a functional link between tissue tension and cell division orientation in a physiological relevant context, paving the way for future studies addressing the reciprocal relationship between these two aspects in tissue morphogenesis.     

Postembryonic development of the wing imaginal discs in the female wingless bagworm moth Eumeta variegata (Lepidoptera,Psychidae)

The process of wing disc development and degeneration in the bagworm moth Eumeta variegata was investigated histologically. Morphological differences between two sexes first appear in the penultimate (eighth) larval instar. In the male, wing discs proliferate rapidly in the penultimate larval instar and continue proliferating; a conspicuous peripodial epithelium forms in the last (ninth) larval instar. The hemopoietic organs break down in this stage and disappear completely by the prepupal stage. In the female, in contrast, the wing discs remain as in the previous (seventh) instar, without proliferation of cells inside. No peripodial epithelium forms in the penultimate instar or later. Hemopoietic organs are still attached to the wing discs in the last larval instar and the entire wing discs transform into a plain, thick epidermis in the prepupal period. It is suggested that the hemopoietic organs may prevent the wing discs from developing in E. variegata.     

Chironomus tentans epithelial cell lines sensitive to ecdysteroids, juvenile hormone, insulin and heat shock

A new culture medium, ZW, and the preparation of an extract of adult Drosophila, FX, are described, which for the first time allow the in vitro proliferation of normal Drosophila cells in the absence of undefined heterologous components. Cells from 6-hour-old Drosophila embryos can extensively differentiate and/or proliferate in ZW supplemented with FX and insulin. Cells isolated from wing discs of 90–120-hour-old larvae require ecdysterone for proliferation in ZW, in addition to FX and insulin. Explanted ovaries, testes, genital discs and intact or halved wing discs of 100-hour-old larvae grow in the same medium, at least in part due to cell proliferation. High concentrations of ecdysterone prevent differentiation and/or proliferation of cells from embryos and from wing discs and cause the lysis of most isolated imaginal disc cells grown in vitro, while cuticular differentiations are induced in wing discs and disc fragments grown in vitro.     

Cellular events within peripodial epithelia that accompany evagination of Manduca wing discs: Conversion of cuboidal epithelia to columnar epithelia

In the wing disc of Manduca, a sheet of peripodial epithelium completely covers the apical surface of another epithelium destined to form the wing blade. The cubodial cells of the peripodial epithelium not only are attached to a thick basal lamina but also their lateral and basal surfaces are highly convoluted and stain intensely with ruthenium red (RR). In contrast, the columnar cells of the wing epithelium lack both a basal lamina and RR-positive surfaces. During evagination, the RR-positive material disappears and the extent of lateral cell contact within the peripodial epithelium increases. Concurrently with this lateral “zippering”, the entire peripodial sheet contracts and slides over the wing blade epithelium, thereby exposing the wing to the external surface of the insect. Trypsin treatment of Manduca discs accelerates both evagination and the disappearance of RR-positive material from the surfaces of cells in the peripodial epithelium. Apparently contraction of the peripodial sheet and the increase in its lateral cell contacts is accompanied by the disappearance of acidic glycoproteins from its lateral and basal cell surfaces.     

Discontinuities in Rap1 activity determine epithelial cell morphology within the developing wing of Drosophila

Mechanisms that govern cell-fate specification within developing epithelia have been intensely investigated, with many of the critical intercellular signaling pathways identified, and well characterized. Much less is known, however, about downstream events that drive the morphological differentiation of these cells, once their fate has been determined. In the Drosophila wing-blade epithelium, two cell types predominate: vein and intervein. After cell proliferation is complete and adhesive cell-cell contacts have been refined, the vast majority of intervein cells adopt a hexagonal morphology. Within vein territories, however, cell-shape refinement results in trapezoids. Signaling events that differentiate between vein and intervein cell fates are well understood, but the genetic pathways underlying vein/intervein cyto-architectural differences remain largely undescribed. We show here that the Rap1 GTPase plays a critical role in determining cell-type-specific morphologies within the developing wing epithelium. Rap1, together with its effector Canoe, promotes symmetric distribution of the adhesion molecule DE-cadherin about the apicolateral circumference of epithelial cells. We provide evidence that in presumptive vein tissue Rap1/Canoe activity is down-regulated, resulting in adhesive asymmetries and non-hexagonal cell morphologies. In particular Canoe levels are reduced in vein cells as they morphologically differentiate. We also demonstrate that over-expression of Rap1 disrupts vein formation both in the developing epithelium and the adult wing blade. Therefore, vein/intervein morphological differences result, at least in part, from the patterned regulation of Rap1 activity.     

The Rap GTPase activator Drosophila PDZ-GEF regulates cell shape in epithelial migration and morphogenesis

Epithelial morphogenesis is characterized by an exquisite control of cell shape and position. Progression through dorsal closure in Drosophila gastrulation depends on the ability of Rap1 GTPase to signal through the adherens junctional multidomain protein Canoe. Here, we provide genetic evidence that epithelial Rap activation and Canoe effector usage are conferred by the Drosophila PDZ-GEF (dPDZ-GEF) exchange factor. We demonstrate that dPDZ-GEF/Rap/Canoe signaling modulates cell shape and apicolateral cell constriction in embryonic and wing disc epithelia. In dPDZ-GEF mutant embryos with strong dorsal closure defects, cells in the lateral ectoderm fail to properly elongate. Postembryonic dPDZ-GEF mutant cells generated in mosaic tissue display a striking extension of lateral cell perimeters in the proximity of junctional complexes, suggesting a loss of normal cell contractility. Furthermore, our data indicate that dPDZ-GEF signaling is linked to myosin II function. Both dPDZ-GEF and cno show strong genetic interactions with the myosin II-encoding gene, and myosin II distribution is severely perturbed in epithelia of both mutants. These findings provide the first insight into the molecular machinery targeted by Rap signaling to modulate epithelial plasticity. We propose that dPDZ-GEF-dependent signaling functions as a rheostat linking Rap activity to the regulation of cell shape in epithelial morphogenesis at different developmental stages.     

Ultrastructure of human blastocyst-endometrial interactions in vitro

The interactions of seven human blastocysts with cultured endometrial cells were investigated by light microscopy and transmission electron microscopy. Trophoblastic-endometrial contact was observed at the lateral border of endometrial epithelial cells where trophoblast and endometrial epithelial cells shared apical junctional complexes and desmosomes. The first sign of penetration was invasion of a trophoblastic cytoplasmic protrusion between endometrial epithelial cells. In broad contact areas, lateral displacement of endometrial epithelial cells and formation of a peripheral pseudostratified epithelium were observed. When trophoblastic cells were interposed fully among endometrial epithelial cells, they formed a penetration cone and appeared to dislodge endometrial epithelial cells from the stromal compartment. A single penetration cone only was found in each specimen. Endometrial or trophoblastic degeneration was not observed. Formation of multinucleate (>/= three nuclei per cell) trophoblast cells was not observed, but many cells displayed areas with abrupt disappearance of well-defined plasma membranes, which is indicative of syncytium formation. In this study, adhesion and penetration occurred at the same time. The human blastocysts penetrated the endometrial surface epithelium by intrusive penetration. Epithelial penetration was achieved primarily by cellular syncytiotrophoblast-like cells and the first indications of syncytium formation were observed simultaneously with penetration of the epithelium.     

Cell proliferation and DNA replication in the imaginal wing disc of Drosophila melanogaster

Cell proliferation in the imaginal wing disc of Drosophila has been analyzed by both pulse and chronic labeling with [3H]thymidine. We find neither spatial nor temporal variation in the fraction of S phase cells during the third instar. At or near the time of white prepupae formation the fraction of S phase cells falls sharply. Our chronic labeling experiments have demonstrated that almost all (and perhaps all) of the cells in a mid third instar wing disc are cycling. By examining sectioned material from such experiments we have found that the collumnar epithelial cell and the adepithetial cell populations become labeled with similar kinetics. The peripodial membrane cell population becomes labeled more slowly. We have also obtained estimates of cell cycle parameters for the imaginal wing disc cells.     

Egfr/Ras pathway mediates interactions between peripodial and disc proper cells in Drosophila wing discs

All imaginal discs in Drosophila are made up of a layer of columnar epithelium or the disc proper and a layer of squamous epithelium called the peripodial membrane. Although the developmental and molecular events in columnar epithelium or the disc proper are well understood, the peripodial membrane has gained attention only recently. Using the technique of lineage tracing, we show that peripodial and disc proper cells arise from a common set of precursors cells in the embryo, and that these cells diverge in the early larval stages. However, peripodial and disc proper cells maintain a spatial relationship even after the separation of their lineages. The peripodial membrane plays a significant role during the regional subdivision of the wing disc into presumptive wing, notum and hinge. The Egfr/Ras pathway mediates this function of the peripodial membrane. These results on signaling between squamous and columnar epithelia are particularly significant in the context of in vitro studies using human cell lines that suggest a role for the Egfr/Ras pathway in metastasis and tumour progression.