Ultrastructure of the osphradium of Aplysia californica

Summary The osphradium of Aplysia californica, a sensory organ, is a small yellow-brown epithelial patch located in the mantle cavity immediately anterior to the rostral attachment of the gill. Scanning electron microscopy reveals a round ellipsoid structure of 0.6–1 mm in diameter with a central, occasionally folded, sensory epithelium. The central area is covered with microvilli and surrounded by a densely ciliated epithelium. Transmission electron micrographs show that the columnar supporting cells in the sensory epithelium contain an abundance of apical pigment granules and microvilli. Between the epithelial-supporting cells, the putative sensory elements consist of thin neurites (0.4–1.5 m in diameter) that reach the sea-water side of the osphradium. The neurites contain many neurotubules, mitochondria, vesicles and cilia in their apices. The nerve endings originate from cell bodies up to 40 m below the epithelium or in the osphradial ganglion itself, as revealed by electron microscopy and retrograde labeling with Lucifer yellow. There appear to be two populations of putative sensory cells, a large population of heavily stained cell bodies 4–10 m in diameter and a few scattered cells of large diameter (25–60 m). Following lanthanum impregnation, septate junctions can be seen between all types of cells in the epithelium, 3–5 m below the sea-water surface. This study provides new information for further investigation of osmo- and mechanosensation in Aplysia californica.     

Über den Bau und die Hell-Dunkel-Adaptation der Augen des Polychäten Platynereis dumerilii

Summary The eye of Platynereis dumerilii consists of three components: a short optic nerve, a cup-shaped retina, and a vitreous body within the cup. The opening of the retinal cup is called pupil. The retina is composed of supporting cells and visual cells. The supporting cells are stuffed with dark blue violet pigment granules. The visual cells have orange pigment granules which are only found in the narrow middle piece of the cells. The supporting cell pigment may be lacking in abnormally pigmented eyes. The jellylike matter of the vitreous body apparently is produced by the supporting cells. It is of high protein contents and does not seem to be derived from the cuticle which consists of polysaccharides.The ultrastructure of the photoreceptor region shows club-shaped processes of visual cells. Each club is of low electron density and contains elongate membranous structures. It is surrounded by many microvilli. The clubs correspond to the rods in light microscopy.The eye of Platynereis dumerilii adapts to changes in light intensity by movements of the retina and the rods. The cup-shaped retina spreads towards its pupillar opening thus adapting the pupil area to light intensity. The length of the rods in darkfixed immature specimens is about 20, in light-fixed ones about 7 . In mature specimens (Heteronereis) the length is 46 or 19 respectively.During metamorphosis the eyes enlarge to about three times their original volume. This enlargement is due to an increase in volume of the retina and the vitreous body, not to cell divisions.

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Durchgeführt mit Unterstützung durch ein Stipendium aus Mitteln der Fritz-Thyssen-Stiftung, ferner mit Hilfe der Deutschen Forschungsgemeinschaft.

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Die Anregung zu dieser Arbeit und das Platynereis-Zuchtmaterial verdanke ich Herrn Prof. Dr. C. Hauenschild. Für Hilfe bei der Herstellung des Bildmaterials danke ich Frl. U. Poltz (Freiburg).     

Stereospecificity and electrogenicity of amino acid transport in Riccia fluitans

In the aquatic liverwort Riccia fluitans, membrane depolarization (_m), change in membrane conductance (g_m), and current-voltage (I-V) characteristics in the presence of different amino acids as well as the uptake of ¹⁴C-labeled amino acids were measured. L-isomers of the tested amino acids generate larger electrical effects (_m, g_m) than D-isomers, and the I-V characteristics show that the positive electrical inward-current of 20 mA m^-2 generated by 0.5 mM D-serine is only about 50% of the current generated by adding 0.5 mM L-serine. Whereas - and -amino acids rapidly depolarize the membrane to the same extend, with -aminobutyric acid (-AB) and dipeptides no significant electrical effects have been measured. The uptake kinetics of ¹⁴C-labeled amino acids display three components: (I) A saturable high-affinity component with K_s-values of 48 M D-alanine, 12 M -aminoisobutyric acid (AIB), 9 M L-alanine, 8 M L-proline, and 6 M L-serine, respectively; (2) an apparently linear low-affinity component, and (3) an also linear but unspecific component at concentrations >20 times the given K_s-value. Uptake of ¹⁴C-labeled AIB can be inhibited competitively by all tested neutral amino acids, the L-isomers being more effective than the D-isomers, as well as by ammonium or methylamine. Vice versa, AIB competitively inhibits uptake of L-serine and L-alanine. It is concluded that an uncharged stereospecific carrier for the investigated amino acids exists in the plasmalemma of Riccia fluitans. Accumulation ratios of about 50 suggest secondary active transport driven by a transmembrane electro-chemical gradient (mainly _m) which is generated by the electrogenic proton pump. It is suggested that this carrier binds to the amino group forming either a charged binary complex with positively charged amines (Felle 1980), or an uncharged complex with -AB or dipeptides, whereas electrogenic transport of - and -amino acids is mediated by a ternary carrier complex, probably charged by a proton.Symbols and Abbreviations _m membrane potential (mV) - E_co equilibrium potential (mV) of the transport system - g_m membrane (slope) conductance (Sm^-2) - g_m change in g_m - I-V curve current-voltage curve - AIB -aminoisobutytric acid - -AB -aminobutyric acid     

The ultrastructure of the vomero-nasal organ in reptilia

Summary There are three types of cells in the vomero-nasal organ of Lacerta sicula and Natrix natrix: receptor cells, supporting cells and basal cells. The receptor cells bear microvilli and no cilia. In Lacerta centrioles are lacking, indicating that the ciliary apparatus can have no essential significance in the transducer process. In Natrix centrioles occur in the deeper dendritic region. The structural constituents of the dendrites are mitochondria, microtubules and characteristic vesicles the properties of which are described. The perikarya which have uniform structure send off axons of about 0.2 diameter. The supporting cells show signs of a very moderate secretory activity, which is different among the species investigated. The microvilli of the supporting cells are not distinguishable from those of the receptor cells. The dendrites of the latter are completely isolated by the apical parts of the supporting cells. The sheet-like processes of the supporting cells contain strands of tonofilaments and do not cover the perikarya of the receptor cells completely. Thus adjacent sensory cells or dendrites and sensory cells are separated among themselves only by the normal intercellular space. The ratio of sensory cells to supporting cells is about 71. The basal cells resemble the supporting cells and replace these in the lower portion of the epithelium. The typical cellular junctions between sensory cells and supporting cells are described. There are no true tight junctions in the vomero-nasal sensory epithelium, and they are most probably absent from the nasal mucosa too. This absence would seem to indicate special conditions for cellular communication and the accessibility of the intercellular space for certain molecules. There is no sign of regeneration of sensory cells. Both immature blastema cells and degenerating receptor cells are not discernible.     

The fine structure of the lateral-line organs of larval Ichthyophis (Amphibia: Gymnophiona)

Light and electron microscopic observations of the lateral-line organs of larval Ichthyophis kohtaoensis confirmed earlier reports of the occurrence of two different types of lateral-line organs. One type, the ampullary organ, possesses 15–26 egg-shaped sensory cells. Each sensory cell extends a single kinocilium surrounded by a few microvilli into the ampullary lumen. This is in contrast to the ampullary organs of urodele amphibians that contain only microvilli. The second type of organ, the ordinary neuromast, has 15–24 pear-shaped sensory cells arranged in two to three rows. Each sensory cell shows a kinocilium that is asymmetrically placed with respect to both a basal plate and approximately 60 stereovilli. The sensory cells of ampullary organs are always separated by supporting cells; those of neuromasts are occasionally in contact with one another. Numerous (neuromasts) or few (ampullary organs) mantle cells separate the organs from the epidermal cells. Only afferent synapses are found in the ampullary organs whereas vesicle-filled fibers together with afferent nerve terminals are found in neuromasts. Both organs contain similarly sized presynaptic spheres adjacent to the afferent fibers. It is suggested that the neuromasts have a mechanoreceptive function, whereas the ampullary organs have an electroreceptive one.     

On the fine structure of the aglomerular renal tubule in Lophius piscatorius

Summary The fine structure of the secretory tubules in the kidney of the aglomerular goose-fish (Lophius piscatorius) is described. The cells have a pyramidal shape, are joined together by multiple desmosomes, and share as main characteristics: abundant and deep inflections of the basal and lateral cell membranes; coated luminal plasma membranes forming multiple microvilli or a genuine brush border; moderate numbers of comparatively small mitochondria, usually unassociated with the basal and lateral plasma membrane specializations; numerous multivesicular bodies occuring in the apical cytoplasm; abundant large lysosome-like bodies in the intermediate regions of the cytoplasm; and comparatively poor development of endoplasmic reticulum and Golgi apparatus.The observations suggest that the cells perform both absorptive and secretory functions and are metabolically unusually active in autolytic and heterolytic work. Comparisons with other aglomerular species indicate that the ability for active secretory function is not necessarily dependent on a close association between plasma membrane and mitochondria; however, this ability does appear to require a markedly increased basal and/or lateral cell surface created by multiple invaginations of the plasma membrane. The abundance of desmosomes and associated structures appears to represent a unique structural specialization of the goosefish tubule, and indicates that the cells must be firmly anchored to one another to supply a rigid and mechanically continuous lining of the tubule. The multivesicular bodies probably represent endocytic vacuoles which fuse with apical vesicles and invaginate their outer membrane to form the internal vesicles; they appear to transform to ambilysosomes via a function as heterophagosomes and — later — combined hetero- and autophagosomes.Supported by grants from Karolinska Institutet, Fonden til Videnskabens Fremme and Konsul Johannes Fogh-Nielsen og fru Ella Fogh-Nielsens Légat. Part of the study was performed at the Zoological Station at Naples, Italy. The assistance of Mrs. Britt-Marie Karlsson is gratefully acknowledged.     

Isolabelling is a radiation-induced phenomenon

Human lymphocytes were incubated during two mitotic cycles in the presence of 5-bromodeoxyuridine and differentiation between chromatids was obtained with combined Hoechst 33258 and azur-eosine staining. Analysis of non-irradiated cells revealed numerous sister chromatid exchanges (SCE) and no abnormalities of harlequine appearance of chromosomes. When, however, the cells were irradiated, an identical staining (IS, isostaining) of some chromosomes or chromosome segments were observed. Production of IS was accompanied by decrease of the frequency of SCE, the total frequency of SCE+IS remained, however, the same as in control. An antagonism between SCE and IS was established: the frequency of SCE decreased in the cells with multiple IS, and chromosomes with both SCE and IS were only rarely observed. Thus, IS is neither an artifact nor a physiologic event but a phenomenon induced by radiation. The reliable existence of IS is considered as an evidence for binemic structure of chromatid. It is suggested that some mechanism of lateral spread of genetic information is involved in the production of SCE. If delayed by radiation, the spread could be restricted only to a fraction of chromosome cross-section resulting in IS.     

Fine structure of the ocellus of Sarsia tubulosa (Hydrozoa,Anthomedusae)

Summary The fine structure of the ocellus of Sarsia tubulosa is described. The ocellar cup is formed of pigment cells and receptor cells. The receptor cells outnumber the pigment cells in almost a 2:1 ratio. Lateral extensions of neighbouring pigment cells enclose a distal region of 2 to 10 receptor cells. The receptor cell body is 5–7 m in diameter with an apical extension (20–60 m long) that reaches the ocellar cavity. A cilium (9+2 microtubules) arises from the distal part of the receptor cell. The ciliary membrane forms lateral microvilli. The tips of a number of cilia are swollen into large vesicles forming a cornea. The central region of the ocellar cavity contains extracellular electron dense homogeneous material surrounded by swollen ciliary tips and small vesicles. The close apposition between the plasma membrane covering the distal part of adjacent receptor cells as well as the adjacent ciliary shafts suggests the presence of gap junctions. The basal part of each receptor cell forms an axon. The axons of receptor cells form 3 to 4 nerve bundles that join to form the optic nerve. Synapses occur between receptor cell bodies, between axons and receptor cell bodies and among axons.     

Cytochemical studies on histones in the condensed chromatin of mature human leucocytes

Summary Histones were studied in human mature neutrophils and lymphocytes by means of simple and modified cytochemical procedures carried out on smear preparations of the peripheral blood to provide more information on the composition of the condensed chromatin in nuclei of these cells. The results indicated that the condensed chromatin of mature neutrophils contains mainly lysine rich histones and the condensed chromatin of mature lymphocytes is characterized mainly by the presence of arginine rich histones.     

Immunocytochemical localization of muscarinic acetylcholine receptors in the rat endocrine pancreas

Summary Immunocytochemical application of the antimuscarinic acetylcholine receptor antibody M35 to pancreas tissue revealed the target areas for the parasympathetic nervous system. Immunoreactivity in the endocrine pancreas was much higher than that in the exocrine part. Moreover, the endocrine cells at the periphery of the islets of Langerhans displayed the highest level of immunoreactivity. Based on these findings in the mantle of the islets, two types of islets have been distinguished: type-I islets with intensely stained mantle cells, and type-II islets with a much lower concentration of these cells. On average, type-I islets were larger (244.8 m±6.1 SEM) than type-II islets (121.5 m±3.8 SEM). M35-immunoreactivity was present on the majority of D cells, which were characterized by their immunoreactivity to somatostatin [of 446 D cells 356 (79.8%) were M35-immunopositive]. However, only a small proportion of the intensely stained mantle cells belonged to the D cell population. Therefore, it is concluded that the majority of the intensely stained mantle cells represent glucagon-secreting A and/or pancreatic polypeptide-secreting F cells. The intensity of M35-immunoreactivity at the periphery and central core of the islets paralleled the density of cholinergic innervation, suggesting a positive correlation between the intensity of cholinergic transmission and the number of muscarinic acetylcholine receptors at the target structures. The present study further revealed some striking parallels for the muscarinic acetylcholine receptor characteristics between the (endocrine) pancreas and the central nervous system.     

Surface changes inPhytophthora palmivora zoospores following induced differentiation

Summary Populations ofPhytophthora palmivora zoospores induced to undergo synchronous differentiation by the addition of pectin showed an ordered sequence of surface changes. Within 10 seconds blebs and microvilli appeared on the cell and flagellar surfaces. These projections gave the zoospore a highly irregular and even convoluted surface for up to 30 seconds poststimulation. Between 30 and 40 seconds, pits appeared on the surface, which began to assume a smoother texture. Zoospores then rounded up and by 4 minutes had assumed an almost spherical form. At this time the surface became wrinkled as though shrinkage had occurred. Germ tubes could be seen emerging from almost all cells by 40 minutes, and as germ tubes enlarged, the cell surface became smooth again but with a fibrous texture. Many zoospores retained their flagella through to the germling stage.When cells were stimulated in iso-osmotic rather than hypo-osmotic media, germ tubes in most cases emerged at or very near the site of flagellar attachment. Differentiation in iso-osmotic media showed the same sequence except that the cells did not assume the spherical shape normally characteristic of cysts and germlings differentiating under hypo-osmotic conditions.Strontium-induced differentiation again followed the same general sequence as desribed above, although the cell surface was noticeably more convoluted and irregular prior to the stage of the formation of pits, and flagella were always shed between 40 seconds and 1 minute. Calcium addition up to 20 seconds after the initiation of differentiation with pectin prevented a high proportion of zoospores from encysting, the cells remained motile, and although the frequency of surface blebs and microvilli increased, pits did not appear.These surface changes are consistent with those expected during stimulus-mediated secretion, and it appears that calcium is able to inhibit differentiation only before the secretory step (pit formation).     

Untersuchungen an der Regio olfactoria des Aals,Anguilla anguilla L.

Zusammenfassung Das Flimmerepithel von Anguilla anguilla besteht aus 4 Zellarten: Flimmerzellen, Stützzellen, Basalzellen und Schleimbecherzellen. Flimmerzellen enthalten im oberen Zelldrittel zahlreiche Mitochondrien und tragen an ihrer Oberfläche bis zu 140 Kinocilien. Die Basalkörper dieser Kinocilien haben lange Wurzelfilamente, von denen ein Teil ins Zellinnere zieht; der andere Teil verläuft parallel zur Oberfläche und verbindet benachbarte Basalapparate. — Ein Übergangsepithel verknüpft das Flimmerepithel mit dem Riechepithel. Im Riechepithel finden sich außer den Zellarten des Flimmerepithels die Rezeptoren. Bei einheitlichem Aufbau des Zellkörpers lassen sich aufgrund rein morphologischer Unterschiede der Vesiculae olfactoriae 3 Rezeptortypen unterscheiden: 1. Cilien-Rezeptor, 2. Mikrovilli-Rezeptor und 3. Pfriem-Rezeptor. — Der Cilien-Rezeptor trägt unterhalb der Vesicula olfactoria in einer Einschnürung 4–8 sensorische Cilien, die alle auf gleicher Höhe entspringen. Zwei gegenüberliegende sensorische Cilien schließen einen konstanten Winkel von 60° ein. — Der Mikrovilli-Rezeptor trägt auf seiner abgerundeten Vesicula olfactoria 30 bis 60 Mikrovilli von 0,1 m Dicke und bis zu 5 m Länge. Der Mikrovillus wird von einem zentralen, 160 Å weiten, Tubulus durchzogen. Unterhalb der Vesicula olfactoria liegen mehrere Centriolen. Die Rezeptornatur dieser Zellen wird durch ein Axon unterstrichen. — Der Pfriem-Rezeptor besitzt eine 0,8 m breite und bis zu 4 m lange Vesicula olfactoria ohne sensorische Cilien und ohne Mikrovilli. Im Lumen der Vesicula olfactoria befinden sich neben Neurotubuli auch Fibrillen von 40–50 Å Durchmesser, die gebündelt auftreten. An der Basis des Köpfchens liegen mehrere Centriolen.

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Studies of the regio olfactoria in the eel, Anguilla anguilla I. Fine structure of the olfactory epithelium

Summary The ciliary and olfactory epithelia of the olfactory folds in Anguilla anguilla were studied with the electron microscope. The ciliary epithelium is composed of ciliary cells, supporting cells, basal cells, and mucous cells. The ciliary cells contain numerous mitochondria in their apical portion and bear up to 140 cilia. The ciliary basal bodies have rootlets, some of which project towards the central part of the cell, and others parallel to the cell surface thereby connecting neighbouring basal bodies. A transitional epithelium is located between the ciliary and olfactory epithelia. The olfactory epithelium is composed of the same 4 cell types of the ciliary epithelium and besides contains three morphologically different receptor cell types: ciliary receptor cells, microvillous receptor cells, and receptors with a single rodshaped free appendage. The ciliary receptors have 4 to 8 sensory cilia which project from below the vesicula olfactoria, each forming a constant angle of about 30° with the vertical cell axis. The vesicula olfactoria of the microvillous receptors bears from 30 to 60 microvilli, each of 0.1 m diameter and up to 5 m length. Each microvillus of this receptor type contains a central tubulus of 160 Å diameter. Few centrioles are located closely to the vesicula olfactoria. The third receptor type, which has neither cilia nor microvilli, is characterised by a single rod-shaped appendage of 0.8 m diameter which projects up to 4 m above the epithelial surface. This appendage contains neurotubules and fibril bundles; some centrioles lie close to the base of the appendage.

     

Normal pharmacological and morphometric parameters in the noradrenergic hyperinnervated mutant mouse, “tottering”

Summary Pharmacological and anatomical analyses of central monoaminergic and cholinergic neurons were performed in the tottering mouse, an autosomal recessive neurologic gene mutation that results in an overproduction of axons of the locus coeruleus and an increase in norepinephrine content in specific terminal fields. Except for the previously reported increase in norepinephrine content, all pharmacological parameters measured, including tyrosine hydroxylase activity, norepinephrine turnover, serotonin content, and choline acetyltransferase activity, in targets hyperinnervated by the locus coeruleus were normal. Immunocytochemical staining for tyrosine hydroxylase demonstrated the pronounced hyperinnervation in the tottering brain, whereas both serotonin and choline acetyltransferase immunostaining were similar between tottering and wild type. The volume of 3 target areas that are hyperinnervated by the locus coeruleus in the tottering mouse, the hippocampus, cerebellum, and cochlear nuclei, were normal. In addition, neuronal number and somal size in the locus coeruleus were found to be unchanged in the mutant genotype. These data demonstrate several features of the effects of the tottering gene: 1) compensatory changes in several adrenergic pharmacological parameters do not occur in response to the hyperinnervation of targets by locus coeruleus axons; 2) neither direct effects of the tottering gene on, nor compensatory changes in, the extent of cholinergic or serotonergic innervation of several targets of the locus coeruleus appear to occur; and 3) the lack of changes in size of the targets of the locus coeruleus suggest that the hyperinnervation in the tottering mouse is due to a direct genetic alteration of axonal growth by the locus coeruleus neurons, rather than to selective shrinkage of targets in the presence of normal terminal arbors.     

Elektronenmikroskopische Untersuchungen am Stirnorgan von Anuren

The ultrastructure of the frontal organ (pineal end-vesicle, Stirnorgan) of Rana temporaria L. and Rana esculenta L. is similar to the submicroscopic organization of the retina and other photosensitive organs. There are five different cell types in the frontal organ: sensory (receptor) cells, ependymal cells, ganglion cells, glial cells and epithelial cells. The ependymal cells may be secretory. There is no evidence for a typical pigment epithelium. The sensory cells have inner and outer segments. The inner segments contain numerous mitochondria, a Golgi complex, filaments, lipid droplets, two centrioles and a fibrillar apparatus (within the connecting piece). The mitochondria are very abundant in the Ellipsoid and Ersatzellipsoid areas (Holmgren) of the inner segment. The outer segment consists of about 60 to 110 discs formed by infoldings of the cell membrane. Most of the sensory cells are cone-like, but there are some elements with rod-like structures. Plexiform areas of the frontal organ contain terminations of the receptor cells, and processes of the nerve cells and glia cells. Synaptic structures have been determined within these areas. Non-medullated and medullated nerve fibers with adjacent glial satellites are observed in the pineal nerve (Nervus pinealis). The anatomical findings are described in detail and discussed in respect to the physiological results of Dodt and Heerd (1962) in Rana temporaria and Rana esculenta.

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Durchgeführt mit Unterstützung durch die Deutsche Forschungsgemeinschaft.     

Chiloscyllium plagiosum low-density lipoprotein receptor: Evolutionary conservation of five different functional domains

All five functional domains of the low-density lipoprotein (LDL) receptor were assembled in their modern form more than 450 million years ago, as revealed from the cloning and sequencing of an LDL receptor cDNA fromChiloscyllium plagiosum (banded cat shark). The shark LDL receptor has the same overall architecture as the mammalian and amphibian counterparts. Each of the seven cysteine-rich repeats in the ligand binding domain resembles its counterpart in the human LDL receptor more than it does the other repeats in the shark receptor as suggested by the presence of unique signature sequences, indicating that these repeats had already acquired their independent structures by the time of shark development. Furthermore, amino acid sequences of the entire ligand binding domain of shark LDL receptor show 35% identity over a stretch of 294 residues with aLymnaea stagnalis G-protein-linked receptor (LSGLR). The region of homology between these unrelated proteins includes conservation of most of the unique characteristics of the cysteine-rich repeats of LDL receptor at the expected positions in LSGLR. The results presented are consistent with the hypothesis that all seven repeats in the ligand binding domain of LDL receptor may have been lifted directly from an ancestral gene instead of being evolutionary duplications of a single repeat recruited by the primitive LDL receptor from another gene.The nucleotide sequence reported will appear in GenBank under accession number L36118     

An electron microscopical investigation of the follicle gland (cerebral gland) and of some neurosecretory cells in the lateral lobe of the cerebral ganglion of the pulmonate gastropod Lymnaea stagnalis L.

Summary The ultrastructure of the follicle gland and of some Gomori-positive neurosecretory cells in the lateral lobes of the cerebral ganglia of Lymnaea stagnalis is described.The follicle wall consists of epithelial cells containing secretion granules, and of processes of lateral lobe nerve cells bearing cilia, including the processes of bipolar neurosecretory B-cells. The ultrastructure of the follicle of Ancylus fluviatilis and Planorbarius corneus appeared to be very similar to that of L. stagnalis. From the ultrastructure of the follicle wall and lumen, no conclusions can be drawn as to its formerly proposed possible functions (sense organ, endocrine organ, neuroendocrine organ). Of three neurosecretory cell types (B-cells, canopy cells, droplet cells), the positivity to chrome-haematoxylin and paraldehyde-fuchsin appeared to be due to elementary granules of different size and appearance. This finding supports in a particular sense the view that results obtained with the neurosecretory stains, should be judged carefully. Also in ordinary neurons elementary granules can be found, at times in great numbers. Several types of elementary granules (at least 6) could be distinguished. Their character and function (neurohormones, neurotransmitters) are not clear.     

Secondary structure of the entomocidal toxin from Bacillus thuringiensis subsp. kurstaki HD-73

The secondary structure of the toxin fromBacillus thuringiensis subsp.kurstaki (Btk) HD-73 was estimated by Raman, infrared, and circular dichroism spectroscopy, and by predictive methods. Circular dichroism and infrared spectroscopy gave an estimate of 33–40% -helix, whereas Raman and predictive methods gave approximately 20%. Raman and circular dichroism spectra, as well as predictive methods, indicated that the toxin contains 32–40% -sheet structure, whereas infrared spectroscopy gave a slightly lower estimate. Thus, all of these approaches are in agreement that the native conformation of Btk HD-73 toxin is highly folded and contains considerable amounts of both -helical and -sheet structures. No significant differences were detected in the secondary structure of the toxin either in solution or as a hydrated pellet.     

Protein compositional analysis of inclusion bodies produced in recombinant Escherichia coli

Summary Culture conditions favouring the simulataneous formation of soluble protein and inclusion bodies (IBs) were chosen for producing the cytoplasmic protein -galactosidase or the periplasmic protein TEM--lactomase. Soluble and insoluble cell fractions of Escherichia coli producing either -galactosidase or TEM--lactomase were analyzed by one- and two-dimensional gel electrophoresis and subsequent silver staining or immunodection of the recombinant protein. The results show that truncated fragments of the recombinant protein were not present in the soluble cell fraction but accumulate in the IB fraction. The presense of other cellular, non-plasmid-encoded proteins in IB preparations such as the outer membrane proteins OmpF, OmpC, and OmpA or the ribosomal subunit proteins L7/L12 was attributed to co-precipitation of cell-debris-associated components. Protein-folding enzymes were not detected in IB preprations. The specificity of in-vivo protein association in the formation of IBs and its implication on protein purification is discussed. Correspondence to: J. E. Bailey     

Ultrastructural localization of monoamines in the epidermis of Lumbricus terrestris (L.)

Summary Receptor cells in the epithelium and the basiepithelial nerve net of the prostomium of Lumbricus terrestris were investigated with electron microscope with special regard to the presence of monoamines. The receptor cells are found in groups of about 40 intermingled with supportive cells. After pretreatment with -methyl-noradrenaline and fixation with potassium permanganate a few receptor cells in each group and some nerve fibres in the basiepithelial nerve net contain small granular vesicles (about400 Å) characteristic for monoaminergic neurons. The distribution and relative number of these receptor cells and nerve fibres coincide well with previous reports on fluorescent receptor cells and varicose fibres. That the monoamine-storing small granular vesicles not are visualized until pretreatment with -methyl-noradrenaline is in accordance with recent microspectrofluorometric analysis, which shows that dopamine is the only primary monoamine present in the epithelium.In the epithelium there are occasional receptor cells and nerve fibres containing large vesicles (1000–1800 Å) which resemble the neurosecretory vesicles in the central nervous system. Photoreceptor cells having an intracellular cavity with microvilli and cilia have infrequently been observed at the base of the epithelium.No synapses on the mucous cells have been noticed. Nor have any synaptic specializations been observed in the basiepithelial nerve net. The morphological conditions necessary for the existence of possible axo-axonal synapses are briefly discussed.This work was supported by grants from the Helge Ax: son Johnson Foundation and the Magn. Bergvall Foundation.     

Der Feinbau des Auges der Mehlmotte,Ephestia kuehniella Zeller (Lepidoptera,Pyralididae)

Zusammenfassung Die Retinula im Ommatidium der Mehlmotte besteht aus einer wechselnden Anzahl (9–12, meist 11) langgestreckter, prismatischer Sinneszellen. Außerdem enthält jede Retinula nahe der Basalmembran im Zentrum zwischen diesen distalen Retinulazellen noch eine basale Retinulazelle. Die Längsachse der Retinula wird von der Achsenstruktur eingenommen, die aus Mikrovilli besteht. Ihr distaler Teil ist der Achsenfaden, der breitere, proximale Teil bildet das Rhabdom. Dieses erscheint im Querschnitt meist vierstrahlig gelappt, da seine Außenseite in Längsrichtung tief gekehlt ist. Der Rhabdomquerschnitt gliedert sich in mehrere Schöpfe parallel angeordneter Mikrovilli (Rhabdomsektoren); jeder Rhabdomsektor besteht aus 1 oder 2 Rhabdomeren. Die basale Retinulazelle entsendet einen kleinen Schopf von Mikrovilli in die proximale Spitze des Rhabdoms. Die distalen Retinulazellen setzen sich proximal in Neuriten fort, welche sich in Einkehlungen der basalen Retinulazelle bzw. der Tracheenendzelle einschmiegen. Jeweils eine Tracheole durchbricht zusammen mit dem Neuritenstrang einer Retinula die Basalmembran; sie verzweigt sich distal zu ca. 30 Tracheolen, die die Retinula umhüllen.Die Kristallkegelzellen grenzen distal an die Cornea; proximal laufen die Kristallkegelzellen eines Ommatidiums in einen gemeinsamen Fortsatz aus, der zwischen den Retinulazellen unmittelbar am Achsenfaden endet. — Nur das helladaptierte Auge wurde untersucht. Hierbei erscheint im distalen Teil der Retinula nur der Achsenfaden lichtdurchlässig, das Cytoplasma der Retinulazellen hingegen von Pigmentgrana durchsetzt und für Licht undurchlässig.

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Fine structure of the eye of the meal moth, Ephestia kuehniella Zeller (Lepidoptera, Pyralididae)

Summary In each ommatidium of the meal moth a retinula is formed from a varying number (9–12, mostly 11) of elongated, prismatic sense cells. In addition, a basal retinular cell is situated near the basement membrane in the center of the other (distal) retinular cells. The axis of the retinula is occupied by many microvilli forming the axial structure, the distal section of which is the slender axial thread. Proximally, the axial structure widens (to 8.5 m instead of 1 m in diameter) and is now called rhabdom. Cross sections of the rhabdom mostly look like a petaloid with four petals; this figure is due to longitudinal infoldings along the length of the rhabdom surface. The rhabdom cross section is subdivided into several brushes of microvilli (rhabdom sectors), each one being characterized by an approximately parallel arrangement of its microvilli. One rhabdom sector may be composed of one or two rhabdomeres respectively.The basal retinular cell participates in rhabdom formation through a small brush of microvilli at the proximal end of the rhabdom. Proximally, the distal retinular cells taper into slender neurites which are embedded in grooves at the surface of the basal retinular cell and the tracheal end cell respectively. One tracheole piercing the basement membrane together with the neurites of one retinula branches into about 30 tracheoles surrounding the retinula.The crystalline cone cells touch the cornea; proximally, their cytoplasm forms a point which eventually terminates amongst the distal tips of the retinular cells, immediately at the axial thread.—Our work was restricted to light adapted eyes; in this condition, light transmission in the distal part of the retinula seems to be blocked by retinular cell pigment except inside the axial thread.

Mit Unterstützung durch die Deutsche Forschungsgemeinschaft.