Salinity-mediated carbonic anhydrase induction in the gills of the euryhaline green crab, Carcinus maenas

The euryhaline green crab, Carcinus maenas, is a relatively strong osmotic and ionic regulator, being able to maintain its hemolymph osmolality as much as 300 mOsm higher than that in the medium when the crab is acclimated to low salinity. It makes the transition from osmoconformity to osmoregulation at a critical salinity of 26 ppt, and new acclimated concentrations of hemolymph osmotic and ionic constituents are reached within 12 h after transfer to low salinity. One of the central features of this transition is an 8-fold induction of the enzyme carbonic anhydrase (CA) in the gills. This induction occurs primarily in the cytoplasmic pool of CA in the posterior, ion-transporting gills, although the membrane-associated fraction of CA also shows some induction in response to low salinity. Inhibition of branchial CA activity with acetazolamide (Az) has no effect in crabs acclimated to 32 ppt but causes a depression in hemolymph osmotic and ionic concentrations in crabs acclimated to 10 ppt. The salinity-sensitive nature of the cytoplasmic CA pool and the sensitivity of hemolymph osmotic/ionic regulation to Az confirm the enzyme's role in ion transport and regulation in this species. CA induction is a result of gene activation, as evidenced by an increase in CA mRNA at 24 h after transfer to low salinity and an increase in protein-specific CA activity immediately following at 48 h post-transfer. CA gene expression appears to be under inhibitory control by an as-yet unidentified repressor substance found in the major endocrine complex of the crab, the eyestalk.     

Effects of eyestalk ablation on carbonic anhydrase activity in the euryhaline blue crab Callinectes sapidus: neuroendocrine control of enzyme expression

Carbonic anhydrase (CA) activity in the gills of the euryhaline blue crab, Callinectes sapidus, was measured in response to acute low-salinity transfer and treatment with eyestalk ablation (ESA) in an attempt to elucidate potential regulatory mechanisms of salinity-mediated CA induction. ESA alone resulted in an approximate doubling of CA activity in the posterior, ion-transporting gills of crabs acclimated to 35 ppt. Transfer of intact crabs to 28 ppt, a salinity at which the blue crab is still an osmotic and ionic conformer, had no effect on CA activity, but treatment with ESA prior to transfer resulted in a 5-fold increase. Hemolymph osmolality was unaffected by ESA. There was a 7-fold induction of CA activity in posterior gills of intact crabs transferred from 35 to 15 ppt, and this was potentiated by about 100% by ESA. Hemolymph osmolality was slightly elevated in the ESA-treated crabs. CA activity in anterior gills did not increase in response to any treatment. Hemolymph concentrations of methyl farnesoate (MF) were measured for all experimental animals. MF concentrations were undetectable in all intact crabs, regardless of salinity. Treatment with ESA resulted in elevated levels of hemolymph MF, but these levels were still relatively low and unrelated to salinity. These results suggest that CA induction is under the control of a regulatory substance located in the eyestalk. This substance appears to be a CA repressor, keeping CA expression at low levels in the gills of crabs acclimated to high salinity. Exposure to low salinity, or treatment with ESA, removes the effects of this putative repressor and allows CA induction to occur.     

Functional genomics and sexual differentiation in amphibians

To succeed on land rather than in water, crabs require a suite of physiological and morphological changes, and ultimately the ability to reproduce without access open water. Some species have modified gills to assist in gas exchange but accessory gas exchange organs, usually lungs, occur in many species. In accomplished air-breathers the lung becomes larger and more vascularised with pulmonary vessels directing oxygenated haemolymph to the heart. The relative abundance of O₂ in air promotes relative hypoventilation and thus an internal hypercapnia to drive CO₂ excretion. Land crabs have a dual circulation via either lungs or gills and shunting between the two may depend on respiratory media or exercise state. During their breeding migration on Christmas Island Gecarcoidea natalis maintained arterial Po₂ by branchial O₂ uptake, while pulmonary O₂ pressure was reduced; partly because exercise doubled relative haemolymph flow through the gills. Related species rely on elevated haemocyanin concentration and affinity for O₂ to assist uptake but this compromises unloading at the tissues and thus the aerobic scope of tissues. Aquatic crabs exchange salt and ammonia with water via the gills but in land crabs this is not possible. Birgus latro has adopted uricotelism but other species excrete ammonia in either the urine or as gas. Land crabs minimise urinary salt loss using a filtration-reabsorption system analogous to the kidney. Urine is redirected across the gills where salt reabsorption occurs in systems under hormonal control, although in G. natalis this is stimulatory and in B. latro inhibitory. While crabs occupy a range of habitats from aquatic to terrestrial, these species do not comprise a physiological continuum but across the crab taxa individual species possess appropriate and specific physiological features to survive in their individual habitat.     

Potential of active excretion of ammonia in three different haline species of crabs

Isolated perfused gills of stenohaline crabs Cancer pagurus adapted to seawater, brackish water-adapted euryhaline shore crabs Carcinus maenas and freshwater-adapted extremely euryhaline Chinese crabs Eriocheir sinensis were tested for their capacity to excrete ammonia. Gills were perfused with haemolymph-like salines and bathed with salines equal in adaptation osmolality. Applying 100 μmol · l⁻¹ NH₄Cl in the perfusion saline and concentrations of NH₄Cl in the bath that were stepwise increased from 0 to 4000 μmol · l⁻¹ allowed us to measure transbranchial fluxes of ammonia along an outwardly as well as various inwardly directed gradients. The gills of all three crab species were capable – to different extents – of active excretion of ammonia against an inwardly directed gradient. Of the three crab species, the gills of Cancer pagurus revealed the highest capacity for active excretion of ammonia, being able to excrete it from the haemolymph (100 μmol · l⁻¹ NH⁺ ₄) through the gill epithelium against ambient concentrations of up to 800 μmol · l⁻¹, i.e. against an eightfold gradient. Carcinus maenas and E. sinensis were able to actively excrete ammonia against approximately fourfold gradients. Within the three crab species, the gills of E. sinensis exhibited the greatest capacity to resist influx at very high external concentrations of up to 4000 μmol · l⁻¹. We consider the observed capacities for excretion of ammonia against the gradient as ecologically meaningful. These benthic crustaceans protect themselves by burying themselves in the sediment, where, in contrast to the water column, concentrations of ammonia have previously been reported that greatly increase haemolymph levels. Electrophysiological results indicate that the permeabilities of the gill epithelia are a clue to understanding the species-specific differences in active excretion of ammonia. During the invasion of brackish water and freshwater, the permeabilities of the body surfaces greatly decreased. The gills of marine Cancer pagurus exibited the greatest permeability (ca. 250 mS cm⁻²), thus representing practically no influx barrier for ions including NH⁺ ₄. We therefore assume that C. pagurus had to develop the strongest mechanism of active excretion of ammonia to counteract influx. On the other hand, freshwater-adapted E. sinensis exhibited the lowest ion permeability (ca. 4 mS cm⁻²) which may reduce passive NH⁺ ₄ influxes at high ambient levels. Accepted: 14 October 1998     

Hemolymph levels of methyl farnesoate increase in response to osmotic stress in the green crab, Carcinus maenas

The salinity of estuarine environments can vary widely, exposing resident organisms to considerable osmotic stress. The green crab Carcinus maenas is well known for its ability to osmoregulate in response to such stress. Therefore, we tested the relationship between osmoregulation and hemolymph levels of methyl farnesoate (MF), a compound previously shown to rise in response to various types of environmental stresses. When crabs were transferred from 100% seawater to dilute (hypo-osmotic) seawater, hemolymph osmolality dropped rapidly, reaching an acclimation level 48 h after transfer. Hemolymph levels of MF also rose in these animals after a delay of 6 h, and reached a maximum level at 48 h. MF levels remained elevated as long as the crabs were maintained in dilute seawater, and quickly returned to basal levels when the animals were returned to full strength seawater. In most (but not all) animals, MF levels were elevated when hemolymph osmolality fell below the isosmotic point (approx. 800 mOsm/kg). These data suggest that MF may have a role in osmoregulation by this species. In addition, the elevation of MF by hypo-osmotic seawater suggests an experimental strategy for manipulating MF levels in crustaceans.     

Histopathological changes in gills of the estuarine crab Chasmagnathus granulata (Crustacea-Decapoda) following acute exposure to ammonia

Histopathological effects of ammonia on the gills of the estuarine crab Chasmagnathus granulata (Dana, 1851) were evaluated after acute exposure to ammonia concentrations around LC₅₀ value (17.85 Mm). Disruption of pilaster cells and a subsequent collapse of gill lamellae were the main effects observed. Ephitelial necrosis and hyperplasia were also detected. Significant (P<0.05) increases in pCO₂ and lactate, and significant decreases of pO₂ were detected in the haemolymph of ammonia-exposed crabs. These changes suggest that the observed histopathological damage affected gas exchange, possibly leading to death.     

Effects of photoperiod on gluconeogenic activity and total lipid concentration in organs of crabs, Neohelice granulata, challenged by salinity changes

Abstract. This study assessed the effects of long (LD) or short (SD) days on the conversion of [¹⁴C]-glycerol to [¹⁴C]-glucose and total lipid concentration in organs of the crab Neohelice granulata challenged by a change in external salinity. In the 20‰-acclimated crabs, no difference was found in the concentration of total lipids in the muscle, hepatopancreas, gills, or hemolymph between crabs acclimated to SD or LD. In SD crabs, the total lipid levels in the anterior and posterior gills did not decrease during an osmotic challenge. Only in the posterior gills did the total lipid levels decrease during acclimation to the 34‰ medium in LD animals. The total lipid concentration in the hemolymph decreased after 1 d of osmotic stress in SD, and increased in the hepatopancreas. In LD crabs, the lipid contents decreased gradually in muscle, and in the hepatopancreas on day 3 after transfer to 34‰ medium. In 20‰-acclimated crabs, the gluconeogenesis activity in both sets of gills was higher in LD than in SD animals. The gluconeogenesis capacity decreased in both sets of gills on the first day of osmotic challenge in SD, and in the posterior gills on the third day in LD crabs. These results suggest that in organs of N. granulata , photoperiod affects the metabolic adjustments to an osmotic challenge.     

Ammonia exposure of Chasmagnathus granulata (Crustacea, Decapoda) Dana, 1851: accumulation in haemolymph and effects on osmoregulation

In order to study lethal and sublethal effects of ammonia to the estuarine crab Chasmagnathus granulata in the presence of an additional stress factor such as salinity, we determined the LC₅₀ (96 h) of ammonia at 20‰ and in response to osmotic stress (5–40‰) and evaluated ammonia accumulation in the haemolymph of C. granulata and ammonia effects on osmo- and ion-regulation of this species through determinations of the haemolymph Na⁺, Ca²⁺, Cl⁻ and osmotic concentration. The LC₅₀ values (96 h) of total ammonia (NH₃+NH₄⁺) were 10.10, 17.85 and 14.0 mM for crabs maintained at 5, 20 or 40‰ salinity, respectively, suggesting that this crab is fairly resistant to ammonia. The haemolymph ammonia concentration augmented with ambient ammonia during a 6-h exposure to sublethal ammonia concentrations which were not enough to reach equilibrium between external and haemolymph ammonia. At 20‰ salinity, following a 96-h exposure to sublethal concentrations, a significant decrease (P<0.05) of haemolymphatic chloride concentration was registered at 3.3 and 5.5 mM of total ammonia. At 40‰ salinity, a significant increase (P<0.05) of the haemolymph osmotic pressure was apparent at 5.5 mM total ammonia. We postulate that C. granulata gives priority to NH₃ formation as a mechanism to eliminate it by simple diffusion. The differential Na⁺ and Cl⁻ regulation of crabs maintained at 20‰ salinity could modify the strong ion difference, augmenting pH, which in turn should lead the NH₄⁺/NH₃ equilibrium towards NH₃.     

Effect of microcystin on ion regulation and antioxidant system in gills of the estuarine crab Chasmagnathus granulatus (Decapoda,Grapsidae)

The objective of this work was to evaluate mechanisms of microcystin toxicity on crustacean species. Adult male crabs of Chasmagnathus granulatus (13.97+/-0.35 g) acclimated to low salinity (2 per thousand ) were injected with saline (control) or Microcystis aeruginosa aqueous extract (39.2 microg/l) at 24 h intervals for 48 h. After the exposure period, the anterior and posterior gills were dissected, measuring Na(+),K(+)-ATPase and glutathione-S-transferase (GST) activity. Total oxyradical scavenging capacity (TOSC) and lipid peroxides (LPO) content were also determined. Na(+),K(+)-ATPase activity in anterior gills was significantly lower in crabs injected with toxin than in control crabs, while no significant difference in the enzyme activity was detected in posterior gills. Both sodium and chloride concentration in the hemolymph were not affected by toxin exposure. Significant changes in GST activity were detected in posterior gills, with higher values being observed in the toxin-injected crabs. Crabs exposed to microcystin also showed a significant increase in the TOSC value against peroxyl radicals, for both anterior and posterior gills. Lipid peroxides level did not change in both gill types after exposure to the toxin. The increased levels of TOSC suggest the occurrence of a crab response against oxidative stress induced by toxin injection, which prevents lipid peroxidation.     

Carbon dioxide excretion and carbonic anhydrase function in the Red Rock CrabCancer productus

Summary The function of carbonic anhydrase (CA) in the Red Rock Crab,Cancer productus Randall, was investigated. CA activity was found to varying degrees in the gills and many other tissues but not in hemolymph. Crabs injected with acetazolamide, a specific CA inhibitor, demonstrated a significant hemolymph acidosis. Hemolymph CO₂ tension ( ) and CO₂ content ( ) also increased and remained significantly elevated for 96 h following treatment. No significant changes could be detected in either hemolymph oxygenation or ionic status (except for HCO ₃ ^– ) as a result of acetazolamide treatment. Crabs treated with acetazolamide, and also exposed to air, exhibited a more pronounced hemolymph acidosis with significantly increased respiratory ( ) and metabolic (lactate) components compared with the control group. Upon reimmersion acetazolamide treated crabs showed a slower recovery of hemolymph pH compared with the control group and no significant removal of the total CO₂ load induced by air exposure. No significant differences between experimental and control groups during air exposure and recovery could be detected in hemolymph oxygenation, ionic status, NH₃+NH ₄ ⁺ levels or respiratory and cardiac pumping frequency and so the effects of acetazolamide treatment were apparently limited to CO₂ removal across the gills. These results indicate that branchial CA facilitates the removal of CO₂ from the hemolymph of SW adaptedC. productus largely by catalyzing the dehydration of hemolymph HCO ₃ ^– to molecular CO₂ at the gill. It is also recognized that gill CA may also serve to hydrate molecular CO₂ to H⁺ and HCO_3/– for use as counterions for ionic uptake mechanisms. Crab gill CA thus appears to play an important role in CO₂ excretion as well as hemolymph ionic regulation.     

Immune defense reduces respiratory fitness in Callinectes sapidus, the Atlantic blue crab

Crustacean gills function in gas exchange, ion transport, and immune defense against microbial pathogens. Hemocyte aggregates that form in response to microbial pathogens become trapped in the fine vasculature of the gill, leading to the suggestion by others that respiration and ion regulation might by impaired during the course of an immune response. In the present study, injection of the pathogenic bacterium Vibrio campbellii into Callinectes sapidus, the Atlantic blue crab, caused a dramatic decline in oxygen uptake from 4.53 to 2.56 micromol g-1 h-1. This decline in oxygen uptake is associated with a large decrease in postbranchial PO2, from 16.2 (+/-0.46 SEM, n=7) to 13.1 kPa (+/-0.77 SEM, n=9), while prebranchial PO2 remains unchanged. In addition, injection of Vibrio results in the disappearance of a pH change across the gills, an indication of reduced CO2 excretion. The hemolymph hydrostatic pressure change across the gill circulation increases nearly 2-fold in Vibrio-injected crabs compared with a negligible change in pressure across the gill circulation in saline-injected, control crabs. This change, in combination with stability of heart rate and branchial chamber pressure, is indicative of a significant increase in vascular resistance across the gills that is induced by hemocyte nodule formation. A healthy, active blue crab can eliminate most invading bacteria, but the respiratory function of the gills is impaired. Thus, when blue crabs are engaged in the immune response, they are less equipped to engage in oxygen-fueled activities such as predator avoidance, prey capture, and migration. Furthermore, crabs are less fit to invade environments that are hypoxic.     

Estimation of total hemolymph volume in the horseshoe crab Limulus polyphemus

Biomedical companies extract blood from the horseshoe crab, Limulus polyphemus, for the production of Limulus Amebocyte Lysate, used worldwide for detecting endotoxins in injectable solutions and medical devices. Despite the extensive use of horseshoe crabs by the biomedical industry, total hemolymph volume for this species is not known. The hemolymph volume of 60 adult horseshoe crabs was estimated using an inulin dilution technique. Blood volume of the horseshoe crab represented as a percentage of wet body weight was 25?±?2.2% for males and 25?±?5.1% (mean?±?SD) for females. Relationships between hemolymph volume and weight (p?=?0.0026, r ²?=?0.8762), hemolymph volume and prosomal width (p?<?0.0001), and hemolymph volume and inter-ocular width (p?<?0.0001) were observed. No significant differences were observed between males and females. The relationship of animal size and hemolymph volume can be used to predict how much blood can be drawn from horseshoe crabs used by the biomedical industry, and can be of further use in future bleeding mortality studies.     

Respiration and Circulation in Land Crabs: Novel Variations on the Marine Design

Both the "true" crabs (Brachyura) and hermit crabs (Anomura)include species that show numerous behavioral, morphological,and physiological specializations permitting terrestrial life.This paper examines respiratory and circulatory adaptationsfor air breathing in these land crabs. Respiratory specializationsinclude modification of gas exchange structures for air breathing(gills and elaborated branchial chamber linings), ventilatorymechanisms permitting effective air pumping, an elevated hemolymphoxygen capacity, and a primarily CO₂- rather than O₂- sensitiveventilatory control system. The qualitative aspects of hemolymphoxygen transport and metabolic rate are apparently unchangedfrom that of marine crabs. While the basic cardiovascular morphologyof land crabs appears similar to that of marine forms, thereis considerable elaboration of the vasculature of the branchialchamber lining, which in some species includes a unique doubleportal system. Cardiac output is lower in land crabs (probablyrelated to their higher hemolymph O₂ capacity), but insufficientdata on hemolymph pressures prevent comparisons with marineforms. In general, land crabs have modified (sometimes extensively)existing structures and processes found in their marine relativesrather than evolving structures for terrestrial life de novo.Accordingly, land crabs present a useful model for the evolutionof terrestriality, showing that even subtle anatomical changescan result in the large changes in physiological function necessaryfor the terrestrial invasion.     

CO2 Excretion Across Isolated Perfused Crab Gills: Facilitation by Carbonic Anhydrase

Crab gill carbonic anhydrase is shown to facilitate the excretionof carbondioxide across isolated perfused gills. A techniquefor perfusing crab gills and assessing the metabolic viabilityof perfused gills is also described in detail. The techniqueis used to follow the disappearance of ¹⁴C label as HCO₃^–and CO₂ from internal perfusate passing through the gill. Theexcretion of the label increases with the flow rate of the externalperfusate across the outside of the gills. The addition of carbonican hydrase to the internal perfusate results in a two- to fourfoldincrease in the excretion of label while Diamox (acetazolamide)treatment decreases the excretion of label by half. It is alsosuggested that carbonic anhydrase, present in muscle tissuesof crabs, minimizes the disequilibrium of the hemolymph CO₂system as metabolically produced CO₂ leaves the tissues andenters the hemolymph. Parallels are drawn between the presenceof carbonic anhydrase in the crab gill system and the presenceof this enzyme in the respiratory organs of both aquatic andterrestrial animals.     

Behavioral and Physiological Responses to Emersion in Freshwater Bivalves

SYNOPSIS. Littoral lentic and shallow lotic freshwater habitatsare unpredictable in periodicity and duration of shore emersion.As a result, freshwater bivalves have evolved extensive capacitiesto withstand prolonged emersion. Valve movement behaviors allowemersed bivalves to control rate of water loss while maintainingat least partial aerial gas exchange; these behaviors are affectedby environmental variables such as temperature and relativehumidity. Aerial oxygen uptake is associated directly with valveventilatory behaviors and mantle edge exposure. Such behaviorsare often phasic, indicative of oxygen "debt" payment. Lackingeffective hemolymph buffer, respiratory acidosis during emersionis compensated by shell carbonate stores allowing hemolymphP_CO2 to rise to levels facilitating diffusion of CO₂ to theenvironment. During emersion, hemolymph calcium can increasefour fold while Na and Cl are tightly regulated. Ammonia productionceases in emersed bivalves. It resumes on reimmersion, indicativeof heavy reliance on non-protein catabolism during emersion.Some emersion adaptations of freshwater species appear to bemodifications of those displayed by intertidal and estuarinebivalves, while others appear independently evolved to allowsurvival of the extreme emersion periods associated with lifein shallow freshwaters.     

Free amino acid pools as effectors of osmostic adjustment in different tissues of the freshwater shrimp macrobrachium olfersii (crustacea,decapoda) during long-term salinity acclimation

To examine osmotic regulation during long-term acclimation to a hyperosmotic medium, hemolymph osmolality, [Na⁺] and total protein, tissue hydration, and free amino acid (FAA) pools in abdominal muscle, gills, central nervous tissue and hemolymph were quantified in the diadromous freshwater (FW) shrimp, Macrobrachium olfersii, during direct exposure to 21‰S seawater over a 20-day period. Hemolymph osmolality and [Na⁺] reach stable maxima within 24?h while total protein is unchanged. Muscle and nerve tissues rapidly lose water while gills hydrate; all tissues attain maximum hydration (+5%) by 5 days, declining to FW values except for gills. Total FAA are highest in muscle, reach a maximum by 2 days (+64%), declining to FW values. Gill FAA increase by 110% after 24?h, diminishing to FW values. Nerve FAA increase 187% within 24?h, and remain elevated. Hemolymph FAA decrease (?75%) after 24?h, stabilizing well below the FW concentration. During acclimation, muscle glycine (+247%), gill taurine (+253%) and proline (+150%), and nerve proline (+426%), glycine (+415%) and alanine (+139%) increase, while hemolymph leucine (?70%) decreases. Total FAA pools contribute 10–20% to intracellular (22–70?mmol/kg) and 0.5–2.4% to hemolymph (3–7?mOsm/kg) osmolalities during direct acclimation from FW. These data emphasize the modest participation of FAA pools in intracellular osmotic regulation during physiological adaptation by M. olfersii to osmotic challenge, accentuating the role of anisosmotic extracellular regulation, suggesting that, during the invasion of freshwater by the Crustacea, dependence on intracellular adjustment employing FAA as osmotic effectors, has become progressively reduced.     

Osmoregulatory disturbances induced by the parasitic barnacle Loxothylacus texanus (Rhizocephala) in the crab Callinectes rathbunae (Portunidae)

The osmoregulatory response of the blue crab Callinectes rathbunae parasitized with the rhizocephalan barnacle Loxothylacus texanus, and subjected to sudden salinity changes, was experimentally measured in the laboratory. Parasitized and control crabs were exposed to salinity changes every 3 h and their hemolymph osmolality measured. Two experiments, one with increasing salinity conditions (5‰, 12‰, 19‰, 25‰) and a second one with decreasing salinities (35‰, 25‰, 15‰, 5‰) were conducted. The results show that L. texanus significantly alters the hemolymph osmolality of C. rathbunae maintaining it at lower than normal levels. In the increasing salinity trial, the hypoosmotic hemolymph condition of parasitized crabs was present at all salinities tested, whereas in the decreasing salinity trial a significant effect was found only at salinities of 5‰ and 15‰. Since C. rathbunae is constantly subjected to abrupt salinity changes in the tropical estuaries where it occurs, moving into high salinity areas may be the only way to cope with the impact of L. texanus.     

Ammonia excretion in the seawater blue crab (Callinectes sapidus) occurs by diffusion, and not Na+/NH4+ exchange

Summary A series of experiments was conducted to investigate whether ammonia is excreted across the seawater-acclimated blue crab's gills as ionized NH ₄ ⁺ or as the free base, NH₃. The net excretion rate of ammonia was not changed by transfer of the crabs to reduced (150 mM) Na⁺ solutions, by transfer to Na⁺- and K⁺-free artificial sea water, or by the sodium transport inhibitor amiloride. Ammonia excretion, therefore, does not appear to be linked to Na⁺ uptake in these animals, and appears to take place by passive diffusion. Since ammonia could diffuse either as NH ₄ ⁺ or NH₃, we examined two other kinds of evidence. The trans-epithelial potential was measured in sea water and the various artificial media. In spite of a 10 mV more negative potential in Na⁺-, K⁺-free medium, the ammonia excretion was not reduced. Also, in alkalinized seawater in which the partial pressure gradient of NH₃ was reduced, but the concentration gradient of NH ₄ ⁺ increased, ammonia excretion was reduced by about 70%. These results are consistent with the conclusion that ammonia excretion takes place by diffusion of the free base, NH₃.Abbreviations SW sea water - ASW artificial sea water - t.e.p. transepithelial potential The University of Texas Marine Science Institute Contribution No. 461Supported by NSF Grant PCM77-24358     

Short‐term effect of hypoxia on ammonia excretion and respiration rates in the crab carcinus maenas

The metabolic response of the crab Carcinus maenas to short‐term hypoxia (60% and 35% saturated seawater) was studied at 17.5°C in fed, 3 day‐unfed and 6 day‐unfed crabs.

Ammonia excretion rate decreased under hypoxia: a 40% and 45% decrease in the normoxic rate was observed in fed crabs at 35% saturation and in 3 day‐unfed crabs at both hypoxic levels respectively. In the 6 day‐unfed crabs, the effect of hypoxia was concealed by the effect of starvation.

Oxygen consumption rate was directly related to the external O₂ tension irrespective of the crab's nutritional state. Stressed crabs behaved as a whole, as oxygen‐conformers.

A strong relationship was observed between ammonia excretion and oxygen consumption rates in fed crabs under hypoxia but not in starved crabs.