Cephalopod chromatophores: neurobiology and natural history

The chromatophores of cephalopods differ fundamentally from those of other animals: they are neuromuscular organs rather than cells and are not controlled hormonally. They constitute a unique motor system that operates upon the environment without applying any force to it. Each chromatophore organ comprises an elastic sacculus containing pigment, to which is attached a set of obliquely striated radial muscles, each with its nerves and glia. When excited the muscles contract, expanding the chromatophore; when they relax, energy stored in the elastic sacculus retracts it. The physiology and pharmacology of the chromatophore nerves and muscles of loliginid squids are discussed in detail. Attention is drawn to the multiple innervation of dorsal mantle chromatophores, of crucial importance in pattern generation. The size and density of the chromatophores varies according to habit and lifestyle. Differently coloured chromatophores are distributed precisely with respect to each other, and to reflecting structures beneath them. Some of the rules for establishing this exact arrangement have been elucidated by ontogenetic studies. The chromatophores are not innervated uniformly: specific nerve fibres innervate groups of chromatophores within the fixed, morphological array, producing 'physiological units' expressed as visible 'chromatomotor fields'. The chromatophores are controlled by a set of lobes in the brain organized hierarchically. At the highest level, the optic lobes, acting largely on visual information, select specific motor programmes (i.e. body patterns); at the lowest level, motoneurons in the chromatophore lobes execute the programmes, their activity or inactivity producing the patterning seen in the skin. In Octopus vulgaris there are over half a million neurons in the chromatophore lobes, and receptors for all the classical neurotransmitters are present, different transmitters being used to activate (or inhibit) the different colour classes of chromatophore motoneurons. A detailed understanding of the way in which the brain controls body patterning still eludes us: the entire system apparently operates without feedback, visual or proprioceptive. The gross appearance of a cephalopod is termed its body pattern. This comprises a number of components, made up of several units, which in turn contains many elements: the chromatophores themselves and also reflecting cells and skin muscles. Neural control of the chromatophores enables a cephalopod to change its appearance almost instantaneously, a key feature in some escape behaviours and during agonistic signalling. Equally important, it also enables them to generate the discrete patterns so essential for camouflage or for signalling. The primary function of the chromatophores is camouflage. They are used to match the brightness of the background and to produce components that help the animal achieve general resemblance to the substrate or break up the body's outline. Because the chromatophores are neurally controlled an individual can, at any moment, select and exhibit one particular body pattern out of many. Such rapid neural polymorphism ('polyphenism') may hinder search-image formation by predators. Another function of the chromatophores is communication. Intraspecific signalling is well documented in several inshore species, and interspecific signalling, using ancient, highly conserved patterns, is also widespread. Neurally controlled chromatophores lend themselves supremely well to communication, allowing rapid, finely graded and bilateral signalling.     

Robo3 isoforms have distinct roles during zebrafish development

Roundabout (Robo) receptors and their secreted ligand Slits have been shown to function in a number of developmental events both inside and outside of the nervous system. We previously cloned zebrafish robo orthologs to gain a better understanding of Robo function in vertebrates. Further characterization of one of these orthologs, robo3, has unveiled the presence of two distinct isoforms, robo3 variant 1 (robo3var1) and robo3 variant 2 (robo3var2). These two isoforms differ only in their 5'-ends with robo3var1, but not robo3var2, containing a canonical signal sequence. Despite this difference, both forms accumulate on the cell surface. Both isoforms are contributed maternally and exhibit unique and dynamic gene expression patterns during development. Functional analysis of robo3 isoforms using an antisense gene knockdown strategy suggests that Robo3var1 functions in motor axon pathfinding, whereas Robo3var2 appears to function in dorsoventral cell fate specification. This study reveals a novel function for Robo receptors in specifying ventral cell fates during vertebrate development.     

Induction of a noggin-like gene by ectopic DV interaction during planarian regeneration

In previous studies, we have shown that dorsoventral (DV) interaction evokes not only blastema formation, but also morphogenetic events similar to those that occur in regeneration. However, it is still unclear what kinds of signal molecules are involved in the DV interaction. To investigate the signal systems involved in the DV interaction, we focused on a noggin-like gene (Djnlg) identified by the planarian EST project. Djnlg is the first noggin homologue isolated from an invertebrate. In DjNLG, the positions of nine cysteine residues which may be essential for dimer formation were well conserved, but overall, the amino acid sequence of DjNLG did not show high similarity to the sequences of vertebrate Noggins. Expression of Djnlg was observed only in the proximal region of the branch structures in the brain of intact planarians, suggesting that Djnlg may have a role in pattern formation in the brain. Interestingly, transient strong expression of Djnlg was observed in the amputated region of regenerating planarians. Djnlg-expressing cells were detected beneath the muscle 9 h after amputation and were then detected in the ventral subepidermal region of the blastema. The induction of Djnlg expression by amputation was not affected by X-ray irradiation, even though the stem cells were completely eliminated, implying the existence of signal-producing cells which may provide a positional cue to the stem cells. In DV reversed grafting, expression of Djnlg was strongly induced in the DV boundary between the host and donor. These results suggest that ectopic DV interaction may induce expression of Djnlg in the positional cue-producing cells, and that it might be involved in stimulation of blastema formation as well as DV patterning of the body.     

Functional characterization and genetic mapping of alk8

The novel type I TGFβ family member receptor alk8 is expressed both maternally and zygotically. Functional characterization of alk8 was performed using microinjection studies of constitutively active (CA), kinase modified/dominant negative (DN), and truncated alk8 mRNAs. CA Alk8 expression produces ventralized embryos while DN Alk8 expression results in dorsalized phenotypes. Truncated alk8 expressing embryos display a subtle dorsalized phenotype closely resembling that of the identified zebrafish dorsalized mutant, lost-a-fin (laf). Single-strand conformation polymorphism (SSCP) analysis was used to map alk8 to zebrafish LG02 in a region demonstrating significant conserved synteny to Hsa2, and which contains the human alk2 gene, ACVRI. Altogether, these functional, gene mapping and phylogenetic analyses suggest that alk8 may be the zebrafish orthologue to human ACVRI (alk2), and therefore extend previous studies of Alk2 conducted in Xenopus.     

Transactivation of BARNASE under the AtLTP1 promoter affects the basal pole of the embryo and shoot development of the adult plant in Arabidopsis

Genetically controlled expression of a toxin provides a tool to remove a specific structure and consequently study its role during a developmental process. The availability of many tissue-specific promoters is a good argument for the development of such a strategy in plants. We have developed a conditional system for targeted toxin expression and demonstrated its use for generating embryo phenotypes that can bring valuable information about signalling during embryogenesis. The BARNASE gene was expressed in the Arabidopsis embryo under the control of two promoters, one from the cyclin AtCYCB1 gene and one from the AtLTP1 gene (Lipid Transfer Protein 1). One-hundred percent seed abortion was obtained with the cyclin promoter. Surprisingly however, the embryos displayed a range of lethal phenotypes instead of a single arrested stage as expected from this promoter. We also show that BARNASE expression under the control of the AtLTP1 promoter affects the basal pole of the globular embryo. Together with reporter expression studies, this result suggests a role of the epidermis in controlling the development of the lower tier of the embryo. This defect was not embryo-lethal and we show that the seedlings displayed a severe shoot phenotype correlated to epidermal defects. Therefore, the epidermis does not play an active role during organogenesis in seedlings but is important for the postgermination development of a viable plant.     

MpFEW RHIZOIDS1 miRNA-Mediated Lateral Inhibition Controls Rhizoid Cell Patterning in Marchantia polymorpha

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Polymer peel‐off mask for high‐resolution surface derivatization,neuron placement and guidance

We present a dry lift‐off method using a chemically resistant spin‐on plastic, polyimide, to pattern surfaces with high accuracy and resolution. Using well‐known lithographic and reactive ion etching techniques, the spin‐on polymer is patterned over a silicon dioxide surface. The plastic efficiently adheres to the silicon dioxide surface during the chemical modification and is readily lifted‐off following the derivatization process, permitting highly reliable surface derivatization. The verticality of the reactive ion etch enables sub‐micrometer features to be patterned, down to 0.8 µm. The technique is used to pattern neurons on silicon dioxide surfaces: efficient neuron placement over a 4 mm area is shown for patterns larger than 50 µm while process guidance is shown for 10 µm patterns. Biotechnol. Bioeng. 2013; 110: 2236–2241. © 2013 Wiley Periodicals, Inc.