Some observations on the fine structure of the sinus gland of a land crab,Gecarcinus lateralis

The dilated axon endings of the sinus glands of the brachyuran crab, Gecarcinus lateralis, are filled with homogeneously dense granules, each granule being bounded by a delicate membrane. The granules are of two orders of magnitude: 0.05 to 0.1 micro and 0.15 to 0.2 micro in diameter. Each axon ending contains granules of a nearly uniform size. Endings with granules of the larger size range predominate. Non-nervous cells endogenous to the sinus gland are scattered among the nerve endings. The cell contours are irregular, and cytoplasmic processes ramify between endings. The axons are unmyelinated, having only thin limiting membranes, and they possess many neurofibrils. Granules in preterminal portions of the axons tend to lie at the periphery of the fiber, and in some cases in chains at the core of the fiber. The granules appear to be storage and release centers for neurosecretory substances or their precursors.     

Oogenesis in the tropical land crab,Gecarcinus lateralis (Freminville)

Summary The ovaries of small and large adult Gecarcinus were studied histologically and histochemically at various stages in the annual cycle. At all seasons of the year, dividing cells are seen within germinal nests in the ovary. Following division, the cells within the germinal nest enlarge and appear to move out into the stroma, forming cords of young oocytes that become encapsulated by follicle cells. Glycogen, not demonstrable in cells within the germinal nests, is present in the perinuclear cytoplasm of both young and mature oocytes. Lipid is distributed peripherally in the cytoplasm of the oocytes. Deoxyribonucleoprotein is demonstrable within the nuclei of germinal nest cells and of the young oocytes; it is not detectable within the nuclei of the large oocytes. The histological observations suggest that oogenesis occurs throughout the reproductive life of Gecarcinus.Dedicated to Professor Berta Scharrer on her 60th birthday in love, respect and admiration. — This work was supported in part by U.S.P.H.S. Training Grant GM-102.I express my thanks to the late Dr. Helen W. Deane and Dr. Dorothy E. Bliss for their help and encouragement.     

Ultrastructural study of the neurosecretory granules in the sinus gland of the blue crab,Callinectes sapidus

Summary Seven morphologically different types of neurosecretory granules have been found in the axon terminals of the sinus gland of the blue crab, Callinectes sapidus. They differ from each other in size, shape, staining characteristics, solubility characteristics, core matrix characteristics, axon terminal matrix characteristics, presence or absence of space between the granule membrane and granule core matrix, and frequency of occurrence. Five of the types are segregated in different axon terminals and are believed to represent different hormone-protein complexes. Two of the types, which have lost part or all of their granular contents, are thought to be variants of the other five types. The differences in granular morphology are better revealed by some fixation procedures than others. Palade's acetate-veronal buffered osmium tetroxide, in particular, reveals striking differences. The following observations suggest that different hormone-protein complexes are segregated in different axon terminals and that these complexes may be morphologically distinguished at the level of the electron microscope.Supported by USPHS-NIH Training Grant GM-00669 and Grant GB-7595X from the National Science Foundation.     

Opioid potentiated chromatophorotropin regulation of pigment migration in the land crab Gecarcinus lateralis

In Gecarcinus lateralis dopamine treatment results in dispersion of black and concentration of red pigments within chromatophores. These effects of dopamine on the migration of pigments can be blocked by the dopamine antagonist haloperidol. These results strongly indicate the presence of a dopamine receptor mediated system in this organism. Serotonin injections also result in the dispersion of black pigment; however, this effect cannot be blocked by haloperidol. Norepinephrine was found to be without effect on this pigment regulatory system. Injections of crude eyestalk extract results in pigment migration within the chromatophores in both stalked and destalked animals. Injection of the stable methionine enkephalin analog FK 33 824 into the organisms causes no observable effects on the pigment system. However, coinjection with eyestalk extract strongly potentiates the effect of the extract. This potentiation can be completely blocked by the opiate antagonist naloxone, thus indicating that an endogenous opioid system may be part of the overall regulation of pigmentation movement.     

Interruption of proecdysis by autotomy of partially regenerated limbs in the land crab, Gecarcinus lateralis

In the land crab, Gecarcinus lateralis, autotomy of partially regenerated limbs before a critical stage in the premolt period results in (1) a very rapid decrease in the serum ecdysone titer, (2) a delay in the growth of partial regenerates remaining on the animal, (3) a delay in the deposition of gastroliths, and (4) a delay in cytological changes in the epidermis. Serum ecdysone titers remain low while new limb regenerates form at the sites of those removed. Ecdysone titers rise when these secondary regenerates complete basal regeneration. Premolt events, which had ceased at the time of autotomy of the partial regenerates, resume their normal patterns of development when ecdysone titers reach the level present in the serum at the time of this interruption. We propose that the effect of autotomy before a critical period is to reinitiate a normal proecdysis. The same pattern of events occurs following autotomy of partial regenerates of crabs without eyestalks, suggesting that the decrease of serum ecdysones is brought about by some mechanism other than changes in the titer of the molt inhibitory hormone.     

Ultrastructural appearance of neurosecretory granules in the sinus gland of the crab after different fixation procedures

Summary The appearance of neurosecretory granules in the crab sinus gland was studied after fixation at different pHs. Whereas at pH 7.0 the neurosecretory granules were pleomorphic with respect to electron density, at pH 5.0 or 6.0 all the granules remained electron dense. The possible role of maturation as an explanation of this observation is discussed.ERA 493 CNRS     

Actin-encoding cDNAs and gene expression during the intermolt cycle of the Bermuda land crab Gecarcinus lateralis

Two actin-encoding cDNAs (act1 and act2) from Gecarcinus lateralis have been sequenced or partially sequenced and the corresponding proteins deduced. The actl cDNA has a complete ORF; the act2 cDNA lacks most of the 5′ end of the coding region. The nucleotide (nt) sequences of both clones are very similar to act sequences of many organisms, the most closely related being from another arthropod, the silkmoth Bombyx mori. The proteins Actl and Act2 are more similar to vertebrate cytoplasmic actin isoforms (β-actins) than to vertebrate muscle actins (α-actins); they are also more similar to animal actins than to those of fungi or plants. Codon usage is strongly biased toward C or G in the third position. The deduced number of amino acid (aa) residues and calculated M_r for Actl are 376 aa and 41.94 kDa, respectively. The deduced aa sequence of Actl is very similar to those of muscle actins of B. mori and Drosophila melanogaster. Southern blots indicated seven to eleven act genes in the crab genome. Northern blots probed with a segment from the 3′ UTR of actl showed a single band of approx. 1.6 kb in poly(A)⁺mRNAs from epidermis, limb bud or claw muscle and in total RNAs from ovary and gill, and two bands of approx. 1.6 and 1.8 kb in total RNA from midgut gland. Western blots of one-dimensional gels of proteins from the four layers of the exoskeleton, epidermis, limb buds and claw muscle were probed with a monoclonal Ab against chicken gizzard actin; tissue- and stage-specific changes in actin content were observed. The presence of several isoforms, and differences in their number and occurrence at various stages of the intermolt cycle, were detected on Western blots of two-dimensional gels.     

Evidence for dopaminergic and opioid involvement in the regulation of locomotor activity in the land crab Gecarcinus lateralis

1. Computerized analysis of the crabs locomotor behavior revealed an initial increase in activity followed by a gradual decrease over a 12 min observation period. 2. Dopamine, in a dose-dependent manner, inhibits locomotor activity. The effect can be antagonized with the dopamine antagonist, haloperidol. This suggests that dopaminergic influences are involved with locomotor mechanisms. 3. FK 33,824, a stable opioid analog, significantly enhances the initial excitatory locomotor activity. Naloxone, a potent opiate antagonist, can block the excitatory action induced by FK 33 824. This suggests the presence of an opioid modulation mechanism in the regulation of locomotor activity. 4. Concomitant administration of the various agents results in the behavioral characteristics of the agonist appearing when the appropriate antagonist is not present. Thus, administration of dopamine + FK 33,824 + haloperidol results in enhanced locomotor activity. 5. Concomitant dopamine and FK 33,824 administration results in enhanced locomotor activity. This suggests that the opioid mechanism is closer to the last step in affecting the organism's locomotion or in initiating activity.     

Characterization of limb autotomy factor-proecdysis (LAF(pro)), isolated from limb regenerates,that suspends molting in the land crab Gecarcinus lateralis

Molting and limb regeneration are tightly coupled processes, both of which are regulated by ecdysteroid hormone synthesized and secreted by the Y-organs. Regeneration of lost appendages can affect the timing and duration of the proecdysial, or premolt, stage of the molt cycle. Autotomy of all eight walking legs induces precocious molts in various decapod crustacean species. In the land crab Gecarcinus lateralis, autotomy of a partially regenerated limb bud before a critical period during proecdysis (regeneration index <17) delays molting so that a secondary limb bud (2 degrees LB) forms and the animal molts with a complete set of walking legs. It is hypothesized that 2 degrees LBs secrete a factor, termed limb autotomy factor-proecdysis (LAF(pro)), that inhibits molting by suppressing the Y-organs from secreting ecdysone. Molting was induced by autotomy of eight walking legs; autotomy of primary (1 degrees ) LBs reduced the level of ecdysteroid hormone in the hemolymph 73% by one week after limb bud autotomy (LBA). Injection of extracts from 2 degrees LBs, but not 1 degrees LBs, inhibited 1 degrees LB growth in proecdysial animals, thus having the same effect on molting as LBA. The inhibitory activity in 2 degrees LB extracts was stable after boiling in water for 15 min, but was destroyed by boiling 15 min in 0.1 N acetic acid or incubation with proteinase K. These results support the hypothesis that LAF(pro) is a peptide that resembles a molt-inhibiting hormone.     

Depletion of neurosecretory granules and membrane retrieval in the sinus gland of the crab

Summary Ultrastructural aspects of hormone release from the sinus gland of the crab Carcinus maenas, have been studied by incubation of glands in vitro (i) in high potassium-containing media to induce hormone release; (ii) in a high potassium-containing calcium-free medium in which depolarisation but no hormone release would be expected; and (iii) in control saline. Uptake of horseradish peroxidase into subcellular organelles was also studied.Many neurosecretory granules could be found in the nerve terminals but, in contrast to mammalian neurosecretory systems, structures resembling microvesicles were extremely scarce. High potassium stimulation in the presence of calcium caused an 18 % loss of granules from the nerve terminals associated with images of single and multiple exocytosis. It further caused an increase in vacuoles which could have accounted for 33 % of the membrane of the granules exocytosed. After incubation in high potassium-containing, calcium-free media there was no evidence either of exocytosis of granules or of an increase in the vacuole population. The population of sparse microvesicle-like structures was not significantly altered by incubation in either high potassium medium. Horseradish peroxidase reaction product could be found only in vacuoles of tissues stimulated by high potassium concentrations in the presence of calcium. It is concluded that this depolarising stimulus produces, in the presence of calcium, the release by exocytosis of about one sixth of all the granules in the sinus gland, and that vacuoles are the organelle responsible for the recapture of membrane after the exocytosis.     

Effects of colchicine on release of neurosecretory material from the posterior pituitary gland of the rat

Summary The effect of colchicine on the release of neurosecretory material from the posterior pituitary gland was investigated in the rat in vivo and in vitro. Colchicine was administered subarachnoidally when neurophysin, radiolabelled by injection of (³⁵S) cysteine into the supraoptic nucleus, had accumulated in the neural lobe. Dehydration for 3 days of non-colchicine-treated rats was followed by a 100% reduction of neurophysin-bound radioactivity. When colchicine was given prior to dehydration, the reduction of radioactive neurophysin was less marked. Colchicine treatment alone was likewise followed by a lowering of protein-bound radioactivity in the neural lobe, which may indicate that colchicine, in addition to blocking the rapid axonal transport of neurosecretory material, also impedes the slow transport.The release of radioactive neurophysin in response to depolarizing concentration of potassium in vitro was diminished in the presence of colchicine, the reduction being most pronounced after colchicine treatment in vivo. The biochemical data prove the view that colchicine inhibits the release of neurosecretory material from the neural lobe. The ultrastructural findings support the biochemical data. Thus, colchicine treatment alone or followed by dehydration induced a marked increase in the number of organelles, especially of mitochondria and dense bodies. There was a marked increase in the number of enlarged axons filled with dammed organelles in the infundibulum and neurohypophysis. There was an accumulation of dense core vesicles and microvesicles in the axonal terminals in the neurohypophysis after treatment with either colchicine or colchicine followed by dehydration, which indicates an impediment of the release process. Dehydration alone induced a depletion of the dense core vesicles in the terminals. Out from the combined biochemical and ultrastructural findings possible mechanisms for the action of colchicine are discussed.The present study was supported by grants from Svenska livförsäkringsbolags fond för medicinsk forskning, The Swedish Medical Research Council (No. B73-12X-2543-05B), Magnus Bergvalls stiftelse and from the Medical Faculty, University of Göteborg.Miss Gull Grönstedt is thanked for careful secretarial work and the technical assistance by Mrs. Wally Holmberg, Mrs. Elisabeth Norström and Mrs. Ulla Svedin is gratefully acknowledged. Abbreviations used: NSG = neurosecretory granules; NSN = neurosecretory material; SON = supraoptic nucleus.     

Immunocytochemical localization of actin and tubulin in the integument of land crab (Gecarcinus lateralis) and lobster (Homarus americanus)

The crustacean integument consists of the exoskeleton and underlying epithelium and associated tissues. The epithelium, which is composed of a single layer of cells, is responsible for the cyclical breakdown and synthesis of the exoskeleton associated with molting (ecdysis). During premolt (proecdysis) the epithelial cells lengthen and secrete the two outermost layers (epicuticle and exocuticle) of the new exoskeleton while partially degrading the two innermost layers (endocuticle and membranous layer) of the overlying old exoskeleton. This increased cellular activity is associated with increased protein synthesis and a change in cell shape from cuboidal to columnar. The cytoskeleton, composed of microfilaments (actin) and microtubules (tubulin), plays important roles in the intracellular organization and motility of eukaryotic cells. Immunoblot analysis shows that the land crab exoskeleton contains actin, tubulin, and actin-related proteins (Varadaraj et al. 1996. Gene 171:177-184). In the present study, immunocytochemistry of land crab and lobster integument showed that both proteins were localized in various cell types, including epithelia, connective tissue, tendinal cells, and blood vessels. Muscle immunostained for actin and myosin, but not for tubulin. The membranous layer of land crab (the other layers of the exoskeleton were not examined) and membranous layer and endocuticle of lobster also reacted specifically with anti-beta-actin and anti-alpha-tubulin monoclonal antibodies, but not with an anti-myosin heavy chain antibody. During proecdysis immunolabeling of the membranous layer decreased probably due to protein degradation. The staining intensity for actin and tubulin in the proecdysial epithelium was similar to that in the intermolt (anecdysial) epithelium, suggesting that there was a net accumulation of both proteins proportional to the increase in cellular volume. These results support the previous biochemical analyses and, more specifically, localize actin and tubulin in exoskeletal structures, suggesting that they may serve both intracellular and extracellular functions in crustaceans. J. Exp. Zool. 286:329-342, 2000.     

Possible sites of release of neurosecretory granules in the sinus gland of the crayfish,Orconectes nais

Summary The sinus gland is a neurohemal organ located in the crayfish eyestalk and represents a storage site for neurohormones prior to their release into the circulation. The sinus gland contains three classes of electron dense, membrane-limited granules. Class 3 granules are the largest and most electron dense of the granules found in the sinus gland. Granules of class 1 are the smallest, while those of class 2 are the most abundant. Generally, all granules undergo similar changes during their release.Release of neurosecretory material may be initiated by a preliminary fragmentation of the parent granules into smaller granules. Following the formation of numerous smaller granules, these move to the plasma membrane and their limiting membrane apparently fuses with it thus releasing its contents into the external lamina which is applied to the sinusoidal surface of the axon terminals. Granule release does not appear to occur along the entire plasma membrane adjacent to the blood sinus but, instead, probably occurs only at specific active sites on the membrane. The active sites are characterized in part by an accumulation of small granules and clear vesicles against the cytoplasmic side of the plasma membrane. At the site of release of the neurohormone, there is often an accumulation of dense homogeneous material beneath the axolemma.Occasionally, axon endings filled with large, electron lucent vesicles are seen. These clear granules vary from 1150–1750 Å in diameter and often exhibit broken limiting membranes. Few small vesicles are seen near the plasma membrane of these endings; however, instances of invaginations of the plasma membrane occur. The significance of endings filled with clear granules is discussed.Supported by a grant from the National Research Council of Canada (No. A-4675).     

Exocytosis of neurosecretory granules from the crustacean sinus gland in freeze-fracture

Exocytosis is clearly shown in freeze-fracture preparations to be the mechanism for neurosecretion granule release from axon endings in the crayfish sinus gland. The cytoplasmic leaflet (A-face) of axon ending membrane is characterized by randomly situated depressions representing invaginations of the axolemma, which are in contact with limiting membranes of neurohormone granules in the subjacent cytoplasm. The extracellular leaflet (B-face) of the axolemma at release sites exhibits complementary volcano-shaped protrusions which are cross-fractures through necks of channels formed by invaginating plasma membrane in contact with underlying neurosecretion granules. Structural variation in B-face protrusions is consistent with a spectrum of exocytotic profiles in various stages of formation, and with granules at different stages of passage out of the endings. Evidence in this study suggests that formation of exocytotic structures may begin by alteration of axon membrane structure at the neurosecretory ending-hemolymph interface prior to contact of the neurohormone granules with the axolemma. Limiting membranes of neurosecretory granules exhibit protrusions which appear to interconnect granules adjacent to release sites and to attach granules to the axolemma. Freeze-fracture is clearly shown to be an invaluable tool for monitoring the degree of exocytosis exhibited by sinus glands under normal conditions and under experimental acceleration of hormone release. This technique is capable therefore, of detecting slight increases in numbers of exocytotic profiles much more quickly and accurately than the examination of random thin sections.