Gas-bubble disease in the blue crab, Callinectes sapidus.

Exposure of crabs to water supersaturated with air resulted in formation of gas emboli in the hemal system, which in turn caused localized ischemia. More than one-third of the exposed crabs died during the 2 days following the episode. In surviving crabs, the most severely affected organs and tissues were the gills, heart, and antennal gland. Especially in gills, emboli were still present in apparently healthy crabs 35 days following exposure to water supersaturated with air. Evidence of ischemic injury was focal in character except in the antennal gland, where the epithelium of the labyrinth was sometimes extensively degenerate. Repair processes apparently did not involve hemocytes except for occasional fibroblastic infiltration in damaged gill lamellae.     

Cardiovascular and respiratory responses associated with limb autotomy in the blue crab, Callinectes sapidus

Cardiovascular and respiratory variables were recorded in the blue crab, Callinectes sapidus, during injury and subsequent autotomy of a chela. Cardiac function and haemolymph flow rates were measured using a pulsed-Doppler flowmeter. Oxygen uptake was recorded using an intermittent flow respirometry system. Crabs reacted to the loss of a chela with a rapid increase in heart rate, which was sustained for 2 h. Stroke volume of the heart also increased after the chela was autotomized. A combined increase in heart rate and stroke volume led to an increase in cardiac output, which was maintained for an hour after the loss of a chela. There was also differential haemolymph perfusion of various structures. There was no change in perfusion of the anterolateral arteries or posterior and anterior aortae, during injury of the chela or subsequent autotomy. Haemolymph flow rates did increase significantly through the sternal artery during injury and immediately following autotomy of the chela. This was at the expense of blood flow to the digestive gland: a sustained decrease in haemolymph flow through the hepatic arteries occurred for 3 h following autotomy. Fine-scale cardiac changes associated with the act of autotomy included a bradycardia and/or associated cardiac pausing before the chela was shed, followed by a subsequent increase in cardiac parameters. Changes in the cardiovascular physiology were paralleled by an increase in oxygen uptake, which was driven by an increased ventilation of the branchial chambers. Although limb loss is a major event, it appears that only acute changes in physiology occur. These may benefit the individual, allowing rapid escape following autotomy with a subsequent return to normal activity.     

Properties of bacteria that trigger hemocytopenia in the Atlantic blue crab, Callinectes sapidus

In the blue crab Callinectes sapidus, injection with the bacterial pathogen Vibrio campbellii causes a decrease in oxygen consumption. Histological and physiological evidence suggests that the physical obstruction of hemolymph flow through the gill vasculature, caused by aggregations of bacteria and hemocytes, underlies the decrease in aerobic function associated with bacterial infection. We sought to elucidate the bacterial properties sufficient to induce a decrease in circulating hemocytes (hemocytopenia) as an indicator for the initiation of hemocyte aggregation and subsequent impairment of respiration. Lipopolysaccharide (LPS), the primary component of the gram-negative bacterial cell wall, is known to interact with crustacean hemocytes. Purified LPS was covalently bound to the surfaces of polystyrene beads resembling bacteria in size. Injection of these "LPS beads" caused a decrease in circulating hemocytes comparable to that seen with V. campbellii injection, while beads alone failed to do so. These data suggest that in general, gram-negative bacteria could stimulate hemocytopenia. To test this hypothesis, crabs were injected with different bacteria--seven gram-negative and one gram-positive species--and their effects on circulating hemocytes were assessed. With one exception, all gram-negative strains caused decreases in circulating hemocytes, suggesting an important role for LPS in the induction of this response. However, LPS is not necessary to provoke the immune response given that Bacillus coral, a gram-positive species that lacks LPS, caused a decrease in circulating hemocytes. These results suggest that a wide range of bacteria could impair metabolism in C. sapidus.     

The utilization of lipovitellin during blue crab (Callinectes sapidus) embryogenesis

Embryos of the blue crab Callinectes sapidus develop in egg sacs carried on the abdomen of the female. They develop over a period of 10-13 days at 28 degrees C and are nutritionally dependent on yolk until they emerge from the egg sacs as free-swimming zoeae. The principal component of blue crab yolk is lipovitellin (LpII), a water-soluble lipoprotein composed of approximately equal amounts of lipid and protein. We followed changes in the concentration of apoproteins of LpII during embryogenesis by ELISA and Western blots, using monoclonal antibodies against two LpII apoprotein associated peptides identified as Protein A (107 kDa) and Protein B (75 kDa). During embryogenesis there was a decrease in Protein B but an increase in two smaller peptides (52 and 35 kDa) that reacted with the Protein B antibody. Utilization of LpII during embryogenesis was also followed morphologically by immunohistochemistry. Utilization of LpII was slow in early embryonic stages, followed by rapid utilization in late embryonic stages, such that only traces of LpII were present at the end of embryogenesis. The cells of the developing hepatopancreas appear to play an important role in the utilization of LpII.     

Synthesis of a high-density lipoprotein in the developing blue crab (Callinectes sapidus)

An important lipoprotein in the hemolymph of crustaceans is LpI. It transports lipid to peripheral tissues and also has a role in crustacean immune recognition. We employed a monoclonal antibody specific for the LpI peptide to demonstrate by ELISA, western blot and immunohistochemistry the appearance of LpI during development of Callinectes sapidus, the blue crab. LpI was first found in stage 5 embryos and appeared to be synthesized by lateral basophilic cuboidal cells that demonstrated cytoplasmic immunoreactivity for LpI at their interface with the yolk mass. The embryonic cuboidal cells bore a strong cytologic resemblance to the hepatopancreas cells of later stages (zoea, megalopae, adults), which were also immunoreactive for LpI.     

Physiological aspects of molting in the blue crab Callinectes sapidus

From a respiratory and metabolic standpoint, a blue crab isin an extremely precarious condition during a molt. A molt isphysiologically possible for two major reasons. First, a premoltalkalosis anticipates the acidosis that arises during actualexuviation when the gas exchanger and ventilatory appendageare impaired and thus anaerobic metabolism must be activated.Second, the crab is able to revert to more primitive forms ofskeletal support and, immediately after exuviation, gas exchange.These mechanisms are very fragile, however, as are the cardiovascularmechanisms that provide the force for exuviation; any one mayfail. Changes in various enzyme activities and in free aminoacid content of the tissues, which are usually associated withosmotic challenges, are associated specifically with a moltas well. I suggest that they are related to isosmotic wateruptake and cell volume regulation.     

Silicification of the medial tooth in the blue crab Callinectes sapidus

Observations of cuticular structures mineralized with silica within the Crustacea have been limited to the opal teeth of copepods, mandibles of amphipods, and recently the teeth of the gastric mill in the blue crab Callinectes sapidus. Copepod teeth are deposited during premolt, with sequential elaboration of organic materials followed by secretion of silica into the tooth mold. The timing of mineralization is in stark contrast to that of the general integument of crustaceans in which calcification is completely restricted to the postmolt period. To determine the timing of molt‐related deposition and silicification of the teeth of the gastric mill, the medial tooth of the blue crab C. sapidus was examined histologically and ultrastructurally across the molt cycle. Histological data revealed deposition of the organic matrix of the epicuticle and exocuticle during premolt. No evidence of postmolt changes in the thickness of the epicuticle and exocuticle, or any deposition of endocuticle, was observed. Scanning electron microscopy revealed degradation of the outer surface of the old tooth during premolt. During premolt, epithelial structures resembling papilla appeared to secrete a fibrous web that coalesces to become the matrix of the new tooth. Semi‐quantitative elemental analyses indicated simultaneous deposition of silica and organic matrix, and demonstrated a homogeneous distribution of silicon throughout the epicuticle of the tooth at all stages. However, there is evidence of deposition (presumably silicification) during postmolt as spaces between the papillae become filled in. Thus, the pattern and timing of deposition and silicification of the tooth are different from both teeth of copepods and the general exoskeleton of decapods, and may facilitate rapid resumption of feeding and consumption of the exuvia in early postmolt. J. Morphol. 277:1648–1660, 2016. © 2016 Wiley Periodicals, Inc.     

Sensory physiology and behavior of blue crab (Callinectes sapidus) postlarvae during horizontaltransport

Adult blue crabs (Callinectes sapidus) live in estuaries and release larvae near the entrances to estuaries. Larvae are then transported offshore to continental shelf areas where they undergo development. Postlarvae, or megalopae, remain near the surface and undergo reverse diel vertical migration. The behaviors underlying this migration pattern are responses to light and a solar day rhythm in activity, in which megalopae are active during the day and inactive at night. Onshore transport probably occurs by wind‐generated surface currents. Once in the vicinity of an estuary, megalopae move up the estuary by selective tidal stream transport, in which they swim in the water column on rising tides at night and are on or near the bottom at all other times. Light inhibits swimming during the day. The ascent into the water column on nocturnal rising tides does not result from a biological rhythm in activity, but rather is cued by the rate of increase in salinity during rising tides. Megalopae have separatebehavioural responses in coastal/shelf areas and in estuaries, which are induced by chemical cues in offshore and estuarine waters.     

Purification and characterization of an iron-binding protein from the blue crab (Callinectes sapidus)

The presence of an iron-binding protein in the hemolymph of the blue crab (Callinectes sapidus) was detected by gel filtration of 59Fe-labeled hemolymph. The iron-binding protein was purified to homogeneity by ion exchange chromatography. 2. This protein has a mol. wt of 155,000 and consists of a single polypeptide chain with an isoelectric point of 5.0. 3. Analysis of the iron-loaded protein indicates that it has a high affinity for iron and the capacity to bind approximately 10 atoms iron/molecule protein. 4. The isolation of a specific iron-binding protein from the blue crab (Callinectes sapidus) provides additional support for the proposal that such proteins are an ancient evolutionary development not necessarily linked to the appearance of iron proteins (hemoglobin and hemerythrin) as a means for oxygen transport.     

Colonization of the gut of the blue crab (Callinectes sapidus) by Vibrio cholerae

Attachment of Vibrio cholerae to the mucosal surface of the intestine is considered to be an important virulence characteristic. Vibrio cholerae, an autochthonous member of brackish water and estuarine bacterial communities, also attaches to crustacea, a significant factor in multiplication and survival of V. cholerae in nature. The ability of V. cholerae to attach to the gut wall of the blue crab (Callinectes sapidus) was examined, and attachment was observed only in the hindgut and not the midgut of crabs, confirming a requirement for chitin in the attachment of V. cholerae to invertebrate and zooplankton surfaces. The new finding of attachment of V. cholerae to the hindgut of crabs may be correlated with the epidemiology and transmission of cholera in the aquatic environment. The crab model may also prove useful in elucidating the mechanism(s) of ion transport in crustacea.     

Respiration and phosphorylation by mitochondria from the hepatopancreas of the blue crab (Callinectes sapidus)

Mitochondria isolated from the hepatopancreas of the blue crab Callinectes sapidus show high rates of oxidation of pyruvate + proline and of various intermediates of the tricarboxylic acid cycle in a 280- to 380-mOsm sucrose-mannitol medium supplemented with bovine serum albumin. The respiratory control ratio ranged from 6 to 10. Respiration was accompanied by phosphorylation of ADP, with the expected ADP:O ratio for all substrates tested except α-ketoglutarate, indicating that all three energy-conserving sites were functional. Fatty acids were also oxidized, but no oxidation of β-hydroxybutyrate, glycerol 3-phosphate, or NADH was observed. The crab mitochondria showed a relatively low affinity for phosphate, but a normal affinity for ADP. Respiration and phosphorylation gave the normal responses to respiratory chain inhibitors, uncoupling agents, oligomycin, and ionophores. Crab mitochondria have an exceptionally high content of phosphate, exceeding 1000 nmoles per mg protein, but a normal energy charge of the adenylic system. An unusual feature is the presence of considerable arginine kinase activity, which is usually thought to be restricted to muscle and nerve tissue in anthropods. This enzyme allows arginine to act as secondary phosphate acceptor. The arginine kinase is located on the cytosol side of the atractyloside-sensitive barrier and is thus unable to transfer the terminal phosphate group of matrix ATP directly to arginine.     

Comparative properties of channel catfish (Ictalurus punctatus) and blue crab (Callinectes sapidus) acetylcholinesterases

1. Acetylcholinesterases (AChEs) from channel catfish and blue crabs were examined for substrate preference, KmS, effects of inhibitors, and pH and osmotic activity profiles. 2. Similarities were noted for substrate preference along with pH and osmotic optima. 3. Crab AChE had a lower Km (9 x 10(-5) vs 2 x 10(-4) M) and was more sensitive in terms of KI50S than fish AChE to eserine (2.6 x 10(-7) vs 3 x 10(-7) M), malathion (4.5 x 10(-5) vs 1.6 x 10(-4) M) and parathion (6.9 x 10(-5) vs 7 x 10(-4) M). 4. Fish AChE appeared easier to solubilize using Triton X-100.     

A viral disease of the blue crab,Callinectes sapidus: Histopathology and differential diagnosis

A disease of the blue crab caused by a cytoplasmic virus morphologically resembling reovirus is described. Crabs infected with the virus were collected both from a low-salinity tributary of Chesapeake Bay, Maryland, and from Chicoteague Bay, Virginia, a high-salinity area. Virus occurs with greatest frequency in cells of the hemopoietic tissue and in hyaline hemocytes. It is also found in epidermis and gill epithelia and within the neurilemma where it occurs in granulocytes and other cells of uncertain identity. The following diseases are considered in the differential diagnosis of the viral infection: paramoebiasis, bacterial infection, microsporidan infection, Hematodinium infection, and disease caused by a herpes-like virus.     

Formation of the arthrodial membrane in the blue crab,Callinectes sapidus

In this study the pattern of arthrodial membrane deposition in Callinectes sapidus was determined by histological and ultrastructural examination of tissues from the carpus joint of the cheliped collected during premolt, ecdysis, postmolt, and intermolt. Apolysis in the arthrodial membrane occurs at stage D(0) and is synchronous with apolysis of the calcified cuticle. Epicuticle formation begins at early stage D(1) and is completed in late stage D(1). Procuticle deposition starts at D(2) and continues until ecdysis. Numerous cytoplasmic extensions occur throughout the lamellae. Component fibers of the arthrodial membrane are intimately associated with dense plaques on the apical membrane of the underlying hypodermal cells, suggesting a site for fiber polymerization. Deposition of the arthrodial membrane continues after ecdysis, with most of the cuticle thickening occurring during stage C. When stained with PAS and counterstained with hematoxylin, a difference can be discerned between preecdysial and postecdysial procuticle of the arthrodial membrane, a distinction not made in previous studies. The boundary between the arthrodial membrane and calcified cuticle is thicker than either of the two layers and the layers overlap rather than butting up against one another. This pattern suggests that underlying hypodermal cells have to produce multiple types of cuticle over the molt cycle. A summary of the various molting patterns in C. sapidus suggests that the control of these diverse events may prove to be complex.     

Colonization of the gut of the blue crab (Callinectes sapidus) by Vibrio cholerae.

Attachment of Vibrio cholerae to the mucosal surface of the intestine is considered to be an important virulence characteristic. Vibrio cholerae, an autochthonous member of brackish water and estuarine bacterial communities, also attaches to crustacea, a significant factor in multiplication and survival of V. cholerae in nature. The ability of V. cholerae to attach to the gut wall of the blue crab (Callinectes sapidus) was examined, and attachment was observed only in the hindgut and not the midgut of crabs, confirming a requirement for chitin in the attachment of V. cholerae to invertebrate and zooplankton surfaces. The new finding of attachment of V. cholerae to the hindgut of crabs may be correlated with the epidemiology and transmission of cholera in the aquatic environment. The crab model may also prove useful in elucidating the mechanism(s) of ion transport in crustacea.