Perception of odor mixtures by the spiny lobster Panulirus argus

We used spiny lobsters (Panulirus argus) in a discriminationlearning procedure with aversive conditioning to examine theirbehavioral discrimination of adenosine-5'-monophosphate (AMP),betaine, L-cysteine and their binary mixtures. Our results showthat spiny lobsters can clearly discriminate among binary mixturesand their components. Lobsters aversively conditioned to avoidresponding to a binary mixture continued to respond to thatmixture's components, and lobsters that were aversively conditionedto avoid responding to a compound tended to continue to respondto binary mixtures containing that compound. Thus, responsesof conditioned lobsters to binary mixtures were not usuallyintermediate between the responses to the mixtures' components,which might be expected for response-matched compounds. Thisresult might arise from any of several factors. First, it mightresult from mixture interactions in the peripheral olfactorysystem, if the responses of olfactory receptor neurons to onecomponent of a binary mixture were suppressed by the other component,making the response to the mixture more similar to the suppressingcomponent. Electrophysiological data from a population of 50singly-recorded olfactory receptor neurons (Daniel and Derby,1994) do not consistently support this idea. A second possiblereason for the behavioral response to a binary mixture not beingintermediate between the responses to its components involveshigher order processing, such as mixture interactions generatedin olfactory interneurons in the CNS (which is known to occur:Derby et al., 1985; Ache, 1989), configural learning or associativeprocessing.     

Coding of blend ratios of binary mixtures by olfactory neurons in the Florida spiny lobster, Panulirus argus

The aim of this study was to investigate quality coding of blend ratios of binary mixtures by olfactory receptor cells in the spiny lobster. Three odorants (adenosine-5′-monophosphate, l-glutamate, and taurine) at 0.1–100 μmol · l⁻¹ and seven blend ratios of each of their binary mixtures at a total concentration of 100 μmol · l⁻¹ were used. The olfactory cells recorded (n = 48) evoked across-neuron patterns for single odorants that were well separated from each other. Across-neuron patterns varied with stimulus concentration but less than with stimulus type. Blend ratios of the three mixtures evoked across-neuron patterns that were orderly placed within a continuum between those elicited by the components. Mixture interactions, defined as a lack of independent effects by a mixture's components, occurred in 25, 24 and 37% of responses to blend ratios of glutamate/taurine, adenosine-5′-monophosphate/taurine, and glutamate/adenosine-5′-monophosphate, respectively. These mixture interactions did not have a large enough effect on the across-neuron patterns for the mixtures such they would be novel relative to those of the single components. These results suggest that despite mixture interactions the quality of individual compounds is not lost when mixed. This corroborates behavioral studies showing that spiny lobsters have the ability to elementally process odor mixtures. Accepted: 23 August 1996     

A CUB-serine protease in the olfactory organ of the spiny lobster Panulirus argus.

csp, a gene encoding a protein with high sequence identity to trypsinlike serine protease and CUB domains, was identified from a cDNA library from the olfactory organ (antennular lateral flagellum) of the spiny lobster Panulirus argus. The full-length cDNA sequence of csp is 1801 bp, encoding a protein of 50.25 kD, with three domains: signal peptide, trypsinlike serine protease, and CUB (named for a class of compounds including Complement subcomponents Clr/Cls, Uegf, and Bone morphogenic protein-1). RT-PCR, Northern blots, and immunoblots showed that csp is predominantly expressed in the lateral flagellum and eyestalk. Immunocytochemistry showed that Csp is present in olfactory (aesthetasc) sensilla around auxiliary cells (glia that surround the inner dendrites of olfactory receptor neurons, ORNs) and ORN outer dendrites. We propose that Csp is expressed and secreted by auxiliary cells, associates with ORN cell membranes or extracellular matrix via the CUB domain, and has trypsinlike activity. In the eyestalk, Csp is associated with cells surrounding axons between neuropils of the eyestalk ganglia. Possible functions in the olfactory organ and eyestalk are discussed. To our knowledge, this is the first report from any olfactory system of a gene encoding a protein with serine protease and CUB domains.     

Behavioral thermoregulation in the spiny lobster Panulirus Argus (latreille)

Ten spiny lobsters (Panulirus argus) were allowed to thermoregulate individually for 3-day periods in an electronic thermoregulatory shuttlebox which allowed them to control water temperatures (and thereby their own body temperatures) by their movements. The range of preferred (voluntarily occupied) temperatures was 25–35°C (mean 29.9°C; mode 30.0°C; median 30.0°C; midpoint 30.0°C; S_k (skewness, Pearson's coefficient) –0.04; s.e.m. 0.19°C; S.D. 2.32°C). The final thermal preferendum (by the gravitation method) in this species is 30°C.     

Complex binding interactions between multicomponent mixtures and odorant receptors in the olfactory organ of the Caribbean spiny lobster Panulirus argus

Our study was designed to examine how components of complex mixtures can inhibit the binding of other components to receptor sites in the olfactory system of the spiny lobster Panulirus argus. Biochemical binding assays were used to study how two- to six-component mixtures inhibit binding of the radiolabeled odorants taurine, L-glutamate and adenosine-5'-monophosphate to a tissue fraction rich in dendritic membrane of olfactory receptor neurons. Our results indicate that binding inhibition by mixtures can be large and is dependent on the nature of the odorant ligand and on the concentration and composition of the mixture. The binding inhibition by mixtures of structurally related components was generally predicted using a competitive binding model and binding inhibition data for the individual components. This was not the case for binding inhibition by most mixtures of structurally unrelated odorants. The binding inhibition for these mixtures was generally smaller than that for one or more of their components, indicating that complex binding interactions between components can reduce their ability to inhibit binding. The magnitude of binding inhibition was influenced more by the mixture's precise composition than by the number of components in it, since mixtures with few components were sometimes more inhibitory than mixtures with more components. These findings raise the possibility that complex binding interactions between components of a mixture and their receptors may shape the output of olfactory receptor neurons to complex mixtures.      

A CUB‐serine protease in the olfactory organ of the spiny lobster Panulirus argus

csp, a gene encoding a protein with high sequence identity to trypsinlike serine protease and CUB domains, was identified from a cDNA library from the olfactory organ (antennular lateral flagellum) of the spiny lobster Panulirus argus. The full‐length cDNA sequence of csp is 1801 bp, encoding a protein of 50.25 kD, with three domains: signal peptide, trypsinlike serine protease, and CUB (named for a class of compounds including C omplement subcomponents Clr/Cls, U egf, and B one morphogenic protein‐1). RT‐PCR, Northern blots, and immunoblots showed that csp is predominantly expressed in the lateral flagellum and eyestalk. Immunocytochemistry showed that Csp is present in olfactory (aesthetasc) sensilla around auxiliary cells (glia that surround the inner dendrites of olfactory receptor neurons, ORNs) and ORN outer dendrites. We propose that Csp is expressed and secreted by auxiliary cells, associates with ORN cell membranes or extracellular matrix via the CUB domain, and has trypsinlike activity. In the eyestalk, Csp is associated with cells surrounding axons between neuropils of the eyestalk ganglia. Possible functions in the olfactory organ and eyestalk are discussed. To our knowledge, this is the first report from any olfactory system of a gene encoding a protein with serine protease and CUB domains. © 2001 John Wiley & Sons, Inc. J Neurobiol 49: 277–302, 2001     

Hemocyanin-derived phenoloxidase activity in the spiny lobster Panulirus argus (Latreille, 1804)

Hemocyanin and phenoloxidase belong to the type-3 copper protein family, sharing a similar active center whereas performing different roles. In this study, we demonstrated that purified hemocyanin (450 kDa) from the spiny lobster Panulirus argus shows phenoloxidase activity in vitro after treatment with trypsin, chymotrypsin and SDS (0.1% optimal concentration), but it is not activated by sodium perchlorate or isopropanol. The optimal pHs of the SDS-activated hemocyanin were 5.5 and 7.0. Hemocyanin from spiny lobster behaves as a catecholoxidase. Kinetic characterization using dopamine, L-DOPA and catechol shows that dopamine is the most specific substrate. Catechol and dopamine produced substrate inhibition above 16 and 2 mM respectively. Mechanism-based inhibition was also evidenced for the three substrates, being less significant for L-DOPA. SDS-activated phenoloxidase activity is produced by the hexameric hemocyanin. Zymographic analysis demonstrated that incubation of native hemocyanin with trypsin and chymotrypsin, produced bands of 170 and 190 kDa respectively, with intense phenoloxidase activity. Three polypeptide chains of 77, 80 and 89 kDa of hemocyanin monomers were identified by SDS-PAGE. Monomers did not show phenoloxidase activity induced by SDS or partial proteolysis.     

Phenoloxidase activity in the hemolymph of the spiny lobster Panulirus argus

The prophenoloxidase activating system plays a major role in the defense mechanism of arthropods. In the present study, the phenoloxidase activity and its location in the hemolymph of the spiny lobster Panulirus argus is presented. Phenoloxidase activity was observed in the hemocyte lysate supernatant (HLS) and plasma after their incubation with trypsin. Higher amounts of trypsin were required to activate the HLS prophenoloxidase, due to the presence of a trypsin inhibitor in this fraction. Activation of prophenoloxidase was found when HLS was incubated with calcium, with an optimal pH between 7.5 and 8. This spontaneous activity is due to the prophenoloxidase activating enzyme, a serine proteinase that activates the prophenoloxidase once calcium ions were available. SDS was able to induce phenoloxidase activity in plasma and hemocyte fractions. Prophenoloxidase from HLS occurs as an aggregate of 300kDa. Electrophoretic studies combining SDS-PAGE and native PAGE indicate that different proteins produced the phenoloxidase activity found in HLS and plasma. Thus, as in most crustaceans, Panulirus argus contains a prophenoloxidase activating system in its hemocyte, comprising at least the prophenoloxidase activating enzyme and the prophenoloxidase. Finally, it is suggested that phenoloxidase activity found in plasma is produced by hemocyanin.     

Sustained primary culture of lobster (Panulirus argus) olfactory receptor neurons

Appropriate conditions were developed for primary sustained culture of olfactory neurons of the spiny lobster Panulirus argus. Neurons were cultured in a modified Liebowitz L15 media supplemented with Panulirus salts, basic minimal essential (BME) vitamins, L-glutamine, low dextrose, and either fetal calf serum (FCS) or lobster haemolymph. Neurite outgrowth and cell viability was strongly affected by choice of adherent substratum, presence of serum, and length of animal captivity. Neither nerve growth factor 7s (NGF-7s), HEPES, nor preconditioned media from the target organ, the olfactory lobe, had any gross effect on either longevity or neurite outgrowth. Five morphologically distinct neuronal cell types (8-16 mum soma diameter) could be defined based on their number and type of processes. All of these cells were electrically excitable (N = 50), and many (56%) produced either inward or outward currents in response to stimulation with single odors. The proportion of cells responding to odors increased (80%) when 10 cells were sequentially presented with a series of 3-5 odors. The finding that cultured cells maintain responsiveness to odors yet are morphologically more compact than their counterparts in situ, argues for the prospect of using these dissociated cultured olfactory receptor neurons to study signal transduction in olfaction.     

Loss of escape-related giant neurons in a spiny lobster, Panulirus argus

When attacked, many decapod crustaceans perform tailflips, which are triggered by a neural circuit that includes lateral giant interneurons, medial giant interneurons, and fast flexor motor giant neurons (MoGs). Slipper lobsters (Scyllaridae) lack these giant neurons, and it has been hypothesized that behavioral (e.g., digging) and morphological (e.g., flattening and armor) specializations in this group caused the loss of escape-related giant neurons. To test this hypothesis, we examined a species of spiny lobster, Panulirus argus. Spiny lobsters belong to the sister taxon of the scyllarids, but they have a more crayfish-like morphology than scyllarids and were predicted to have escape-related giant neurons. Ventral nerve cords of P. argus were examined using paraffin-embedded sections and cobalt backfills. We found no escape-related giant neurons and no large axon profiles in the dorsal region of the nerve cord of P. argus. Cobalt backfills showed one fewer fast flexor motor neuron than in species with MoGs and none of the fast flexor motor neurons show any of the anatomical specializations of MoGs. This suggests that all palinuran species lack this giant escape circuit, and that the loss of rapid escape behavior preceded, and may have driven, alternative predator avoidance and anti-predator strategies in palinurans.     

Glucose and sulfate conjugation of phenolic compounds by the spiny lobster (Panulirus argus)

Previous work has shown that the hepatopancreas of the spiny lobster (Panulirus argus) contains a mixed-function oxidase system capable of catalyzing the monooxygenation of polycyclic aromatic hydrocarbons to highly toxic products similar to those formed by mammalian tissues. Studies were designed to determine the ability of the spiny lobster to conjugate the phenolic compounds 4-methylumbelliferone, p-nitrophenol, beta-naphthol, and 3-hydroxybenzo[a]pyrene with endogenous molecules. The hepatopancreas contained UDP-glucose (UDPG) dependent glucosyltransferase, while no activity was detected when UDP-glucuronic acid was used as the cosubstrate. Atypical Michaelis-Menten kinetics result with varying concentrations of UDPG, indicating that multiple forms of glucosyltransferase may exist in this organ. The activity was localized in the microsomal fraction, exhibited a pH optimum at 8.0-8.5, and a temperature optimum of 30 degrees C. Sulfate conjugation was found only in the cytosolic fraction of the antennal gland and used adenosine 3'-phosphate 5'-phosphosulfate (PAPS) as the sulfate donor (Km(apparent) = 9.0 +/- 4.9 microM). Hepatopancreas cytosol inhibited sulfotransferase activity. The pH optimum of antennal gland sulfotransferase was a function of the substrate and ranged from 5.5 to 7.4. Analysis of spiny lobster urine 24 hr following exposure to 3-hydroxybenzo[a]pyrene demonstrated the ability of the lobster to form both the sulfate and glucoside conjugate in vivo.     

Polymorphic tetranucleotide microsatellite markers in the Caribbean spiny lobster,Panulirus argus

Ten tetranucleotide microsatellite loci are described for the Caribbean spiny lobster Panulirus argus. Loci were polymorphic (4–15 alleles per locus) and exhibited high levels of expected (0.553–0.921) and observed heterozygosity (0.469–0.906) from samples caught off Belize and Puerto Rico coasts. No significant departure from Hardy–Weinberg equilibrium conditions were observed for any locus. All microsatellite loci should be useful for assessing population discrimination for this valuable marine animal currently subjected to excessive fishing efforts.     

Polymorphism and partial characterization of digestive enzymes in the spiny lobster Panulirus argus

We characterized major digestive enzymes in Panulirus argus using a combination of biochemical assays and substrate-(SDS or native)-PAGE. Protease and amylase activities were found in the gastric juice while esterase and lipase activities were higher in the digestive gland. Trypsin-like activity was higher than chymotrypsin-like activity in the gastric juice and digestive gland. Stability and optimal conditions for digestive enzyme activities were examined under different pHs, temperature and ionic strength. The use of protease inhibitors showed the prevalence of serine proteases and metalloproteases. Results for serine proteases were corroborated by zymograms where several isotrypsins-like (17-21 kDa) and isochymotrypsin-like enzymes (23-38 kDa) were identified. Amylases (38-47 kDa) were detected in zymograms and a complex array of non-specific esterases isoenzymes was found in the digestive gland. Isoenzyme polymorphism was found for trypsin, amylase, and esterase. This study is the first to evidence the biochemical bases of the plasticity in feeding habits of P. argus. Distribution and properties of enzymes provided some indication on how the digestion takes place and constitute baseline data for further studies on the digestion physiology of spiny lobsters.     

Ecto-ATPase/phosphatase activity in the olfactory sensilla of the spiny lobster,Panulirus argus: localization and characterization

Summary Electrophysiological studies have shown that the olfactory organ (antennule) of the spiny lobster, Panulirus argus, has chemoreceptors that are selectively excited by adenine nucleotides in seawater. Biochemical studies have revealed that these same nucleotides can be rapidly dephosphorylated by ectoenzymes associated with the olfactory sensilla (aesthetascs). In this study the distribution of ecto-ATPase/phosphatase activity within aesthetascs was determined cytochemically and the nature of the adenine-nucleotide dephosphorylating activity was dissected biochemically. Cytochemically, the distribution of ATP-dephosphorylating activity was similar to that shown previously for AMP and -glycerol phosphate; i.e., cerium phosphate reaction product was specifically localized to the transitional zone where the sensory dendrites develop cilia and branch to form the outer dendritic segments. Unlike the dephosphorylation of AMP and -glycerol phosphate, Mg²⁺ or Ca²⁺ was required for ecto-ATPase/phosphatase activity. Biochemical measures of both AMP-and ATP-dephosphorylating activity within aesthetascs corroborated the cytochemical evidence that these activities are localized to the transitional zone. A major portion of the AMP dephosphorylation (about 67%) derives from nonspecific alkaline phosphatase activity that is insensitive to levamisole and L-bromotetramisole. In contrast, nonspecific phosphatase activity accounted for a much smaller part of the ATP dephosphorylation (about 15%). Ectoenzymatic activity in the transitional zone may be an important means of removing excitatory/inhibitory nucleotides from this region.Abbreviations ADP Adenosine 5-diphosphate - AMP adenosine 5-monophosphate - AMPCP , -methylene ADP - ASW artificial seawater - ATP adenosine 5-triphosphate - -GP -glycerol phosphate - EM electron microscopy     

Rosette-type tegumental glands associated with aesthetasc sensilla in the olfactory organ of the Caribbean spiny lobster, Panulirus argus

The lateral antennular flagellum of decapod crustaceans bears unique olfactory sensilla, namely the aesthetascs, and other sensilla types. In this study, we identify a new major tissue in the lateral flagellum of the Caribbean spiny lobster, Panulirus argus, namely “aesthetasc tegumental glands” (ATGs), based on immunostaining with antibodies against CUB serine protease (Csp), in situ hybridization with csp-specific probes, labeling with the F-actin marker phalloidin, labeling with the nuclear marker Hoechst 33258, and staining with methylene blue. Each ATG has 12–20 secretory cells arranged in a rosette. Each secretory cell has a Csp-immunoreactive basal portion and an apical portion containing granular material (metachromatic staining indicative of acid mucopolysaccharides). At the center of each secretory rosette is a phalloidin-positive common locus that gives rise to a main drainage duct projecting toward the cuticle. Scanning electron and light microscopy show that thin ducts traverse the cuticle and connect to “peg pores” proximal to the bases of the aesthetascs, with 3.4 peg pores per aesthetasc. Since the number of common loci is correlated with the number of peg pores, we conclude that each pore represents the outlet of one ATG, and that the secretions are released from them. We conclude further that ATGs and aesthetascs are functionally linked. We hypothesize that ATG secretions have antifouling and/or friction-reducing properties, and that they are spread over the surface of the aesthetascs by antennular grooming. A review of the literature suggests that ATGs are common in decapod crustacean antennules, and that rosette glands and grooming might be functionally coupled in other body areas.This study was supported by NSF IBN 0077474 and NIH DC00312.     

Primary culture of hemocytes from the Caribbean spiny lobster, Panulirus argus, and their susceptibility to Panulirus argus Virus 1 (PaV1)

Primary cultures of hemocytes from the Caribbean spiny lobster Panulirus argus were developed for studies on the in vitro propagation of Panulirus argus Virus 1 (PaV1). A modified Leibovitz L-15 medium supported the best survival of hemocytes in in vitro primary cultures. However, degradation of the cultures occurred rapidly in the presence of granulocytes. A Percoll step gradient was used to separate hemocytes into three subpopulations enriched in hyalinocytes, semigranulocytes, and granulocytes, respectively. When cultured separately, hyalinocytes and semigranulocytes maintained higher viability ( approximately 80%) after 18 days incubation compared with granulocytes, which degraded over 2-3 days. Susceptibility of the cell types was investigated in challenge studies with PaV1. Hyalinocytes and semigranulocytes were susceptible to PaV1. Cytopathic effects (CPE) were observed as early as 12h post-inoculation, and as the infection progressed, CPE became more apparent, with cell debris and cellular exudates present in inoculated cultures. Cell lysis was noticeable within 24h of infection. The presence of virus within cells was further confirmed by in situ hybridization using a specific DNA probe. The probe gave a unique staining pattern to cells infected with PaV1 24-h post-inoculation. Cells in the control treatment were intact and negative to hybridization. This assay was further applied to the quantification of infectious virus in hemolymph using a 50% tissue culture infectious dose assay (TCID(50)) based on CPE. These tools will now allow the quantification of PaV1 using established culture-based methods.     

Processing of antennular input in the brain of the spiny lobster, Panulirus argus

Neurons in the olfactory deutocerebrum of the spiny lobster, Panulirus argus, were recorded intracellularly and filled with biocytin. Recorded neurons arborized in the olfactory lobe (OL), a glomerular neuropil innervated by olfactory and some presumptive mechanosensory antennular afferents. The neurons responded to chemosensory input from the lateral antennular flagellum bearing the olfactory sensilla but not the medial flagellum bearing many non-olfactory chemosensory sensilla. Many neurons received additional mechanosensory input. Thus the OL integrates specifically olfactory with mechanosensory input. OL neurons had multiglomerular arborizations restricted to one or two of the three horizontal layers of the columnar glomeruli. OL local interneurons comprised core neurons with tree-like neurites and terminals in the base of the glomeruli and rim neurons with neurites surrounding the OL and terminals in the cap/subcap. The somata of OL local interneurons lay in the medial soma cluster (100000 somata). OL projection neurons arborized in the base of the glomeruli and ascended via the olfactory glomerular tract to the lateral protocerebrum. A parallel projection pathway is constituted by projection neurons of the accessory lobe, a glomerular neuropil without afferent innervation but intimate links to the OL. The projection neuron somata constituted the lateral soma cluster (200000 somata).Abbreviations AC anterior cluster (cluster 6,7) - AL accessory lobe - aMC anterior subcluster of medial cluster (cluster 9) - A _lNv main antenna I (antennular) nerve - A _lNM antenna I (antennular) motor nerve - A _llNv main antenna II (antennal) nerve - CB central body - CL central layer of accessory lobe - DC deutocerebral commissure - DCN deutocerebral commissure neuropil - dDUMC dorsal subcluster of dorsal unpaired median cluster (cluster 17) - dMC dorsal subcluster of medial cluster (cluster 11) - dVPALC dorsal subcluster of ventral paired anterolateral cluster (cluster 8) G glomerulus - IDUMC lateral subcluster of dorsal unpaired median cluster (cluster 16) - LC lateral cluster (cluster 10) - LF lateral flagellum of antenna I (antennule) - LL lateral layer of accessory lobe - MF medial flagellum of antenna I (antennule) - ML medial layer of accessory lobe - MPN anterior and posterior median protocerebral neuropils - OGT olfactory globular tract - OGTN olfactory globular tract neuropil - OL olfactory lobe - OLALT olfactory lobe-accessory lobe tract - PB protocerebral bridge - pMC posterior subcluster of medial cluster (cluster 9) - PT protocerebral tract - TNv tegumentary nerve - VPMC ventral paired medial cluster (cluster 12) - VUMC ventral unpaired medial cluster (cluster 13) - vVPALC ventral subcluster of ventral paired anterolateral cluster (cluster 8) - ASW artificial sea water - M3 mixture 3 - PRO L-proline - TM TetraMarin extract