PROTEIN PATTERNS IN DIFFERENT LOBES AND DURING DEVELOPMENT OF OCTOPUS BRAIN

Abstract— Utilizing techniques of continuous and SDS-electrophoresis we have examined the saline-soluble and SDS-soluble (membrane-bound) proteins extracted from the main lobes of adult octopus brain and from the developing optic lobe of the same species. Several additional protein bands are present among the soluble and the membrane-bound proteins of the vertical lobe in comparison with the suboesophageal lobe. Since the former contains an essentially homogeneous population of small neurons, while the suboesophageal lobe is rich in large nerve cells, these protein bands have been attributed to the small neuronal type present in the vertical lobe.
In the course of a 10,000-fold increment in body weight, from 0.4 g to 4 kg, there is a significant increase in the concentration of several soluble proteins extracted from the optic lobe. Three of these proteins increase to a marked degree. Among the membrane-bound proteins some show a moderate increase with age while other protein components of smaller molecular weight undergo a moderate decrease. The overall tissue concentration of the membrane-bound proteins increases between 0.4 g and 50 g body weight, slightly declining in animals of larger size.     

A BRAIN-SPECIFIC PROTEIN WITH AFFINITY FOR DNA1

Abstract— A procedure has been developed which allows the isolation from rat brain cytosol of a soluble acidic protein, designated DNA-110 protein, having two basic properties: selective affinity for single-stranded DNA and immunological specificity to the nervous system. Only two major purification steps, DNA-cellulose chromatography and affinity chromatography on immunoadsorbents are needed to give apparently pure protein. The purification steps of the DNA-110 protein have been followed by immunological assay. DNA-110 has a molecular weight of 68,000 and an isoelectric point of 5.9. It accounts for 1.95% of the total soluble protein and its concentration is 216 μg per g wet weight of rat brain. DNA-110 is immunologically unrelated to other soluble acidic brain-specific proteins and glycoproteins.     

IDENTIFICATION OF A GROUP OF OCTOPUS BRAIN PROTEINS AS HISTONES

Abstract— We have investigated the subcellular localization of a group of proteins solubilized with SDS from saline-washed particulates of octopus brain and identified as the most rapidly moving species in SDS-gel electrophoresis. These proteins are several-fold more concentrated in the vertical and optic lobes than in the suboesophageal lobe. In the optic lobe their concentration decreases with increasing body weight (G iuditta et al , 1975).
Upon separation of hypertonic sucrose homogenates from the optic lobe in a nuclear pellet and in a floating layer containing cytoplasmic particulates, the proteins appear associated with the nuclear fraction. Differential extraction of the latter fraction shows that the proteins have the same solubility and electrophoretic mobilities as histones. Proteins with similar properties are present in other brain regions and in non-nervous organs.     

Isolation of PGP 9.5, a New Human Neurone-Specific Protein Detected by High-Resolution Two-Dimensional Electrophoresis

Protein gene product (PGP) 9.5 is a new brain-specific protein originally detected by high-resolution two-dimensional electrophoresis of the soluble proteins of human brain and other organs. We have purified this protein from human brain and raised a rabbit antihuman PGP 9.5 antiserum. The protein has a monomer molecular weight of approximately 27,000 and is present in brain at concentrations at least 50 times greater than in other organs. Immunoperoxidase labelling has localised PGP 9.5 to neurones in the human cerebral cortex with no evidence of staining of glial elements. PGP 9.5 is estimated to be present in brain at concentrations of 200-500 micrograms/g wet weight and represents a major protein component of neuronal cytoplasm. This new neurone-specific cytoplasmic marker may prove useful in studies of neuronal development and in the detection of neuronal damage in disease of the nervous system.     

Axoplasmic transport of a brain-specific soluble protein

The rate and extent of axoplasmic transport of the brain-specific soluble protein (14-3-2 protein) has been investigated in the avian visual system. 1-day-old chicks were injected monocularly with tritiated proline. Incorporation of the isotope into the 14-3-2 protein synthetized within the retina of the injected eye, as well as the appearance of the labeled protein in the optic lobes was determined at 6 h and 6 days. These time periods were chosen to distinguish between the rapid and slow phases of axoplasmic flow. Following preparation of high-speed supernatant fractions, dialysis, chromatography on Sephadex G-150 and immunoprecipitation with specific antiserum, identification of the labeled 14-3-2 protein was carried out by sodium dodecylsulfate-polyacrylamide gel analysis of the radioactive immunoprecipitates. 6 days after isotope administration, approx. 8% of the 14-3-2 protein synthesized in the chick retina had been transported to the contralateral optic lobe. By contrast, at 6 h no labeled 14-3-2 protein was detectable. Thus, transport of this neuronal protein appears to be a relatively slow process with little or no rapid component.     

Axoplasmic transport of a brain-specific soluble protein.

The rate and extent of axoplasmic transport of the brain-specific soluble protein (14-3-2 protein) has been investigated in the avian visual system. 1-day-old chicks were injected monocularly with tritiated proline, Incorporation of the isotope into the 14-3-2 protein synthesized within the retina of the injected eye, as well as the appearance of the labeled protein in the optic lobes was determined at 6 h and 6 days. These time periods were chosen to distinguish between the rapid and slow phases of axophlasmic flowmfollowing preparation of high-speed supernatant fractions, dialysis, chromatography on Sephadex G-150 and immunoprecipitation with specific antiserum, identification of the labeled 14-3-2 protein was carried out by sodium dodecylsulfate-polyacrylamide gel analysis of the radioactive immunoprecipitates; 6 days after isotope administration, approxo% of the 14-3-2 protein synthesized in the chick retina had been transported to the contralateral optic lobe. By contrast, at 6 h no labeled 14-3-2 protein was detectablemthus, transport of this neuronal protein appears to be relatively slow process with little or no rapid component.     

Nonsomatotopic Organization of the Higher Motor Centers in Octopus

Hyperredundant limbs with a virtually unlimited number of degrees of freedom (DOFs) pose a challenge for both biological and computational systems of motor control. In the flexible arms of the octopus, simplification strategies have evolved to reduce the number of controlled DOFs [1], [2] and [3]. Motor control in the octopus nervous system is hierarchically organized [4] and [5]. A relatively small central brain integrates a huge amount of visual and tactile information from the large optic lobes and the peripheral nervous system of the arms [6], [7], [8] and [9] and issues commands to lower motor centers controlling the elaborated neuromuscular system of the arms. This unique organization raises new questions on the organization of the octopus brain and whether and how it represents the rich movement repertoire. We developed a method of brain microstimulation in freely behaving animals and stimulated the higher motor centers—the basal lobes—thus inducing discrete and complex sets of movements. As stimulation strength increased, complex movements were recruited from basic components shared by different types of movement. We found no stimulation site where movements of a single arm or body part could be elicited. Discrete and complex components have no central topographical organization but are distributed over wide regions.     

The isolation of three neurophysins from porcine posterior pituitary lobes

1. Three neurophysins, proteins that bind the polypeptide hormones oxytocin and vasopressin, have been isolated from acetone-dried porcine posterior pituitary lobes. The proteins have been named porcine neurophysins-I, -II and -III in order of their electrophoretic mobilities at pH8.1. 2. Electrophoretic comparison of the purified proteins, which are homogeneous on starch-gel electrophoresis, with the soluble proteins of fresh porcine posterior pituitary lobes extracted in 0.1m-HCl and in buffer pH8.1 suggests that the isolated proteins are native to the fresh tissue. 3. Neurophysins-I and -II are present in similar amounts in the tissue, whereas neurophysin-III is present only in small quantities. Acetone-dried tissue also contains traces of other hormone-binding neurophysin components. 4. All the neurophysins can bind both oxytocin and [8-lysine]-vasopressin. 5. The apparent molecular weights of the neurophysins increase with increasing protein concentration as measured by equilibrium sedimentation in the ultracentrifuge. 6. Neurophysins-I and -III are of similar molecular dimensions, contain one residue of methionine per molecule and lack histidine. The minimum molecular weight of neurophysin-I obtained by amino acid analysis is 9360. Neurophysin-II is of larger molecular dimensions than neurophysins-I and -III and can be separated from these by gel filtration on Sephadex G-75. It contains no histidine or methionine, and its minimum molecular weight has been estimated as 14020 by amino acid analysis. 7. Each of the three neurophysins possesses N-terminal alanine. 8. The possible biological significance of the existence of several neurophysins within one species is discussed.     

IDENTIFICATION OF A CALCIUM-BINDING, BRAIN SPECIFIC PROTEIN IN THE AXOPLASM OF SQUID GIANT AXONS

Abstract— An acidic protein has been isolated from the optic lobes of two cephalopods, Sepia officinalis and Loligo vulgaris. The protein has been obtained in pure form by fractionation with ammonium sulphate and chromatography on DEAE-cellulose and Sephadex G 100. Its apparent molecular weight is 13,000–15,000. Glutamic and aspartic acids account for 35 per cent of the amino acid residues. The protein binds Ca²⁺ ions with an apparent dissociation constant of 2·5 × 10⁻⁵ M at physiological concentrations of KCI. Antibodies have been prepared against the protein purified from Sepia officinalis. By the micro-complement fixation technique it has been shown that the protein is highly concentrated in the nervous system of cephalopods and that the amount in the axoplasm of squid giant axons is eight to nine-fold higher than in the optic lobes of the same animal.     

Analysis of differential gene expression in the central nervous system of Schistocerca gregaria by differential display PCR

Within the optic lobes, the mushroom bodies or other parts of the insect brain, information is processed in an area-specific manner. To study the molecular basis of the abilities of the respective areas, the central nervous system of the desert locust Schistocerca gregaria was dissected into different parts, the optic lobes, the “midbrain”, and the thoracic ganglia. Using a simple electrophoretic approach we were able to show area-specific expression of proteins exclusively present in the optic lobes. To study brain area-specific gene expression in more detail, we adapted the differential display polymerase chain reaction to the specific needs of this project. A number of differentially expressed amplicons were identified. The majority of them could be reamplified and their differential expression verified by northern blot analysis. To demonstrate the efficiency of the approach two amplicons with complementary expression patterns were further analysed. Accepted: 31 August 1997     

GLUCOSE AND AMINO ACID METABOLISM IN OCTOPUS OPTIC AND VERTICAL LOBES IN VITRO

(1) The metabolism of glucose and amino acids in vitro was compared in the rat cerebral cortex and the optic and vertical lobes of the octopus brain. (2) Specific activities and pool sizes of the five amino acids, glutamate, aspartate, glutamine, alanine and γ-aminobutyric acid (GABA), were determined in octopus and rat brain slices after 2 hr incubation with 10 mm -[U-¹⁴C]glucose, 10 mm -L-[U-¹⁴C]glutamate, and 10mm -^L-[U-¹⁴C]glutamate with added 10 mM-glucose. Amino acid pool sizes were similar in rat and octopus brain, with the exception of alanine, which was higher in the octopus. Generally specific activities were from four- to 20-fold higher in rat brain. With [U-¹⁴C]glucose as substrate, specific activities of GABA and glutamate were highest in rat; those of alanine and glutamine highest in octopus brain. With ^L-[U-¹⁴C]glutamate the specific activities of GABA and aspartate were highest in rat, that of aspartate highest and GABA lowest in octopus. The addition of glucose to ^L-[U-¹⁴C]glutamate as substrate had little effect on the specific activities of any of the amino acids. (3) The uptake of some amino acids was determined by incubation with [U-¹⁴C]amino acids for 2 hr, and ¹⁴CO₂ formation was also measured. The amount of label taken up by octopus was uniformly 20-25 per cent of that found for rat brain. The amount of ¹⁴CO₂, however, differed according to the amino acid. Four times as much ¹⁴CO₂ was generated from alanine by octopus optic lobe and twice as much by the vertical lobe than rat cortex, but from glutamate, only 24 per cent in the optic and 15 per cent in the vertical lobe. No ¹⁴CO₂ was generated from [U-¹⁴C]GABA in the octopus, by contrast with the rat. (4) Activity of some of the enzymes involved in amino acid metabolism was determined in homogenates of rat cortex and octopus optic and vertical lobes, with and without activation by Triton X-100. Enzymic activities in the octopus, with the exception of alanine aminotransferase, were lower than in the rat, and glutamate decarboxylase could not be detected in octopus brain, in the absence of detergent.     

Control of GnRH expression in the olfactory lobe of Octopus vulgaris

In the cephalopod mollusk Octopus vulgaris, the gonadotropic hormone released by the optic gland controls sexual maturity. Several lobes of the central nervous system control the activity of this gland. In one of these lobes, the olfactory lobe, a gonadotropin releasing hormone (GnRH) neuronal system has been described. We assume that several inputs converge on the olfactory lobes in order to activate GnRH neurons and that a glutamatergic system mediates the integration of stimuli on these neuropeptidergic neurons. The presence of N-methyl-d-aspartate (NMDA) receptor immunoreactivity in the neuropil of olfactory lobes and in the fibers of the optic gland nerve, along with the GnRH nerve endings strongly supports this hypothesis. A distinctive role in the control of GnRH secretion has also been attributed, in vertebrates, to nitric oxide (NO). The lobes and nerves involved in the nervous control of reproduction in Octopus contain nitric oxide synthase (NOS). Using a set of experiments aimed at manipulate a putative l-glutamate/NMDA/NO signal transduction pathway, we have demonstrated, by quantitative real-time PCR, that NMDA enhances the expression of GnRH mRNA in a dose-response manner. The reverting effect of a selective antagonist of NMDA receptors (NMDARs), 2-amino-5-phosphopentanoic acid (D-APV), confirms that such an enhancing action is a NMDA receptor-mediated response. Nitric oxide and calcium also play a positive role on GnRH mRNA expression. The results suggest that in Octopusl-glutamate could be a key molecule in the nervous control of sexual maturation.     

Morphological changes of the optic lobe from late embryonic to adult stages in oval squids Sepioteuthis lessoniana

The optic lobe is the largest brain area within the central nervous system of cephalopods and it plays important roles in the processing of visual information, the regulation of body patterning, and locomotive behavior. The oval squid Sepioteuthis lessoniana has relatively large optic lobes that are responsible for visual communication via dynamic body patterning. It has been observed that the visual behaviors of oval squids change as the animals mature, yet little is known about how the structure of the optic lobes changes during development. The aim of the present study was to characterize the ontogenetic changes in neural organization of the optic lobes of S. lessoniana from late embryonic stage to adulthood. Magnetic resonance imaging and micro‐CT scans were acquired to reconstruct the 3D‐structure of the optic lobes and examine the external morphology at different developmental stages. In addition, optic lobe slices with nuclear staining were used to reveal changes in the internal morphology throughout development. As oval squids mature, the proportion of the brain making up the optic lobes increases continuously, and the optic lobes appear to have a prominent dent on the ventrolateral side. Inside the optic lobe, the cortex and the medulla expand steadily from the late embryonic stage to adulthood, but the cell islands in the tangential zone of the optic lobe decrease continuously in parallel. Interestingly, the size of the nuclei of cells within the medulla of the optic lobe increases throughout development. These findings suggest that the optic lobe undergoes continuous external morphological change and internal neural reorganization throughout the oval squid's development. These morphological changes in the optic lobe are likely to be responsible for changes in the visuomotor behavior of oval squids from hatching to adulthood.     

WALLERIAN DEGENERATION IN RABBIT OPTIC NERVE: CELLULAR LOCALIZATION IN THE CENTRAL NERVOUS SYSTEM OF THE S-100 AND 14-3-2 PROTEINS1

Abstract— The S-100 and 14-3-2 proteins, which are found only in nervous tissues, were measured in degenerating rabbit optic nerve at 0, 5 10, 20, 40, 60, 80, 100, 150 and 200 days after unilateral enucleation in order to obtain indications of the cellular localization of these proteins in the central nervous system. S-100 increased and 14-3-2 decreased (both approximately 70 per cent) in cut nerves by 200 days of degeneration. Changes in amounts of the proteins were related to cellular alterations which characterize the degenerative process, as demonstrated by electron microscopy. In uncut nerves (intact eye) from these experimental animals, S-100 increased and 14-3-2 decreased slightly at 5 days, after which time the levels of each returned to those approximating the content in corresponding nerves from unoperated control animals. No appreciable change in total soluble proteins was measured in degenerating or intact nerves. Since S-100 increased and 14-3-2 decreased in the degenerating optic nerve as it became relatively enriched in glial constituents but impoverished in axonal content, it is suggested that S-100 is primarily a glial protein and 14-3-2 predominantly a neuronal protein in the central nervous system.     

Immunolocalization of choline acetyltransferase of common type in the central brain mass of Octopus vulgaris

Acetylcholine, the first neurotransmitter to be identified in the vertebrate frog, is widely distributed among the animal kingdom. The presence of a large amount of acetylcholine in the nervous system of cephalopods is well known from several biochemical and physiological studies. However, little is known about the precise distribution of cholinergic structures due to a lack of a suitable histochemical technique for detecting acetylcholine. The most reliable method to visualize the cholinergic neurons is the immunohistochemical localization of the enzyme choline acetyltransferase, the synthetic enzyme of acetylcholine. Following our previous study on the distribution patterns of cholinergic neurons in the Octopus vulgaris visual system, using a novel antibody that recognizes choline acetyltransferase of the common type (cChAT), now we extend our investigation on the octopus central brain mass. When applied on sections of octopus central ganglia, immunoreactivity for cChAT was detected in cell bodies of all central brain mass lobes with the notable exception of the subfrontal and subvertical lobes. Positive varicosed nerves fibers where observed in the neuropil of all central brain mass lobes.Key words: invertebrate, cephalopod, choline acetyltransferase, neuron, immunohistochemistry.     

L(1)trol and L(1)devl, Loci Affecting the Development of the Adult Central Nervous System in Drosophila Melanogaster

Adult optic lobes of Drosophila melanogaster are composed of neurons specific to the adult which develop postembryonically. The structure of the optic lobes and aspects of its development have been described, and a number of mutants that affect its development have been identified. The focus of every screen to date has been on disruption of adult structure or function. Although these loci were originally identified on the basis of viable mutants, some have proven capable of giving rise to lethal alleles. It seems reasonable to assume that mutants which strongly affect development of the imaginal-specific central nervous system may evidence abnormalities during the late larval or pupal stages when the adult central nervous system is undergoing final assembly and might show a lethal phase prior to eclosion (as is true for mutations at the previously defined l(1)ogre locus). We have carried out the first screen of autosomal and sex-linked late larval and pupal lethals to identify mutations that affect the development of the optic lobes. Our screen yielded nine mutants that could tentatively be grouped into three classes, depending on the neuroblast population affected and imaginal disc phenotypes. Two of these, including one that is allelic to l(1)zw1, were chosen for further analysis.     

SITE OF BIOSYNTHESIS OF BRAIN-SPECIFIC PROTEINS IN THE GIANT FIBRE SYSTEM OF THE SQUID

The synthesis of brain-specific proteins has been examined in perikaryal and axonal regions of the giant fibre system of the squid. After in vitro incubation of stellate ganglia, stellate nerves and isolated giant axons with radioactive amino acids, the labelled soluble proteins have been extracted from the giant fibre lobe, the axoplasm and the axonal sheath of the giant axon and have been separated by gel electrophoresis on a continuous system. In addition, they have been challenged with antisera prepared against the cephalopod brain-specific proteins L1 and L2 and the resulting precipitate has been resolved by sodium dodecyl sulphate-gel electrophoresis. Synthesis of these two proteins appears to be restricted to the giant fibre lobe, while an additional discrete protein band (L5) also becomes clearly labelled in the isolated giant axon. Radioactive components migrating in the region of the L1 and L2 proteins are synthesized in the isolated giant axon. They can be distinguished from tbese proteins on the basis of electrophoretic and immunochemical criteria.     

Nitric oxide synthase-dependent NADPH-diaphorase activity in the optic lobes of male and female Ceratitis capitata mutants

Nitric oxide (NO) is acknowledged as a messenger molecule in the nervous system with a pivotal role in the modulation of the chemosensory information. It has been shown to be present in the optic lobes of several insect species. In the present study, we used males and females from four different strains of the medfly Ceratitis capitata (Diptera, Tephritidae): or; or,wp (both orange eyed); w,M360 and w,Heraklion (both white eyed), as models to further clarify the involvement of NO in the mutants' visual system and differences in its activity and localization in the sexes. Comparison of the localization pattern of NO synthase (NOS), through NADPH-diaphorase (NADPHd) staining, in the optic lobes of the four strains, revealed a stronger reaction intensity in the retina and in the neuropile region lamina than in medulla and lobula. Interestingly, the intensity of NADPHd staining differs, at least in some strains, in the optic lobes of the two sexes; all the areas are generally strongly labelled in the males of the or and w,M360 strains, whereas the w,Heraklion and or,wp mutants do not show evident sex-dependent NADPHd staining. Taken as a whole, our data point to NO as a likely transmitter candidate in the visual information processes in insects, with a possible correlation among NOS distribution, eye pigmentation and visual function in C. capitata males. Moreover, NO could influence behavioural differences linked to vision in the two sexes.     

Modulation of brain protein phosphorylation by the S-100 protein

The effects of the nervous system specific protein, S-100, on protein phosphorylation in rat brain is examined. The S-100 protein inhibits the phosphorylation of several soluble brain proteins in a calcium dependent fashion. The most potent effect exhibited by S-100 was on the phosphorylation of a protein having a molecular weight of 73,000. The data suggest that the calcium binding S-100 protein, for which a function has not yet been assigned, may modulate calcium dependent phosphorylation of selected brain proteins.     

Identification and characterisation of soluble epoxide hydrolase in mouse brain by a robust protein biochemical method

Summary. The central nervous system is an important potential target for certain environmental prototoxins, but relatively little is known regarding brain-specific expression of biotransformation enzyme systems. On the other hand, developments in the field of molecular biology and advances in high-throughput screening methods continue to increase the number and amounts of available proteins. We used thus a robust and reliable technique, two-dimensional gel electrophoresis coupled to matrix assisted laser desorption/ionisation mass spectroscopy followed by tandem mass spectrometry and identified for the first time soluble epoxide hydrolase and added other biotransformation enzymes in the hippocampal region of mouse brain. Soluble epoxide hydrolase has an Mr of 61.5kDa, pI of 5.9, twenty-six matching peptides and sequence coverage of 56% and was unambiguously identified by MS/MS. Since localised biotransformation events in regions of the central nervous system may account for pathologies and/or toxicities initiated by exposure to certain endogenous and/or environmental chemicals, identification of these enzymes would present an opportunity for developing novel therapeutic targets or would have critical toxicologic significance.