The Ventral Photoreceptor Cells of Limulus : I. The microanatomy

The ventral photoreceptor cells of Limulus polyphemus resemble the retinular cells of the lateral eyes both in electrical behavior and in morphology. Because of the great size of the ventral photoreceptor cells they are easy to impale with glass capillary micropipettes. Their location along the length of the ventral eye nerve makes them easy to dissect out and fix for electron microscopy. Each cell has a large, ellipsoidal soma that tapers into an axon whose length depends upon the distance of the cell from the brain. The cell body contains a rich variety of cytoplasmic organelles with an especially abundant endoplasmic reticulum. The most prominent structural feature is the microvillous rhabdomere, a highly modified infolding of the plasmalemma. The microvilli are tightly packed together within the rhabdomere, and quintuple-layered junctions are encountered wherever microvillar membranes touch each other. Glial cells cover the surface of the photoreceptor cell and send long, sheet-like projections of their cytoplasm into the cell body of the photoreceptor cell. Some of these projections penetrate the rhabdomere deep within the cell and form quintuple-layered junctions with the microvilli. Junctions between glial cells and the photoreceptor cell and between adjacent glial cells are rarely encountered elsewhere, indicating that there is an open pathway between the intermicrovillous space and the extracellular medium. The axon has a normal morphology but it is electrically inexcitable.     

Function of <Emphasis Type="Italic">Drosophila mob2</Emphasis> in photoreceptor morphogenesis

The Drosophila photoreceptor is a highly polarized cell; a mature photoreceptor cell in Drosophila contains a photosensitive structure (the rhabdomere) and a supporting membrane (stalk) at its apical membrane. In a screen to isolate genes involved in determining stalk and rhabdomere formation, this study has identified the Drosophila mob2 (Dmob2) gene. Dmob2 belongs to a Mob1/phocein domain protein family whose functions are involved in polarized cell growth and asymmetric cell fate determination in yeast. To study the role of Dmob2 in photoreceptor development, we have raised an antibody against the Dmob2 protein. An immunocytochemical study has shown that Dmob2 is mainly localized in the apical membrane of photoreceptor cells during early development. As development proceeds, Dmob2 is gradually confined to the rhabdomere base of the photoreceptor cells. RNA interference (RNAi) for knockdown Dmob2 expression during eye development impairs rhabdomere formation. Our study further shows that the subcellular localization of phosphorylated Moesin and Crumbs in the developing photoreceptor cell is disrupted in Dmob2 RNAi flies. This work thus reports a novel function of Dmob2 in photoreceptor cell development.     

The Actomyosin Machinery Is Required for Drosophila Retinal Lumen Formation

Multicellular tubes consist of polarized cells wrapped around a central lumen and are essential structures underlying many developmental and physiological functions. In Drosophila compound eyes, each ommatidium forms a luminal matrix, the inter-rhabdomeral space, to shape and separate the key phototransduction organelles, the rhabdomeres, for proper visual perception. In an enhancer screen to define mechanisms of retina lumen formation, we identified Actin5C as a key molecule. Our results demonstrate that the disruption of lumen formation upon the reduction of Actin5C is not linked to any discernible defect in microvillus formation, the rhabdomere terminal web (RTW), or the overall morphogenesis and basal extension of the rhabdomere. Second, the failure of proper lumen formation is not the result of previously identified processes of retinal lumen formation: Prominin localization, expansion of the apical membrane, or secretion of the luminal matrix. Rather, the phenotype observed with Actin5C is phenocopied upon the decrease of the individual components of non-muscle myosin II (MyoII) and its upstream activators. In photoreceptor cells MyoII localizes to the base of the rhabdomeres, overlapping with the actin filaments of the RTW. Consistent with the well-established roll of actomyosin-mediated cellular contraction, reduction of MyoII results in reduced distance between apical membranes as measured by a decrease in lumen diameter. Together, our results indicate the actomyosin machinery coordinates with the localization of apical membrane components and the secretion of an extracellular matrix to overcome apical membrane adhesion to initiate and expand the retinal lumen.     

The Drosophila bifocal gene encodes a novel protein which colocalizes with actin and is necessary for photoreceptor morphogenesis.

Photoreceptor cells of the Drosophila compound eye begin to develop specialized membrane foldings at the apical surface in midpupation. The microvillar structure ultimately forms the rhabdomere, an actin-rich light-gathering organelle with a characteristic shape and morphology. In a P-element transposition screen, we isolated mutations in a gene, bifocal (bif), which is required for the development of normal rhabdomeres. The morphological defects seen in bif mutant animals, in which the distinct contact domains established by the newly formed rhabdomeres are abnormal, first become apparent during midpupal development. The later defects seen in the mutant adult R cells are more dramatic, with the rhabdomeres enlarged, elongated, and frequently split. bif encodes a novel putative protein of 1063 amino acids which is expressed in the embryo and the larval eye imaginal disc in a pattern identical to that of F actin. During pupal development, Bif localizes to the base of the filamentous actin associated with the forming rhabdomeres along one side of the differentiating R cells. On the basis of its subcellular localization and loss-of-function phenotype, we discuss possible roles of Bif in photoreceptor morphogenesis.     

The Eyes of Mesostoma ehrenbergi (Focke, 1836) (Platyhelminthes,Rhabdocoela). Fine Structure and Photoreceptor Membrane Turnover

Abstract Each pigment-cup eye of Mesostoma ehrenbergi consists of two photoreceptor cells, the anterior cell being bilobate. the posterior almost linear, and of a multicellular pigment cup. The nuclei of the photoreceptor cells are located inside the medial region of the brain. Thin cytoplasmic photoreceptor projections provided with neurosecretory-like granules are interposed between the inner surface of the eye cup and the distal extremity of the microvilli. The breakdown and renewal of microvillar membranes was analysed. Membrane turnover is a continuous process. At dusk and during the night abscission of photoreceptive membranes occurs. At dawn the membrane fragments are degraded to granular material, which is then endocytosed into the submicrovillar cytoplasm as coated vesicles. These vesicles form multivesicular bodies. The degradation of multivesicular body content occurs during the following light hours. The dark period is correlated with membrane synthesis for elongation of reticular membranes, which are converted into ellipsoid bodies. The formation of new microvillar membranes occurs at the base of the microvillar border, and involves the fusion with the old microvillar membranes of small vesicles detached from the tubular endoplasmic membranes and from the flattened concentric cisternae of ellipsoid bodies. The correlations with daily cycles of other invertebrates are discussed.     

Actin filaments and photoreceptor membrane turnover

The shape and turnover of photoreceptor membranes appears to depend on associated actin filaments. In dipterans, the photoreceptor membrane is microvillar. It is turned over by the addition of new membrane at the bases of the microvilli and by subsequent shedding, mostly from the distal ends. Each microvillus contains actin filaments as a component of its cytoskeletal core. Two myosin I-like proteins co-localize with the actin filaments. It is suggested that one of the myosin I-like proteins might be linked to the microvillar membrane. By interacting with the actin filaments, this motor should move the membrane of a microvillus in a distal direction, thus providing a possible mechanism for the turnover of the membrane. A vertebrate photoreceptor cell contains a small cluster of actin filaments in its connecting cilium at the site where new transductive disk membranes are formed. Disruption of the actin filaments perturbs disk morphogenesis. The most likely explanation for this perturbation is that the process of initiating a new disk is inhibited. Conventional myosin (myosin II) is found in the connecting cilium with the same distribution as actin. A simple model is proposed to illustrate how the actin-myosin system of the connecting cilium might function to initiate the morphogenesis of a disk membrane.     

Localisation of actin, villin, fimbrin, ezrin and ankyrin in rat taste receptor cells

Mammalian taste buds consist of 50–150 pear- or spindle-shaped taste receptor cells which contain, at their apical cell surface, a bundle of microvillar projections. The microvilli probably serve to increase the receptive membrane surface of the chemosensory receptor cells. The molecular basis controlling the ultrastructure of taste receptor microvilli is present unknown. In the present study we analysed, by immunostaining at the light and electron microscopic levels and by immunoblotting, components of the cytoskeleton of these microvilli. We show here that taste cell microvilli contain the major cytoskeletal proteins of intestinal microvilli, actin, fimbrin and villin. Another actin-binding, peripheral membrane protein of intestinal microvilli, ezrin, was also localised to taste cell microvilli, where ezrin might play a role, for example, in placement of specific membrane proteins to the microvillus membrane. In search of further linkage proteins, we found ankyrin localised along the basolateral cell surface of taste receptor cells, where ankyrin might be involved in the immobilisation of the Na⁺, K⁺-ATPase or other ion-translocating proteins of taste cells to the membrane cytoskeleton. Accepted: 26 April 1999     

Dynactin affects extension and assembly of adherens junctions in<Emphasis Type="Italic">Drosophila</Emphasis> photoreceptor development

Drosophila eye development is a progressive process including cell fate determination, pattern formation, and rhabdomere morphogenesis. During eye development, a dramatic change in cell shape, which involves turning and extension of the photoreceptor apical surface, occurs in the early pupal stages. It is known that assembly and extension of adherens junctions (AJs) play an important role in this process. In the present study, I show that mutation of the largest subunit of dynactin complexes encoded byGlued (GI) affects the extension and assembly of Ajs in developing photoreceptors. InGl ¹/+ mutants and transgenic flies expressing the dominant negative form of Glued, the AJs failed to properly assemble and extend. In addition, the morphogenesis of rhabdomeres was also affected in these flies. Taken together, these results suggest that the extension and assembly of AJs as well as determination of the rhabdomere domain in photoreceptor development areGl dependent.     

Localization of Na/K-ATPase in developing and adult Drosophila melanogaster photoreceptors

Drosophila melanogaster photoreceptors are highly polarized cells and their plasma membrane is organized into distinct domains. Zonula adherens junctions separate a smooth peripheral surface, the equivalent of the basolateral surface in other epithelial cells, from the central surface (approximately equal to apical surface). The latter consists of the microvillar rhabdomere and the juxtarhabdomeric domain, a nonmicrovillar area between the rhabdomere and the zonulae adherens. The distribution of Na/K-ATPase over these domains was examined by immunocytochemical, developmental, and genetic approaches. Immunofluorescence and immunogold labeling of adult compound eyes reveal that the distribution of Na/K-ATPase is concentrated at the peripheral surface in the photoreceptors R1-R6, but extends over the juxtarhabdomeric domain to the rhabdomere in the photoreceptors R7/R8. Developmental analysis demonstrates further that Na/K-ATPase is localized over the entire plasma membrane in all photoreceptors in early pupal eyes. Redistribution of Na/K-ATPase in R1-R6 occurs at about 78% of pupal life, coinciding with the onset of Rh1-rhodopsin expression on the central surface of these cells. Despite the essential role of Rh1 in structural development and intracellular trafficking, Rh1 mutations do not affect the distribution of Na/K-ATPase. These results suggest that Na/K-ATPase and rhodopsin are involved in distinct intracellular localization mechanisms, which are maintained independent of each other.     

Moesin contributes an essential structural role in Drosophila photoreceptor morphogenesis

Ezrin-Radixin-Moesin (ERM) family proteins organize heterogeneous sub-plasma membrane protein scaffolds that shape membranes and their physiology. In Drosophila oocytes and imaginal discs, epithelial organization, fundamental to development and physiology, is devastated by the loss of Moesin. Here, we show that Moesin is crucial for Drosophila photoreceptor morphogenesis. Beyond its requirement for retinal epithelium integrity, Moesin is essential for the proper assembly of the apical membrane skeleton that builds the photosensitive membrane, the rhabdomere. Moesin localizes to the rhabdomere base, a dynamic locus of cytoskeletal reorganization and membrane traffic. Downregulation of Moesin through RNAi or genetic loss of function profoundly disrupts the membrane cytoskeleton and apical membrane organization. We find normal levels and distribution of Moesin in photoreceptors of a Moesin mutant previously regarded as protein null, suggesting alternative interpretations for studies using this allele. Our results show an essential structural role for Moesin in photoreceptor morphology.     

Ultrastructural changes of the microvillar cytoskeleton in the photoreceptor of the crayfish Orconectes limosus related to different adaptation conditions

In the retina of crayfish microvilli of seven of the eight photoreceptor cells build highly organized structures, the rhabdoms. Cytoskeletal elements inside the microvilli were investigated in conventional and slightly extracted electron microscopical preparations. In conventional preparations the ultrastructure of these cytoskeletal elements depended on the adaptational state of the animal. They appeared as central filament-like structures inside each microvillus when dark-adapted retinae were prepared and fixed at night in the absence of calcium. Changes of these conditions (light, daytime, or calcium concentration) impaired the detectability of these central filaments; in light-adapted eyes prepared at midday they were rarely seen. Nevertheless, single microvillar filaments were present in light-adapted retinae after mild cell permeabilization with the saponin beta-escin. They appeared as a regular structure in each microvillus, often attached to the membrane. Their fine structure was consistent with the ultrastructure of single actin filaments as indicated by fast-Fourier-analysis and further supported by the presence of anti-actin immunoreactivity in electron microscopical and immunocytochemical preparations. These results indicate that microvillar filaments are not necessarily destroyed by light as previously described; we suggest that their appearance inside the microvillus might be altered by the properties of associated, maybe sidearm-like proteins.     

Role of Spastin in Apical Domain Control along the Rhabdomere Elongation in Drosophila Photoreceptor

Background

Mutations in spastin are the most common cause of hereditary spastin paraplegia, a neurodegenerative disease. In this study, the role of spastin was examined in Drosophila photoreceptor development.

Methodology/Principal Findings

The spastin mutation in developing pupal eyes causes a mild mislocalization of the apical membrane domain at the distal section, but the apical domain was dramatically reduced at the proximal section of the developing pupal eye. Since the rhabdomeres in developing pupal eyes grow from distal to proximal, this phenotype strongly suggests that spastin is required for apical domain maintenance during rhabdomere elongation. This role of spastin in apical domain modulation was further supported by spastin''s gain-of-function phenotype. Spastin overexpression in photoreceptors caused the expansion of the apical membrane domain from apical to basolateral in the developing photoreceptor. Although the localizations of the apical domain and adherens junctions (AJs) were severely expanded, there were no defects in cell polarity.

Conclusions/Significance

These results strongly suggest that spastin is essential for apical domain biogenesis during rhabdomere elongation in Drosophila photoreceptor morphogenesis.     

Essential function of Drosophila Sec6 in apical exocytosis of epithelial photoreceptor cells

Polarized exocytosis plays a major role in development and cell differentiation but the mechanisms that target exocytosis to specific membrane domains in animal cells are still poorly understood. We characterized Drosophila Sec6, a component of the exocyst complex that is believed to tether secretory vesicles to specific plasma membrane sites. sec6 mutations cause cell lethality and disrupt plasma membrane growth. In developing photoreceptor cells (PRCs), Sec6 but not Sec5 or Sec8 shows accumulation at adherens junctions. In late PRCs, Sec6, Sec5, and Sec8 colocalize at the rhabdomere, the light sensing subdomain of the apical membrane. PRCs with reduced Sec6 function accumulate secretory vesicles and fail to transport proteins to the rhabdomere, but show normal localization of proteins to the apical stalk membrane and the basolateral membrane. Furthermore, we show that Rab11 forms a complex with Sec5 and that Sec5 interacts with Sec6 suggesting that the exocyst is a Rab11 effector that facilitates protein transport to the apical rhabdomere in Drosophila PRCs.     

Reversible ultrastructural changes in the rhabdom of the locust eye are induced by long term light deprivation

Summary Quantitative electron microscopic analysis of the compound eyes of locusts (Schistocerca gregaria) subjected to long term light deprivation showed that disorganization of rhabdomal microvillus structure and disruption of rhabdomere fusion were significantly more prevalent in deprived animals than in controls. These structural changes accompanied a reduction in sensitivity to photic stimulation in the deprived eyes. The disorganization of microvillus structure was reversible after 14 days recovery in light while the disruption of rhabdomere fusion was irreversible. Deprivation also resulted in an irreversible increase in number of ommatidia bearing fewer than normal retinula cells. These results are consistent with disruption by light deprivation of some aspect of normal photoreceptor membrane synthesis or degradation.We thank Ms. Irene Kwan for her excellent technical assistance, Dr. H. Silverman for useful discussions through all stages of this study, and Drs. H. Injeyan and S. Tobe for supplying the hatchling locusts. This work was supported by Ontario Graduate Fellowships to J.W.B. and a National Research Council of Canada operating grant to H.L.A.     

Immuno-electronmicroscopical localization of a microvillus membrane disaccharidase in the human small-intestinal epithelium with monoclonal antibodies

The cellular localization of the human intestinal disaccharidase, sucrase-isomaltase, was visualized in ultrathin cryosections by the use of specific monoclonal antibodies [25] followed by protein A-gold. The principle site of immunoreaction concerned the microvillus membrane, which supports current concepts of the localization of these hydrolases. One antibody against sucrase-isomaltase also showed labeling of the Golgi apparatus, apical vesicles, and lysosomes, but not of the basolateral membrane. The labeling of the Golgi complex was uniform, suggesting the absence of accumulation of sucrase-isomaltase in cisternae during its passage through this organelle. Absence of labeling of the basolateral membrane appears to support the view that newly synthesized sucrase-isomaltase is transferred directly from the Golgi complex to the microvillus membrane, bypassing the basolateral membrane. However, the results do not exclude the possibility of a very rapid passage through the basolateral membrane. A substantial fraction of the sucrase-isomaltase occurred in lysosomes, which indicates that this organelle plays a major role in the catabolism of microvillar hydrolases. Transport of sucrase-isomaltase to lysosomes might occur by endocytosis or via the crinophagic pathway. The latter was previously postulated to reflect a regulatory mechanism at the post-Golgi level for the surface expression of microvillar membrane proteins.     

Drosophila melanogaster Cad99C, the orthologue of human Usher cadherin PCDH15, regulates the length of microvilli

Actin-based protrusions can form prominent structures on the apical surface of epithelial cells, such as microvilli. Several cytoplasmic factors have been identified that control the dynamics of actin filaments in microvilli. However, it remains unclear whether the plasma membrane participates actively in microvillus formation. In this paper, we analyze the function of Drosophila melanogaster cadherin Cad99C in the microvilli of ovarian follicle cells. Cad99C contributes to eggshell formation and female fertility and is expressed in follicle cells, which produce the eggshells. Cad99C specifically localizes to apical microvilli. Loss of Cad99C function results in shortened and disorganized microvilli, whereas overexpression of Cad99C leads to a dramatic increase of microvillus length. Cad99C that lacks most of the cytoplasmic domain, including potential PDZ domain-binding sites, still promotes excessive microvillus outgrowth, suggesting that the amount of the extracellular domain determines microvillus length. This study reveals Cad99C as a critical regulator of microvillus length, the first example of a transmembrane protein that is involved in this process.     

Ultrastructural study of sensory cells of the proboscidial glandular epithelium of Riseriellus occultus (Nemertea,Heteronemertea)

Only one sensory cell type has been observed within the glandular epithelium of the proboscis in the heteronemertine Riseriellus occultus. These bipolar cells are abundant and scattered singly throughout the proboscis length. The apical surface of each dendrite bears a single cilium enclosed by a ring of six to eight prominent microvilli. The cilium has the typical 9×2 + 2 axoneme arrangement and is equipped with a cross-striated vertical rootlet extending from the basal body. No accessory centriole or horizontal rootlet was observed. Large, modified microvilli (stereovilli) surrounding the cilium are joined together by a system of fine filaments derived from the glycocalyx. Each microvillus contains a bundle of actin-like filaments which anchor on the indented inner surface of a dense, apical ring situated beneath the level of the ciliary basal body. The tip of the cilium is expanded and modified to form a bulb-like structure which lies above the level where the surrounding microvilli terminate. In the region where the cilium emerges from the microvillar cone, the membrane of the microvillar apices makes contact with a corresponding portion of the ciliary membrane. At this level microvilli and cilium are apparently firmly linked by junctional systems resembling adherens junctions. The results suggest that these sensory cells may be mechanoreceptors. © 1996 Wiley-Liss, Inc.     

Effect of colchicine on rat small intestinal absorptive cells. I Formation of basolateral microvillus borders

Treatment of rats with colchicine (0.5 mg/100 g of body weight) for more than 3 hr causes formation of microvillus borders along lateral and basal surfaces of absorptive cells in the small intestine. Morphologically, these strongly resemble the apical brush border inclusive of the terminal-web region. Formation of basolateral microvilli is restricted to mature absorptive cells. At 6 hr after administration of colchicine, 3.47% (+/- 1.94%) of the basolateral cell surfaces exhibit "implantation" of microvillus borders. The results show that colchicine induces formation of surface differentiations at lateral and basal surface regions that are restricted to the apical cell surface in controls. Redistribution of constituents of the plasma membrane from apical to basolateral membrane portions, as well as rearrangement in the organization of microfilaments can be considered to underlie formation of basolateral microvillus borders. From the antimicrotubular effect of colchicine it may be deduced that microtubules exert a regulative function in the formation of surface differentiations on absorptive cells of the small intestine and in the maintenance of the polarity of the cells.     

The local deletion of a microvillar cytoskeleton from photoreceptors of tipulid flies during membrane turnover

The distal regions of the photoreceptor microvilli of tipulid flies are shed to extracellular space during membrane turnover. Before abscission, the microvillar tips undergo a transformation: they become deformed, and after conventional fixation for electron microscopy are relatively electron-lucent compared to the stable, basal microvillar segments. We now show that the electron-lucent segment is an empty bag of membrane whose P-face after freeze-etch preparation appears as densely particulate as the remainder of the microvillus. Transformation is achieved by the local deletion of a microvillar cytoskeleton which consists of a single, axial filament linked to the plasma membrane by side-arms. The filament may be partially preserved by the chelation of Ca2+; the provision of a divalent cation (Mg2+ or Ba2+) stabilizes the side-arms during subsequent fixation, as has been shown previously for the rhabdomeral cytoskeleton of blowflies. Incubation of the isolated retina in the presence of 0.25 mM Ca2+ at room temperature for 10-20 min causes proteolysis of the cytoskeleton which is blocked by as little as 0.5 mM of the thiol protease inhibitors Ep-475 and Ep-459. Loss of the cytoskeleton is accompanied by deformation of all regions of the microvilli. Local deletion of the cytoskeleton from the transformed zone of the normal rhabdom is sufficient to explain deformation of the microvillar tips, but not their subsequent abscission. The intimate association between a Ca2+-activated thiol protease and the cytoskeleton implied by the great rapidity of proteolysis calls for a reassessment of published studies of membrane turnover by radioautography, and of the nature of light-induced damage to arthropod photoreceptor membranes.     

Exocytotic shedding and glial uptake of photoreceptor membrane by a salticid spider.

Receptors in the anterior lateral eyes of salticid spiders possess paired rhabdomeres. The tips of the rhabdomeral microvilli lie adjacent to non-pigmented glial processes. Photoreceptor membrane is lost during turnover by a hitherto undescribed process: individual microvilli lengthen at their tips, taper, and are received by corresponding, coated endocytotic pits in the glial membrane. Pits detach as coated vesicles with coherent fragments of microvilli within them, lose their coats, and accumulate in the glial processes as disorderly membranous detritus. Some microvillus membrane disintegrates before local endocytosis, and appears to get into the glial arms distant from the parent rhabdomere by invaginations which are either endocytotic clefts or a tubulo-cisternal system, but whose precise nature is not yet clear. No photoreceptor membrane is lost by pinocytosis into the receptor cytoplasm. Analogies between the behaviour of this system and the phagocytosis of shed vertebrate photoreceptor membrane are briefly discussed.