Behaviour studies of the fungicide cymoxanil in two strains of the fungus Botrytis cinerea and in haemolymph of locust and lobster. I. In situ monitoring by internal surface reversed-phase high-performance liquid chromatography.

A method for following the metabolism of the fungicide cymoxanil in various biological media is described. By using a recently developed high-performance liquid chromatographic method, with an internal surface reversed-phase column, it is unnecessary to clean up the sample before analysis. Thus this technique makes monitoring in fungi as well as in arthropod haemolymph easier and faster.

Comparison of microwave digestion with conventional wet ashing and dry ashing digestion for analysis of lead, cadmium, chromium, copper, and zinc in shellfish by flame atomic absorption spectroscopy.

A closed vessel microwave digestion procedure was developed for shellfish samples. This procedure was compared with wet and dry ash procedures for levels of lead, cadmium, chromium, copper, and zinc. Results obtained for microwave and conventional wet ash digestion were comparable. The dry ashing procedure produced results consistently lower than either of the other methods. Recoveries ranged from 80-92% for microwave and wet ashing procedures and 54-72% for the dry ashing procedure. Accuracy was also determined by analyzing lobster hepatopancreas marine reference material. Values for Pb, Cd, and Cr fell within the range specified for the reference material for all 3 digestion procedures; however, values were lower for Cu and Zn. Results of this study show that microwave digestion is comparable to wet ashing.

American lobster troponin.

Troponin was isolated from the abdominal muscle of the American lobster (Homarus americanus) by essentially the same method as used for akazara scallop troponin [J. Biol. Chem. 261, 16749-16754 (1986)]. The thus isolated troponin together with lobster tropomyosin confers high Ca2(+)-sensitivity to rabbit reconstituted actomyosin. The troponin consists of components having Mr of about 42,000, 32,000, 30,000, and 17,000, but not the Mr 52,000-59,000 component previously reported to be present in several crustacean troponins. These troponin components were separated from each other by DEAE-Toyopearl column chromatography in the presence of 6 M urea. The Mr 17,000 component was further separated into one major and two minor components by the same chromatography, but each of them was confirmed to be a Ca2+ binding component, TnC. The Mr 32,000 and 30,000 components were both regarded as inhibitory subunits, TnIs, since the Mg-ATPase activity of actomyosin in the presence of tropomyosin was strongly inhibited by the addition of the components, and the inhibition was reversed by the further addition of TnC. Finally, the Mr 42,000 component was regarded as TnT, since this component formed stoichiometic complex with TnC and TnI, and was indispensable for Ca2+ regulation of the actomyosin-tropomyosin system.

Purification and chemical characterization of peptide G1, an invertebrate neuropeptide that stimulates cyclic GMP metabolism.

Bioassay analysis of extracts of the major neurosecretory structures of the American lobster have revealed several different agents with stimulatory effects on the cyclic GMP metabolism of various lobster tissues. The most potent of these is a peptide extracted from the sinus gland, a neurohemal organ found in the animal's eyestalk. This molecule, called peptide G1 (for its effects on cyclic GMP metabolism), can increase the cyclic GMP content of every lobster tissue tested, sometimes by as much as 200-fold. In this article, we describe the purification and some of the chemical properties of peptide G1. Purification was accomplished by sequential anion exchange and reverse-phase HPLC. The purified peptide is a large, extremely hydrophobic molecule. Its apparent molecular mass on a reducing sodium dodecyl sulfate-containing gel is 6.4 kDa, and its calculated molecular mass (based on an amino acid analysis of the purified material) is 8.2 kDa. Amino acid analysis reveals a high proportion of leucine and valine residues. The amino terminus of the molecule is not susceptible to Edman degradation, but sequencing studies were successfully carried out on tryptic fragments. Based on the estimated size of the molecule, these studies provide approximately 60% of the total sequence. No homologies with any previously sequenced peptide were observed, but biochemical similarities to as yet unsequenced peptides found in extracts of sinus glands from other crustaceans (hyperglycemic hormone and moult-inhibiting hormone) are described.

Identification of all GABA-immunoreactive neurons projecting to the lobster stomatogastric ganglion.

The stomatogastric ganglion of lobsters (Homarus or Jasus) contains a large number of gamma-aminobutyric acid-immunoreactive processes originating from ten fibres in the single input nerve, the stomatogastric nerve. The cell bodies and axonal pathways of these ten fibres have been identified using gamma-aminobutyric acid immunohistochemistry in combination with Lucifer Yellow staining (double labelling) and nickel chloride backfilling (selective gamma-aminobutyric acid immunoinhibition). It is shown that eight gamma-aminobutyric acid-immunoreactive neurons project to the stomatogastric ganglion: gamma-aminobutyric acid neurons 1 and 2, found posterior to the oesophageal ganglion, entering the stomatogastric nerve via the oesophageal nerve as well as sending an axonal branch into each superior oesophageal nerve; gamma-aminobutyric acid neurons 3 and 4, found anterior to the oesophageal ganglion, each sending an axonal branch into each inferior oesophageal nerve to reach the stomatogastric nerve via the commissural ganglion and the superior oesophageal nerve; and gamma-aminobutyric acid neurons 5 and 6, found in each commissural ganglion, projecting into the stomatogastric nerve via the inferior oesophageal nerve, the oesophageal ganglion and the oesophageal nerve. These gamma-aminobutyric acid-immunoreactive neurons were also characterized by electrophysiological methods coupled with Lucifer Yellow labelling, and their picrotoxin-sensitive effects on several stomatogastric ganglion neurons were demonstrated. The present results provide a firm basis for further studies concerning the physiological significance of one class of neurochemically-defined input neurons to stomatogastric ganglion networks.

The presence of inorganic and organic mercury and selenium in Nephrops norvegicus from the Ligurian Sea.

Samples of Nephrops norvegicus from the Ligurian Sea were analysed for contents of organic mercury, total mercury and selenium. Results for 37 specimens are reported. Total mercury concentrations increase with size of the specimens. Percentage of organic mercury ranges from 31 to 88% with an average of 58%. Selenium does not correlate with size and the average content is 0.88 micrograms g-1 fresh weight (range 0.30-1.74 micrograms g-1 fresh weight).

Composition of chlorinated dibenzodioxins and dibenzofurans in various samples.

The composition of chlorinated dibenzodioxins (CDD) and dibenzofurans (CDF) in terms of the degree of chlorination (tetra- to octachloro-) is displayed by principal components projection. Chlorinated dibenzodioxins and dibenzofurans with 4-6 chlorines are the main classes in samples of crabs and lobsters, CCD with 7 and 8 chlorines prevail in human samples. Chlorinated dibenzodioxins and dibenzofurans from incinerator ash are similar to those from human tissues. Those from gaseous incinerator emissions are enriched in less chlorinated classes and resemble residues isolated from conifer needles. Compositions of CDD and CDF in ambient air vary depending on both local and remote sources.

The lobster nerve sodium channel: solubilization and purification of the tetrodotoxin receptor protein.

Solubilization and purification of the tetrodotoxin (TTX) binding protein of the lobster walking-leg nerve Na+ channel were carried out utilizing [3H]tetrodotoxin [( 3H]tetrodotoxin) as a marker. The nerve membrane was solubilized with Lubrol-PX and the Na+ channel protein was purified with diethylaminoethyl Bio-Gel A, Bio-Gel hydroxylapatite powder and two Sepharose 6B columns. Care was taken to keep the temperature of the Na+ channel preparation as close to 1 degrees C as possible and to use solutions (pH 7.5) that contain Na channel protectors, i.e., egg phosphatidylcholine/Lubrol-PX mixture, TTX, EDTA, EGTA, phenylmethylsulfonyl fluoride, pepstatin A, iodoacetamide, antipain, phosphoramidon, soybean trypsin inhibitor, leupeptin and bacitracin. From an initial specific binding of 20.1 pmol of [3H]TTX/mg protein for the solubilized membrane, the binding increased to 1241 pmol/mg protein for the most active fraction of the last Sepharose 6B column. The [3H]TTX specific binding of the Sepharose 6B fractions correlated with a large peptide of Mr 260,000 (240-280K), although other peptides were also present in lesser amounts.

Substance P-like immunoreactivity in the stomatogastric nervous systems of the crab Cancer borealis and the lobsters Panulirus interruptus and Homarus americanus.

The distribution of substance P-like immunoreactivity in the stomatogastric nervous systems of three decapod crustacean species, Cancer borealis, Homarus americanus, and Panulirus interruptus, was studied. The stomatogastric ganglion showed dense staining in the neuropil, but none in the somata. A single neuron stained in the esophageal ganglion. Lucifer yellow backfills and intracellular injections followed by incubation with the substance P antibody showed that the axons of this neuron project into the inferior esophageal nerves towards the paired commissural ganglia. The commissural ganglia showed a pronounced projection from a large bundle of fibers in the anterior medial portion of the circumesophageal connective. Additionally, less dense neuropil and stained somata were seen in the commissural ganglia. Staining was completely blocked by preabsorption with authentic substance P, physalaemin, eledoisin, and substance K. These data suggest that in the nervous system of crustacean species a molecule with C-terminal homology to substance P and other tachykinins is released as a neuroregulator in the stomatogastric ganglion.

Histochemical and biochemical characterization of two slow fiber types in decapod crustacean muscles.

Myofibrillar proteins in muscles of the claws and abdomen of lobster, Homarus americanus, and the claws of fiddler crab, Uca pugnax, and land crab, Gecarcinus lateralis, have been analyzed with sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Fibers contained numerous isoforms of structural and regulatory proteins in assemblages correlated with fiber type. One fast (F) and two slow (S1 and S2) fibers were identified. All F fibers possessed two isoforms of paramyosin (P1 and P2), while all slow fibers, with the exception of Uca major claw, contained only the P2 variant. S1 and S2 fibers were distinguished by the distribution of a large isoform of troponin-T (T1; Mr = 55,000); S2 fibers in all three species contained T1 in addition to one or two smaller-molecular-weight variants usually associated with S1 fibers. In order to determine whether the slow fibers differed in histochemical properties, land crab claw closer muscle was cryosectioned and stained for myofibrillar ATPase and NADH diaphorase activities. Most S2 fibers had lower ATPase and higher NADH diaphorase activities than S1 fibers, which indicated that S2 fibers had a lower rate of contraction and were more fatigue-resistant than S1 fibers. It is proposed that the S1 and S2 fibers defined by biochemical and histochemical criteria are identical to the slow-twitch and tonic fibers, respectively characterized physiologically.

Chitin structure and chitinase activity: isolation of structurally intact chitins.

Assessment of chitinase kinetics and mechanism in vitro has been hampered by lack of suitable substrates. We have previously reported rapid linear initial chitinase velocity with chitin substrate isolated from insect larval cuticle. Such chitin is shown to be fibrous in the light microscope. Methods are described for preparing fibrous chitins from any animal source including calcified carapaces. Evidence is given that chitin native fine structure in situ is maintained by structural proteins which in the fibrous chitin isolates are functionally replaced by covalently bound ester groups. Chitin fiber analogues thus reconstructed appear to have retained their native fine structure.

Purification and characterization of FMRFamidelike immunoreactive substances from the lobster nervous system: isolation and sequence analysis of two closely related peptides.

In the preceding paper (Kobierski et al: J. Comp. Neurol. 266:1-15, '87) FMRFamidelike immunoreactivity (FLI) was localized to specific cells and processes in the nervous system of the lobster Homarus americanus. In an effort to establish a role for this material we have purified and characterized a variety of immunoreactive peptides that can be extracted from the secretory pericardial organs. By using gel-filtration chromatography and three different HPLC systems, it has been established that little or no authentic FMRFamide is present. Of the major immunoreactive components two peptides were purified in sufficient quantity for microsequence analysis and have been tentatively identified as the octapeptides Ser-Asp-Arg-Asn-Phe-Leu-Arg-Phe-amide (FLI 3) and Thr-Asn-Arg-Asn-Phe-Leu-Arg-Phe-amide (FLI 4). Both of these are novel neuropeptides with some sequence homology to the previously described FMRFamide family. The pericardial organs release FLI when depolarized with 100 mM K+ in the presence of calcium. Between 75 and 80% of this release is accounted for by FLI 3 and FLI 4. One of these peptides (FLI 4) has been synthesized and shown to cochromatograph with the endogenous immunoreactive material. Preliminary studies show that this peptide can act as a modulator of exoskeletal and cardiac neuromuscular junctions.

FMRFamidelike peptides of Homarus americanus: distribution, immunocytochemical mapping, and ultrastructural localization in terminal varicosities.

The distribution of FMRFamidelike peptides was studied in the nervous system of the lobster Homarus americanus by using immunocytochemical and radioimmunological techniques. By radioimmunoassay FMRFamidelike immunoreactivity (FLI) was found in low levels (ca. 1 pmol/mg protein) throughout the ventral nerve cord and in much higher amounts (60-100 pmol/mg protein) in the neurosecretory pericardial organs. Immunocytochemical studies showed FLI in approximately 300-350 cell bodies, and in distinct neuropil regions, neuronal fiber tracts, and varicose endings. Specificity of the immunostaining was tested by preabsorbing the antiserum with FMRFamide, with peptides having similar carboxyl termini to FMRFamide (Met-enkephalin-Arg-Phe, Phe-Met-Arg-Tyr-amide), with several amidated peptides (alpha-melanocyte-stimulating hormone, substance P, oxytocin), and with proctolin, a peptide found widely distributed in the lobster nervous system. Of these substances, only FMRFamide blocked the staining. In addition to the pericardial organs, significant levels of FLI were found in neurosecretory regions associated with thoracic second roots and in the connective tissue sheath that surrounds the ventral nerve cord. In all three regions, immunocytochemical studies showed the FLI to be localized to fine fibers and associated terminal varicosities lying close to the surface of the tissue, with no obvious target in their immediate vicinity. When examined at the ultrastructural level, the immunoreactive varicosities of the thoracic second roots and of the ventral nerve cord sheaths were found a few microns from the surface of the tissue and contained electron-dense granules. In the immunoreactive nerve cord sheath endings, in addition to the large, dense granules, small, clear vesicles were found. The appearance and location of these terminals suggest a neurohormonal role for FMRFamidelike peptides in lobsters. The observation that low levels of FLI are found in the hemolymph supports this suggestion. In addition, the localization of FLI to particular neuronal somata, fiber tracts, and neuropil regions suggests possible functional roles for these peptides in (1) integration of visual and olfactory information, (2) function of the anterior and posterior gut, and (3) the control of exoskeletal muscles.

Partial characterization and amino acid composition of a high molecular weight peptide with salmon calcitonin immunoreactivity in a crustacean: Nephrops norvegicus.

Anti-salmon calcitonin antibodies were used to follow the purification of a high molecular weight peptide present both in the haemolymph and in the hepatopancreas of the Norway lobster Nephrops norvegicus. An apparent molecular weight of 22 kDa has been measured in electrophoresis on SDS gels and amino acid composition compared to salmon calcitonin. The amount determined by the immunoreactivity assay corresponds to about 1/40 and 1/140 of that which is based on direct protein measurement for the hepatopancreas and the haemolymph respectively. The total amount of this peptide could be estimated as 3.5 mg/g fresh weight for the hepatopancreas and 140 ug/ml for the haemolymph. The function of this peptide is still unknown.

Immunochemical and immunocytochemical studies of the crustacean vitellogenesis-inhibiting hormone (VIH).

Immunochemical investigations, using dot immunobinding assay (DIA) and enzyme-linked immunosorbent assay (ELISA), and immunocytochemical studies reveal the following new information about crustacean vitellogenesis-inhibiting hormone (VIH): (1) The structure of VIH is sufficiently different from that of the other sinus gland neuropeptides to allow a selective recognition of VIH by polyclonal antibodies. (2) From immunochemical criteria, VIH does not seem strictly species specific. The antisera raised against VIH of Homarus americanus cross-react with sinus gland extracts of Palaemonetes varians, Palaemon serratus, Macrobrachium rosenbergii, Carcinus maenas, and Porcellio dilatatus. (3) In the sinus gland of H. americanus, VIH immunoreactivity is localized mainly in electron-dense granules of medium size (110-185 nm in diameter) while, in P. dilatatus, the labeling is mostly on the largest granules (200-270 nm in diameter).

Distribution and partial characterization of FMRFamide-like peptides in the stomatogastric nervous systems of the rock crab, Cancer borealis, and the spiny lobster, Panulirus interruptus.

The distribution of FMRFamide-like peptides was studied in the complete stomatogastric nervous system [the paired commissural ganglia, single oesophageal ganglion, and the single stomatogastric ganglion (STG)] of two decapod crustacean species, the spiny lobster Panulirus interruptus and the rock crab Cancer borealis, by using immunocytochemical techniques. Antiserum 231 from the O'Donohue laboratory and antiserum 671C (described here) gave essentially the same staining patterns. In the commissural ganglia of both species there were ten to 20 stained neurons and dense neuropilar staining. The oesophageal ganglion of the crab had four stained neurons. Lucifer Yellow backfills followed by immunostaining showed that the two larger stained neurons of the oesophageal ganglion sent processes into the inferior ventricular nerve. The two smaller neurons sent processes into the inferior oesophageal nerves. The oesophageal ganglion of the lobster had two stained neurons that sent processes into the inferior ventricular nerve as well. None of the somata of the STG stained in either species, but in both species stained fibers were seen in the stomatogastric nerve that entered the STGs and ramified profusely throughout the neuropil. In some preparations of the crab, a stained fiber was visible in the dorsal ventricular nerve. The amounts of the FMRFamide-like peptides found in all regions of the nervous system of P. interruptus and C. borealis were determined by radioimmune assay (RIA). Column chromatography and high-performance liquid chromatography suggest that, in both species, much if not all of the RIA-assayable material is accountable for by peptides that are larger and more hydrophobic than FMRFamide.

Identification and characterization of a polypeptide from a lobster neurosecretory gland that induces cyclic GMP accumulation in lobster neuromuscular preparations.

Several observations suggest that cyclic GMP might regulate some aspect of neuromuscular physiology or metabolism in the lobster. Homarus americanus: lobster muscle is one of the richest known sources of cyclic GMP-dependent protein kinase, the preparation contains several phosphoproteins whose state of phosphorylation is affected by cyclic GMP more effectively than by cyclic AMP, and guanylate cyclase and phosphodiesterase are active in this tissue. However, no factor has yet been identified that alters lobster muscle cyclic GMP levels. We have screened extracts of neural and neurosecretory structures for the capacity to promote cyclic GMP accumulation in isolated exoskeletal muscles. Extracts of the sinus gland (a neurohemal organ found in the eyestalk) contain a factor that induces up to 100-fold increases in muscle cyclic GMP content, whereas extracts of other tissues are ineffective. This factor can also act on targets other than muscle, with hepatopancreas, testis, and neuronal tissue showing the largest responses. The sinus gland factor does not appear to affect cyclic GMP metabolism by depolarizing the preparation or by mobilizing extracellular Ca2+. The effect on cyclic GMP levels is dose-dependent and linear with time. Biological activity is destroyed by boiling and by 90% ethanol. It is also destroyed by trypsin, chymotrypsin, or pronase, which suggests that the factor is a protein or peptide. Both gel filtration chromatography and experiments using dialysis tubing with different molecular weight exclusion limits indicate that the factor has an apparent molecular weight of 5,000-12,000 daltons. A preliminary fractionation scheme, based on gel filtration, ion-exchange, and reverse-phase chromatography, gives greater than 1,300-fold purification. Our long-range goal is to purify this factor to homogeneity, compare it to other peptide hormones, and use it as a probe to evaluate the role of cyclic GMP at the neuromuscular junction.

Proctolin in identified serotonergic, dopaminergic, and cholinergic neurons in the lobster, Homarus americanus.

In order to explore the functions of the peptide proctolin in the lobster nervous system, 3 classes of neurons showing proctolin-like immunocytochemical staining were selected for study. These neurons were identified on the basis of physiological and/or morphological criteria, isolated by dissections, and analyzed with biochemical methods to determine whether they contained authentic proctolin and which classical neurotransmitters coexisted with the peptide. Pairs of large proctolin-immunoreactive neurons in fifth thoracic and first abdominal ganglia were identified as serotonin-immunoreactive neurons (Beltz and Kravitz, 1983, 1987) by staining serial sections of the ganglia alternately with the 2 antisera. Physiologically identified cells, dissected from the ganglia and analyzed with high-performance liquid chromatography (HPLC), contained approximately 20 microM proctolin and 0.5 mM serotonin. A large proctolin-immunoreactive neuron in the circumesophageal ganglion was identified as the lobster homolog of a dopaminergic neurosecretory cell found in other crustaceans (Cooke and Goldstone, 1970). The large lobster cell stained with antityrosine hydroxylase antiserum, and synthesized 3H-dopamine from 3H-tyrosine. Dissected cell bodies, analyzed by HPLC, contained approximately 25 microM proctolin. Proctolin-immunoreactive sensory neurons were identified as large stained fibers that terminated in sensory dendrites of the oval organ mechanoreceptor in the scaphognathite (Pasztor, 1979; Pasztor and Bush, 1982). The largest sensory fiber was isolated for biochemical studies. It synthesized 3H-acetylcholine from 3H-choline and, by HPLC analysis, was found to contain approximately 3 microM proctolin. Thus, proctolin coexists with different conventional transmitters in several classes of identified lobster neurons. Investigations of the actions of proctolin in these different contexts should contribute to a more complete understanding of the diverse functions of neuropeptides and their roles as cotransmitters.