Sensory organs in a cavernicolous insect after cryofixation without cryoprotectants: a comparative ultrastructural study

Three different sensory organs (one mechanoreceptor, one chemoreceptor and one chemo-mechanoreceptor) of the antennae of the cavernicolous Coleoptera Speonomus hydrophilus and S. zophosinus have been compared by means of electron microscopy after chemical fixation or cryofixation without cryoprotectant; when cryofixation succeeds, cells and organelles have a different appearance from the chemically fixed ones: they have rounded and smooth outlines and are more electron-dense; some very fine details, such as tubulinc sub-units of microtubules, are perceptible after cryofixation only. However, chemical fixation gives much more reproducible results than cryofixation; moreover, when good cryofixation is achieved preservation of cells and organelles is satisfactory only for the peripheral region; large ice-crystals more or less destroying the central zone, except the nerves. In short, chemical fixation and cryofixation appear as complementary techniques: chemical fixation must be used as a routine fixation and cryofixation when specially good cell and molecular preservation must be achieved for peripheral tissues only.     

The fine structure of sublingual gland acinar cells of the Mongolian gerbil,Meriones unguiculatus,processed by rapid freezing followed by freeze-substitution fixation

Summary We compare the ultrastructure of the gerbil sublingual gland as seen after cryofixation followed by substitution with osmium tetroxide, with the more familiar appearance of material processed by glutaraldehyde-osmium chemical fixation. After primary cryofixation of fresh salivary glands, the nuclei of the mucous cells are found to be spherical in shape and, rather than being displaced toward the cell base, occupy a nearly central position in the cytoplasm, even in the storage phase of the secretory cycle. The mucous secretory granules are seen as membrane-limited inclusions, only rarely partially fused to each other. In both mucous and serous cells the Golgi cisterns have numerous large fenestrae which are aligned to form cytoplasmic channels which extend across the stack.     

Immunohistochemical demonstration of hyaluronan and its possible involvement in axolotl neural crest cell migration

Hyaluronan (HA), an extracellular matrix component, is involved mainly in the control of cell proliferation, neural crest and tumor cell migration, and wound repair. We investigated the effect of hyaluronan on neural crest (NC) cell migration and its ultrastructural localization in dark (wild-type) and white mutant embryos of the Mexican axolotl (Ambystoma mexicanum, Amphibia). The axolotl system is an accepted model for studying mechanisms of NC cell migration. Using a biotinylated hyaluronan binding protein (HABP), major extracellular matrix (ECM) spaces, including those of NC cell migration, reacted equally positive on cryosections through dark and white embryos. Since neural crest-derived pigment cells migrate only in subepidermal spaces of dark embryos, HA does not seem to influence crest cell migration in vivo. However, when tested on different alternating substrates in vitro, migrating NC cells in dark and white embryos prefer HA to fibronectin. In vivo, such an HA migration stimulating effect might exist as well, but be counteracted to differing degrees in dark and white embryos. The ultrastructural localization of HA was studied by means of transmission electron microscopic immunohistochemistry using HABP and different protocols of standard chemical fixation, cryofixation, embedding, and immunolabeling. The binding reaction of HA to HABP was strong and showed an equal distribution throughout ECM spaces after both standard chemical fixation/freeze substitution and cryofixation. A preference for the somite or subepidermal side was not observed. Following standard fixation/freeze substitution HABP-labeled "honeycomb"-like networks reminiscent of fixation artifacts were more prominent than labeled fibrillar or irregular net-like structures. The latter predominated in adequately frozen specimens following high-pressure freezing/freeze substitution. For this reason fibrillar or irregular net-like structures very likely represent hyaluronan in the complex subepidermal matrix of the axolotl embryo in its native arrangement.     

The combination of chemical fixation procedures with high pressure freezing and freeze substitution preserves highly labile tissue ultrastructure for electron tomography applications

The emergence of electron tomography as a tool for three dimensional structure determination of cells and tissues has brought its own challenges for the preparation of thick sections. High pressure freezing in combination with freeze substitution provides the best method for obtaining the largest volume of well-preserved tissue. However, for deeply embedded, heterogeneous, labile tissues needing careful dissection, such as brain, the damage due to anoxia and excision before cryofixation is significant. We previously demonstrated that chemical fixation prior to high pressure freezing preserves fragile tissues and produces superior tomographic reconstructions compared to equivalent tissue preserved by chemical fixation alone. Here, we provide further characterization of the technique, comparing the ultrastructure of Flock House Virus infected DL1 insect cells that were (1) high pressure frozen without fixation, (2) high pressure frozen following fixation, and (3) conventionally prepared with aldehyde fixatives. Aldehyde fixation prior to freezing produces ultrastructural preservation superior to that obtained through chemical fixation alone that is close to that obtained when cells are fast frozen without fixation. We demonstrate using a variety of nervous system tissues, including neurons that were injected with a fluorescent dye and then photooxidized, that this technique provides excellent preservation compared to chemical fixation alone and can be extended to selectively stained material where cryofixation is impractical.     

Methods of quick-freezing and cryosubstitution of biological tissues in analytical ion microscopy

The localization and relative concentration of diffusible ions (Li+, K+) or bound but easily displaceable ions (Ca2+) have been studied in myocardium prepared by rapid-freeze fixation and compared with results from chemically prepared samples. Contrary to chemical fixation which gives diffused potassium imaging, cryofixation enables elemental precise mapping in cellular compartment. Bound displazable external calcium, extracted by chemical fixation, is visualized after rapid-freeze fixation. Its localization is distinguished by a bright cellular outline, which corresponds to the glycocalix. Intracellular calcium is less emissive and has the same distribution and concentration whatever the sample preparation. Very movable and present at low concentration in tissues, lithium is localized after rapid-freeze fixation. Those qualitative and quantitative results show the adequation of rapid freeze fixation and freeze substitution to the study of diffusible ions by means of analytical ion microscopy.     

Total Wiring Length Minimization of C. elegans Neural Network: A Constrained Optimization Approach

Using the most recent data on the connectivity of the C. elegans neural network, we find optimal two-dimensional positions of interneurons that minimize the total wiring length provided that the positions of motor and sensory neurons are fixed. The rationale behind fixing motor and sensory neurons is the following: while positions of motor and sensory neurons can be influenced by the locations of muscles and sensory organs they are attached to, the main function of interneurons is to connect other neurons, and their placement could try to minimize the wiring length. Solutions for l ¹, l ² and squared l ²–norm were obtained. For the Euclidean norm l ², the relative and absolute difference between the real and optimal total wiring lengths is minimal among these functions of distance. Additional network constraints were discussed such as assignment of different weights to electrical or chemical connections, fixation of “tail” interneurons, minimal interneural distance limitation, and others. These constraints were compared by their influence on the optimal positions of interneurons.     

Formalin as a Hardener of Photographic Emulsions to Facilitate Staining of Epon Sections after Autoradiography

We have performed a computer assisted image analysis evaluation of the effects of two preparation protocols on morphological variables and immunolabeling density of secretory granules using rat adenohypophysis as a model. Glutaraldehyde (GA) fixation for 2 hr and chemical dehydration was compared with short GA fixation (15 min) followed by cryofixation and freeze-drying (CF-FD). The 2 hr GA fixed specimens showed spherical nuclei and secretory granules regardless of their size, contrasting with the more irregularly shaped nuclei and secretory granules after short GA-CF-FD. In the latter group of specimens a correlation could be found between smaller nuclear areas and more irregular shapes. The differences in morphological variables between the two preparation protocols might be due to a better protein stabilization and a reduced collapse of macromolecules after the 2 hr GA fixation, strengthened by the chemical dehydration. The specific immunolabeling with antiserum to growth hormone was much greater but more varied after short time GA-CF-FD than after long GA fixation. Epon surface topography over the granule area also differed: smooth after short time GA-CF-FD and furrowed after long GA fixation. Our results, demonstrating important differences in morphological parameters and immunolabeling density between two common preparation protocols, seem critical for more reliable interpretation in quantitative immunoelectron microscopy. We also emphasize the need for computer assisted image analysis and measurements in immunoelectron microscopy to ensure objective evaluations.     

Short Fixation-Shock Freezing and Freeze-Drying versus Chemical Fixation and Dehydration: Computer Assisted Image Analysis of Morphological Variables and Immunogold Labeling Density on Pituitary Secretory Granules

We have performed a computer assisted image analysis evaluation of the effects of two preparation protocols on morphological variables and immunolabeling density of secretory granules using rat adenohypophysis as a model. Glutaraldehyde (GA) fixation for 2 hr and chemical dehydration was compared with short GA fixation (15 min) followed by cryofixation and freeze-drying (CF-FD). The 2 hr GA fixed specimens showed spherical nuclei and secretory granules regardless of their size, contrasting with the more irregularly shaped nuclei and secretory granules after short GA-CF-FD. In the latter group of specimens a correlation could be found between smaller nuclear areas and more irregular shapes. The differences in morphological variables between the two preparation protocols might be due to a better protein stabilization and a reduced collapse of macromolecules after the 2 hr GA fixation, strengthened by the chemical dehydration. The specific immunolabeling with antiserum to growth hormone was much greater but more varied after short time GA-CF-FD than after long GA fixation. Epon surface topography over the granule area also differed: smooth after short time GA-CF-FD and furrowed after long GA fixation. Our results, demonstrating important differences in morphological parameters and immunolabeling density between two common preparation protocols, seem critical for more reliable interpretation in quantitative immunoelectron microscopy. We also emphasize the need for computer assisted image analysis and measurements in immunoelectron microscopy to ensure objective evaluations.     

Quantitative immuno-gold labelling and ultrastructural preservation after cryofixation (combined with different freeze-substitution and embedding protocols) and after chemical fixation and cryosectioning. Analysis of the secretory organelle matrix of Paramecium trichocysts.

Among the variety of parameters affecting immuno-gold labelling efficiency, mainly the effects of different preparative protocols were tested. Preservation of ultrastructure and of antigenicity are the salient features of this study. We have labelled insoluble components of the secretory matrix of Paramecium trichocysts with specific antisera, using 10 nm colloidal gold particles. The highest labelling efficiency was obtained with fast freezing (cryofixation, either by sandwich or spray-freezing), freeze-substitution in methanol (without added fixatives) and hydrophilic Lowicryls, particularly when applied at low temperatures (K11M at 193 K). The presence of different chemical fixatives always reduced the labelling density and some recommendations from the literature do not appear advisable. Methods commencing with fixation at greater than or equal to 0 degree C, such as "progressive lowering of temperature" (PLT) or preparation of cryostat sections, i.e. with chemical pretreatments, always resulted in lower labelling density. Our data appear, therefore, relevant for optimal immuno-gold labelling of insoluble antigens and emphasize the potential of cryofixation as a primary preparation step. In addition, ultrastructural preservation was also superior after cryofixation.     

Description of antennal structures of the parasitoid Mallophora ruficauda (Diptera: Asilidae) and its relationship with resources searching behaviour

The robber fly Mallophora ruficauda is a parasitoid of white grubs (Coleoptera: Scarabaeidae) inhabiting in Pampas region of Argentina. Females locate host’s habitat and lay eggs away from the host in tall grasses. After hatching, larvae fall to the ground and actively seek hosts. Previous works suggested that female would detect the presence of host’s chemical cues, but sensory organs involved in olfaction are still unknown. However, few studies have looked at dipteran parasitoids sensilla, and no study has been undertaken in Asilidae species. The aim of this work was to determine the presence, density, distribution and morphology of chemosensilla in M. ruficauda antennae using optic and scanning microscope techniques. We found that antennae have 4 segments: scape, pedicel, postpedicel and style. We identified basiconic and trichoid sensilla, small and long bristles, and sensory pits. Basiconic sensilla are multiporous and are widely spread between the small bristles through the postpedicel. Trichoid sensilla are grouped in 6–8 units on latero-ventral margin of postpedicel, have mobile base, striated wall and an apical porous. Small bristles are present in the pedicel and postpedicel, and long bristles are found in groups on scape and pedicel. Three different types of sensory pits were observed, with basiconic sensilla, distributed along external and internal lateral side of the postpedicel. Considering the morphological characteristics of the antennae, and based on the olfaction biomechanics, the structure and distribution of these cuticular structures of the parasitoid antennae would contribute to the odour detection mechanism in adults of M. ruficauda.     

Improved ultrastructural preservation ofPetunia andBrassica ovules and embryo sacs by high pressure freezing and freeze substitution

Summary In order to improve the ultrastructural preservation of the female gametophyte ofPetunia x hybrida andBrassica napus we tested several cryofixation techniques and compared the results with those of conventional chemical fixation methods. Ovules fixed with glutaraldehyde and osmium tetroxide in the presence or absence of potassium ferrocyanide showed poor cell morphological and ultrastructural preservation. In ovules cryo-fixed by plunging into liquid propane, the cell morphology was well preserved. However, at the ultrastructural level structure-distorting ice crystals were detected in all tissues. Due to the large size of the ovules, cryofixation by plunging in liquid propane is not adequate for ultrastructural studies. In contrast,P. x hybrida andB. napus ovules cryo-fixed by high pressure freezing showed improved cell morphological as well as ultrastructural preservation of the embryo sac and the surrounding integumentary tissues. The contrast of the cellular membranes after freeze substitution with 2% osmium tetroxide and 0.1% uranyl acetate in dry acetone was high. At the ultrastructural level, the most prominent improvements were: straight plasma membranes which were appressed to the cell walls; turgid appearing organelles with smooth surface contours; minimal extraction of cytoplasmic and extracellular substances. In contrast to the chemically fixed ovules, in high pressure frozen ovules numerous microtubules and multivesicular bodies could be distinguished.     

The Electrosensory Cells of the Ampullary Organ of the Transparent Catfish (Kryptopterus bicirrhus)

An easy method to demonstrate epidermal sensory organs is described. With the dye Daspei, sensory cells as well as their nerves are visible in the fluorescence microscope. Actin filaments in pore cells and sensory cells are demonstrated with rhodamine-labelled phalloidin, and the distribution of microtubules is described after fixation in albumin-osmium tetroxide-glutaral-dehyde fixation.     

Drosophila Hook-Related Protein (Girdin) Is Essential for Sensory Dendrite Formation

The dendrite of the sensory neuron is surrounded by support cells and is composed of two specialized compartments: the inner segment and the sensory cilium. How the sensory dendrite is formed and maintained is not well understood. Hook-related proteins (HkRP) like Girdin, DAPLE, and Gipie are actin-binding proteins, implicated in actin organization and in cell motility. Here, we show that the Drosophila melanogaster single member of the Hook-related protein family, Girdin, is essential for sensory dendrite formation and function. Mutations in girdin were identified during a screen for fly mutants with no mechanosensory function. Physiological, morphological, and ultrastructural studies of girdin mutant flies indicate that the mechanosensory neurons innervating external sensory organs (bristles) initially form a ciliated dendrite that degenerates shortly after, followed by the clustering of their cell bodies. Importantly, we observed that Girdin is expressed transiently during dendrite morphogenesis in three previously unidentified actin-based structures surrounding the inner segment tip and the sensory cilium. These actin structures are largely missing in girdin mutant. Defects in cilia are observed in other sensory organs such as those mediating olfaction and taste, suggesting that Girdin has a general role in forming sensory dendrites in Drosophila. These suggest that Girdin functions temporarily within the sensory organ and that this function is essential for the formation of the sensory dendrites via actin structures.     

Ultrastructure of chytridiomycete and oomycete zoospores using spray-freeze fixation

Summary The ultrastructure of zoospores of several zoosporic fungi was examined using a modified cryofixation technique. An atomizer was used to spray a zoospore suspension into the cold propane reservoir of a conventional plunge freeze-substitution apparatus. Spray-freeze fixation and freeze-substitution of zoospores porvided better fixation of vacuolar structures, membranes and the extracellular coat than that obtained with chemical fixation. The overall shape of cryofixed spores was closer to that seen in living zoospores. Two types of vacuoles were seen in cryofixed zoospores ofMonoblepharella andChytridium. One type of vacuole contained electron-opaque material within the lumen while the other type had no visible internal material in the lumen and appeared to be part of the water expulsion vacuole complex. Coated pits and coated vesicles were observed associated with both the water expulsion vacuoles and the plasma membrane inMonoblepharella andPhytophthora, suggesting that endocytosis of the plasma membrane and expulsion vacuoles is part of membrane recycling during osmoregulatory events. An extracellular coat was seen on the outer surface of cryofixed zoospores ofMonoblepharella sp.,Chytridium confervae andPhytophthora palmivora without the use of carbohydrate-specific stains. The spray-freeze method gave good and reproducible fixation of the wall-less spores in quantities greater than those obtained in previously described zoospore cryofixation studies. The technique is potentially useful for cell suspensions in that freeze damage from excess water is limited.Abbreviations ddH₂O deionized distilled water - PME Pipes/MgCl2/EGTA buffer - WEV water expulsion vacuole     

Morphology of the prothoracic discs and associated sensilla of Acanthocnemus nigricans (Coleoptera, Acanthocnemidae)

The Australian ‘little ash beetle’ Acanthocnemus nigricans (Coleoptera, Cleroidea, Acanthocnemidae) is attracted by forest fires. A. nigricans has one pair of unique prothoracic sensory organs and it has been speculated that these organs may play a role in fire detection. Each organ consists of a cuticular disc, which is fixed over an air-filled cavity. On the outer surface of the disc, about 90 tiny cuticular sensilla are situated. The poreless outer peg of a sensillum is 3–5 μm long and is surrounded by a cuticular wall. One ciliary sensory cell innervates the peg. As a special feature, the outer dendritic segment is very short already terminating below the cuticle. A massive electron-dense cylindrical rod, which most probably represents the hypertrophied dendritic sheath, extends through the cuticular canal connecting the tip of the outer dendritic segment to the peg. The dendritic inner segment and the soma are fused indistinguishably. Thin, leaflike extensions of glial cells deeply extend into that conjoint and considerably enlarged compartment which also contains large numbers of mitochondria. In summary, the sensilla of the sensory disc of A. nigricans represent a new type of insect sensillum of hitherto unknown function. The possible role of the prothoracic sensory organ in fire detection is discussed.     

Tandem High-pressure Freezing and Quick Freeze Substitution of Plant Tissues for Transmission Electron Microscopy

Since the 1940s transmission electron microscopy (TEM) has been providing biologists with ultra-high resolution images of biological materials. Yet, because of laborious and time-consuming protocols that also demand experience in preparation of artifact-free samples, TEM is not considered a user-friendly technique. Traditional sample preparation for TEM used chemical fixatives to preserve cellular structures. High-pressure freezing is the cryofixation of biological samples under high pressures to produce very fast cooling rates, thereby restricting ice formation, which is detrimental to the integrity of cellular ultrastructure. High-pressure freezing and freeze substitution are currently the methods of choice for producing the highest quality morphology in resin sections for TEM. These methods minimize the artifacts normally associated with conventional processing for TEM of thin sections. After cryofixation the frozen water in the sample is replaced with liquid organic solvent at low temperatures, a process called freeze substitution. Freeze substitution is typically carried out over several days in dedicated, costly equipment. A recent innovation allows the process to be completed in three hours, instead of the usual two days. This is typically followed by several more days of sample preparation that includes infiltration and embedding in epoxy resins before sectioning. Here we present a protocol combining high-pressure freezing and quick freeze substitution that enables plant sample fixation to be accomplished within hours. The protocol can readily be adapted for working with other tissues or organisms. Plant tissues are of special concern because of the presence of aerated spaces and water-filled vacuoles that impede ice-free freezing of water. In addition, the process of chemical fixation is especially long in plants due to cell walls impeding the penetration of the chemicals to deep within the tissues. Plant tissues are therefore particularly challenging, but this protocol is reliable and produces samples of the highest quality.     

On the ultrastructural organization of Trypanosoma cruzi using cryopreparation methods and electron tomography

The structural organization of Trypanosoma cruzi has been intensely investigated by different microscopy techniques. At the electron microscopy level, bi-dimensional analysis of thin sections of chemically fixed cells has been one of the most commonly used techniques, despite the known potential of generating artifacts during chemical fixation and the subsequent steps of sample preparation. In contrast, more sophisticated and elaborate techniques, such as cryofixation followed by freeze substitution that are known to preserve the samples in a more close-to-native state, have not been widely applied to T. cruzi. In addition, the 3D characterization of such cells has been carried out mostly using 3D reconstruction from serial sections, currently considered a low resolution technique when compared to electron tomography (ET). In this work, we re-visited the 3D ultrastructure of T. cruzi using a combination of two approaches: (1) analysis of both conventionally processed and cryofixed and freeze substituted cells and (2) 3D reconstruction of large volumes by serial electron tomography. The analysis of high-pressure frozen and freeze substituted parasites showed novel characteristics in a number of intracellular structures, both in their structure and content. Organelles generally showed a smooth and regular morphology in some cases presenting a characteristic electron dense content. Ribosomes and new microtubule sets showed an unexpected localization in the cell body. The improved preservation and imaging in 3D of T. cruzi cells using cryopreparation techniques has revealed some novel aspects of the ultrastructural organization of this parasite.     

The influence of aphids on the behaviour of adults of the ladybird beetle,Harmonia axyridis (Col.: Coccinellidae)

The mechanism of prey finding by adultHarmonia axyridis (Pallas) (Coleoptera, Coccinellidae) was investigated in the laboratory by offering beetles small gauze or polyethylene bags containing either aphid-infested leaves or uninfested leaves along with empty control bags. The beetles were attracted to bags containing aphid-infested leaves. It is suggested that adults ofH. axyridis use olfactory and visual cues to detect prey. Mate-searching by males and the mating receptivity of females were enhanced in the presence of an abundance of aphids. The presence of aphids, perceived by the sensory organs of the beetles, possibly influence behaviour other than prey-searching.     

Method for the Prfservation of Polystyrene Latex Beads in Tissue Sections

The degree of infiltration of epoxy resin into pituitary secretory granules was evaluated using X-ray microanalysis of the concentrations of chlorine in the epoxy resins. The effectiveness of infiltration was tested after three different tissue preparation techniques: cryofixation + freeze-drying (CF-FD), glutaraldehyde fixation (GF) + chemical dehydration, and no fixation— no dehydration. Signs of marked incomplete infiltration were found in embedded unfixed tissue while the other two techniques showed 80% infiltration. Uneven penetration was seen after CF-FD and GF. The plastic surface demonstrated a mountain-like appearance over the secretory granules after immunocytochemistry of the glutaraldehyde fixed tissue, whereas the CF-FD tissue showed a less furrowed surface. This probably is due to contact with water, which swells those parts of the granules that are unprotected by the plastic embedding medium. Our findings may explain why it is possible to perform immunocytochemistry on Epon embedded tissue.