The cytoskeletal architecture of interdigitated microvilli in the photoreceptors of some nocturnal spiders

Summary The photoreceptor microvilli of some nocturnal spiders (Isopeda andOlios in theSparassidae, andClubiona in theClubionidae) are wide (80–140 nm), and microvilli from adjacent receptors are interdigitated. Because microvillar diameters are relatively large in relation to the thicknesses of thin sections, it is possible to examine cytoskeletal structures closely associated with the microvillar plasmalemmae directly.Retinae were treated with a specific inhibitor of cysteine proteases before primary fixation for electron microscopy in a Ca²⁺-chelating medium. Cytoskeletal components were stabilized with tannic acid. A variety of microvillar profiles was obtained, consistent with an assumption that they represent imperfect preservation of anin vivo plasmalemmal undercoat, inferred to consist of longitudinally-disposed microfilaments, presumptively bonded to the microvillar plasmalemma. The microvillar lumen is inferred to be empty of cytoskeletal components in life.This model is discussed in terms of 1. the cytoskeletal organisation of microvilli of the primitive photoreceptors of a leech (Blest et al. 1983), where the arrangement of microfilaments resembles that in the vertebrate intestinal brush-border; 2. the large complement of membrane-associated oligomeric actin in rhabdoms of crayfish, where identifiable microfilaments cannot be resolved within microvilli by transmission electron microscopy (de Couet et al. 1984), and a single visualizable axial filament of uncertain composition is linked to the plasmalemma by side-arms.     

Photoreceptor membrane breakdown in the spider Dinopis: GERL differentiation in the receptors

Summary In the spider Dinopis, retinae of the posterior median eyes synthesise new photoreceptor membrane in bulk at dusk and destroy it at dawn (Blest, 1978). During the dawn period, there is a rapid, anticipatory differentiation of unusual organelles from the rough endoplasmic reticulum (RER) in the intermediate segments of the receptors. This system is classified as GERL. Its products appear to play a role in the autolysis of photoreceptor membrane. Consistent topographical relationship to Golgi bodies has not been determined. Circumscribed regions of RER whorls first reorganise to yield fenestrated profiles; these differentiate further to a number of structures by condensation and loss of ribosomes. Smooth tubular profiles are termed rigid tubules to indicate their probable homology with the rigid lamellae of vertebrate secretory cells. More complex smooth multilocular bodies are also produced. Evidence is discussed which implies that both rigid tubules and multilocular bodies give rise to condensing vacuoles. These, in turn, pinch off coated vesicles assembled as Nebenkerne. Some rigid tubules are transported to the interrhabdomeral cytoplasm of the receptive segments. At late stages of differentiation, rigid tubules, multilocular bodies and Nebenkerne give strong, positive responses to zinc iodide-osmium tetroxide (ZIO) treatment; early stages and both cis and trans Golgi components do not. GERL differentiation is independent of immediate illumination of the retina at dawn. It is suggested to mediate the lysis of membrane degradation products by the production of hydrolases.We thank Professor D.T. Anderson F.R.S. for our use of field facilities at the Crommelin Biological Field Station of Sydney University at Warrah, Pearl Beach, N.S.W., and Andrew and Sally Austin and Sally Stowe for help in the field. We are indebted to Rod Whitty and the Electron Microscopy Unit for advice and support throughout these studies     

A labile,Ca2+-dependent cytoskeleton in rhabdomeral microvilli of blowflies

Summary Rhabdomeral microvilli of photoreceptors of the blowfly Lucilia are shown to contain a cytoskeleton. An axial filament ( 6–11 nm) in each microvillus is inserted into a terminal cap distally, and into a plug filling the narrow neck of the microvillus proximally. In some states, the axial filament projects beyond the neck; within the microvillus it is surrounded by amorphous material. Together, they form an axial complex, which supports side-arms linking it to the plasma membrane. Conventional fixation for examination with the electron microscope destroys the cytoskeleton. To preserve it, retinae are pre-treated with a Ringer's solution buffered with 20 mM imidazole and containing, minimally, the following components: (i) a protease inhibitor, usually phenylmethylsulphonyl-fluoride (PMSF); (ii) either the Ca²⁺-chelator EGTA, or the calmodulin-blocking agent trifluoperazine (TFP); and (iii) a source of divalent cations to preserve the side-arms. When EGTA is used, Mg²⁺, Sr²⁺, Ba²⁺, Mn²⁺ and Co²⁺ are effective, Ba²⁺ giving the most satisfactory contrast, and Mg²⁺ and Co²⁺ the best preservation. It is inferred that the cytoskeletal complex includes at least one Ca²⁺-activated protease, and possibly calmodulin. Microvilli are bonded together by intermicrovillar bridges with a periodicity of 11–17nm. The cytoskeleton is destroyed by pretreatment with 1 mM dithiothreitol (DTT), possibly by the activation of a thiol protease. It does not survive osmication unless treated with low molecular weight tannic acid (LMWT). The evidence does not discriminate between actin and intermediate filaments as the basis of the cytoskeleton. Attention is drawn to similarities and differences between the rhabdomeral cytoskeleton and that of vertebrate intestinal brush-borders. The extreme lability of the rhabdomeral cytoskeleton to conventional methods of fixation is attributed in part to the Ca²⁺ fluxes experienced by invertebrate photoreceptors, and in part to the effects of osmication.The authors thank Dr. Lindsay Barton-Brown and Tom Van Gerwen for supplying flies from CSIRO cultures: Smith Kline and French Laboratories Ltd., French's Forest, N.S.W. for a generous gift of trifluoperazine, and Mallinckrodt, Inc., St. Louis, Missouri, USA, for a gift of low molecular weight tannic acid. Many colleagues, especially Richard Payne, Steve Shaw and Gert De Couet helped by discussing the results. George Weston and the staff of the Electron Microscope Unit provided support and advice. Sandy Smith prepared Table 1     

Effect of Metalaxyl on the incidence and severity of Pearl millet downy mildew disease in Northern Nigeria

Pearl millet downy mildew (DM) incidence, severity and yield losses of two pearl millet varieties (local and improved) due to the disease were determined in the field. Significant differences in the disease incidence and severity were recorded in the plots sown with metalaxyl-treated seeds and those sown with non-treated seeds, indicating the efficacy of the fungicide on the fungus. Yield losses due to non-treatment of seeds with metalaxyl was 40.88 and 45.39% in a local variety and 43.00 and 18.60% in an improved variety in the 2000 and 2001 cropping seasons respectively. Significant differences between plots sown with metalaxyl-treated and those sown with non-treated seeds were obtained for other yield components such as 1000-grains weight, panicle length and weight.     

Gene expression and the evolution of phenotypic diversity in social wasps

Background  

Organisms are capable of developing different phenotypes by altering the genes they express. This phenotypic plasticity provides a means for species to respond effectively to environmental conditions. One of the most dramatic examples of phenotypic plasticity occurs in the highly social hymenopteran insects (ants, social bees, and social wasps), where distinct castes and sexes all arise from the same genes. To elucidate how variation in patterns of gene expression affects phenotypic variation, we conducted a study to simultaneously address the influence of developmental stage, sex, and caste on patterns of gene expression in Vespula wasps. Furthermore, we compared the patterns found in this species to those found in other taxa in order to investigate how variation in gene expression leads to phenotypic evolution.     

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.