Test cell migration and tunic formation during posthatching development of the larva of the ascidian, Ciona intestinalis

Morphological changes in the tunic layers and migration of the test cells during swimming period in the larva of the ascidian, Ciona intestinalis , were observed by light and electron microscopy. The swimming period was divided into three stages. In stage 1, further formation of juvenile tunic layer started only in the larval trunk and neck region. In stage 2, the layer became swollen in the ventral and dorsal sides of the neck region and in stage 3, the swelling expanded backward. Concomitantly with these changes, the outermost larval tunic layer (outer cuticular layer), which had been formed before hatching, also swelled in the neck region in stage 2 and formed two humps in stage 3, although the layer did not change in the tail region during the swimming period. Test cells that were present over the entire larval tunic layer in stage 1 began to move from the surface of the fin toward that of the side of the body in stage 2, and finally gathered to form six bands running radially from the anterior end to the posterior end of the trunk region and aligned along the lateral sides of body in the tail region in stage 3. In electron microscopic observations, pseudopodia protruding from the test cells invaded the larval tunic, following which they extended proximate to the juvenile tunic in the trunk region. In the tail region, which had no juvenile tunic layer as that described, the pseudopodia invaded and remained adjacent to the surface of the epidermis or the sensory cilia protruded from the epidermis. Metamorphosis of the larvae, further tunic formation, degradation of adhesive papilla, attachment of larva to the substratum and tail resorption commenced after these morphological changes occurred. The possible role of the test cells in metamorphosis is discussed.     

Gelsolin in Cerebrospinal Fluid as a Potential Biomarker of Epilepsy

Gelsolin is an actin regulatory protein that generally distributed in a wide variety of body tissues, especially the brain tissues and cerebrospinal fluid. In this study we found that lumbar CSF-gelsolin concentrations markedly decreased in epileptic patients by enzyme linked immunosorbent assay. In order to help judge the result, we determined gelsolin expression in temporal lobe tissues of patients with temporal lobe epilepsy using double-label immunofluorescence to location and using western blot to quantitation. Then we observed that gelsolin was co-expressed with microtubule-associated protein-2 in axons and cytoplasms of neurons and gelsolin protein level was also down-regulated in temporal lobe tissues of epileptic patients. Our findings suggested that CSF-gelsolin level might reflect the alteration of gelsolin in brain tissue of epileptic patients and CSF-gelsolin seems to be a potential biomarker for epilepsy.     

ENZYMATIC ACTIVITIES RELATING TO THE RESPIRATION AND THE ONSET OF METAMORPHOSIS OF THE ASCIDIAN TADPOLE

The oxygen consumption of a single ascidian larva was measured. After hatching the consumption increases gradually. During the period of tail resorption it also increases gradually, but after the completion of tail resorption the consumption decreases conspicuously.
With the development of the larva after hatching, the activities of cytochrome oxidase and succinic dehydrogenase and of Janus green-reduction become detectable in the adhesive papillae, the proximal region of the tail, and the tail muscle. After the completion of tail resorption, these activities become indistinct.
These tissues underwent most profound morphological changes at the onset of metamorphosis. Soon after hatching, Janus green has no effect to induce metamorphosis. In larvae 4 hr after hatching, the shrinkage of adhesive papillae can be induced by Janus green-treatment. In 12 hr larvae, both the shrinkage of adhesive papillae and the tail resorption can be induced by Janus green. The enhancement of respiratory activities in the larvae after hatching may be related to the changes in the adhesive papillae and later to changes in the proximal region of the tail. Only when both of these changes occur can metamorphosis be induced.     

Gelsolin expression in sheep milk somatic cells during lactation

The identification of genes involved in phenotypes related to milk quality is important for both economic and health aspects in livestock production. The aim of this study was to assess the level of gelsolin gene expression in two breeds of dairy sheep – Sarda and Gentile – with pronounced differences in quantitative and qualitative milk traits. Gelsolin, a type of actin-modulating proteins is involved in the processes of actin remodeling during cell growth and apoptosis; therefore a role of this protein in mammary changes during lactation was here hypothesized. Individual milk samples were collected three times during lactation from 26 ewes of the two breeds. The differential gene expression of gelsolin in the two breeds and the three lactation times was estimated by quantitative PCR on RNA extracted from milk somatic cells. Correlations of gelsolin gene expression with milk yield and quality and days of lactation were also estimated. The results showed that gelsolin gene expression was significantly higher in the Sarda compared to the Gentile at each lactation stage, in agreement with the longer lactation duration and the higher daily milk yield of the first breed. Significant correlations of gelsolin gene expression were found with milk fat content in Sarda breed (−0.46, P<0.05). Gelsolin expression analysis confirmed the link between gelsolin gene function and milk fat content of sheep.     

Gelsolin affects the migratory ability of human colon adenocarcinoma and melanoma cells

AimsFormation of different protrusive structures by migrating cells is driven by actin polymerization at the plasma membrane region. Gelsolin is an actin binding protein controlling the length of actin filaments by its severing and capping activity. The main goal of this study was to determine the effect of gelsolin expression on the migration of human colon adenocarcinoma LS180 and melanoma A375 cells.Main methodsColon adenocarcinoma cell line LS180 was stably transfected with plasmid containing human cytoplasmic gelsolin cDNA tagged to enhanced green fluorescence protein (EGFP). Melanoma A375 cells were transfected with siRNAs directed against gelsolin. Real-time PCR and Western blotting were used to determine the level of gelsolin. The ability of actin to inhibit DNase I activity was used to quantify monomeric and total actin level and calculate the state of actin polymerization. Fluorescence confocal microscopy was applied to observe gelsolin and vinculin distribution along with actin cytoskeleton organization.Key findingsIncreased level of gelsolin expression leads to its accumulation at the submembranous region of the cell accompanied by distinct changes in the state of actin polymerization and an increase in the migration of LS180 cells. In addition, LS180 cells overexpressing gelsolin form podosome-like structures as indicated by vinculin redistribution and its colocalization with gelsolin and actin. Downregulation of gelsolin expression in melanoma A375 cells significantly reduces their migratory potential.SignificanceOur experimental data indicate that alterations in the expression level of gelsolin and its subcellular distribution may be directly responsible for determining migration capacity of human cancer cells.     

Programmed cell death in the ascidian embryo: modulation by FoxA5 and Manx and roles in the evolution of larval development

Programmed cell death (PCD) has been discounted in the ascidian embryo because the descendants of every embryonic cell appear to be present in the tadpole larva. Here we show that apoptotic PCD is initiated in the epidermis and central nervous system (CNS) but not in the endoderm, mesenchyme, muscle, and notochord cells during embryogenesis in molgulid ascidians. However, the affected cells do not actually die until the beginning of metamorphosis. Although specific patterns of PCD were different in distantly related ascidian species, the results suggest that removal of CNS cells by apoptosis is a urchordate feature predating the origin of the vertebrates. Certain molgulid ascidian species have evolved an anural (tailless) larva in which notochord cells fail to undergo the morphogenetic movements culminating in tail development. These anural species include Molgula occulta, the sister species of the urodele (tailed) species Molgula oculata. We show that PCD in the notochord cell lineage precedes the arrest of tail development in M. occulta and other independently evolved anural species. The notochord cells are rescued from PCD and a tail develops in hybrid embryos produced by fertilizing M. occulta eggs with M. oculata sperm, implying that apoptosis is controlled zygotically. Antisense inhibition experiments show that zygotic expression of the FoxA5 and Manx genes is required to prevent notochord PCD in urodele species and hybrids with restored tails. The results provide the first indication of PCD in the ascidian embryo and suggest that apoptosis modulated by FoxA5 and Manx is involved in notochord and tail regression during anural development. Differences in PCD that occur between ascidian species suggest that diversity in programming apoptosis may explain differences in larval form.     

Changes in the tail of Ambystoma maculatum at different stages of metamorphosis: observations on tissue remodeling and its relationship to hydrolytic enzymes.

A system for staging A. maculatum during growth and metamorphosis was devised, based on several parameters of body size; body length, tail length and tail width. Animals at various stages of metamorphosis were employed to study the relationship between specific biochemical and histological changes that occur in the tail of this urodele during metamorphosis. The specific and total activity of two hydrolytic enzymes, acid phosphatase and beta-N-acetyl-glucosaminidase, were measured in tail tissues at progressive stages of development. The activities of these enzymes increased in both the fins and muscular portion of the tail during metamorphosis. These activities can be correlated with resorption of the tail fins and the remodeling of tissues in the muscular portion of the tail.     

Localization and mobility of gelsolin in cells

To investigate the physiologic role of gelsolin in cells, we have studied the location and mobility of gelsolin in a mouse fibroblast cell line (C3H). Gelsolin was localized by immunofluorescence of fixed and permeabilized cells and by fluorescent analog cytochemistry of living cells and cells that were fixed and/or permeabilized. Overall, the images show that in living cells gelsolin has a diffuse cytoplasmic distribution, but in fixed cells a minor fraction is associated with regions of the cell that are rich in actin filaments. The latter fraction is more prominent after permeabilization of the fixed cells because some diffuse gelsolin is not fixed and is therefore lost during permeabilization, confirmed by immunoblots. To determine quantitatively whether gelsolin is bound to actin filaments in living cells, we measured the mobility of microinjected fluorescent gelsolin by fluorescence photobleaching recovery. Gelsolin is fully mobile with a diffusion coefficient similar to that of control proteins. As a positive control, fluorescent phalloidin, which binds actin filaments, is totally immobile. These results are supported by immunoblots on cells permeabilized with detergent. All the endogenous gelsolin is extracted, and the half-time for the extraction is approximately 5 s, which is about the rate predicted for diffusion. Therefore, gelsolin is not tightly bound to actin filaments in cells. The most likely interpretation of the difference between living and fixed cells is that fixation traps a fraction of gelsolin that is associated with actin filaments in short-lived complexes.     

Molecular biology of gelsolin, a calcium-regulated actin filament severing protein

Gelsolin is a Ca2+-binding protein of mammalian leukocytes, platelets and other cells which has multiple and closely regulated powerful effects on actin. In the presence of micromolar Ca2+, gelsolin severs actin filaments, causing profound changes in the consistency of actin polymer networks. A variant of gelsolin containing a 25-amino acid extension at the NH2-terminus is present in plasma where it may be involved in the clearance of actin filaments released during tissue damage. Gelsolin has two sites which bind actin cooperatively. These sites have been localized using proteolytic cleavage and monoclonal antibody mapping techniques. The NH2-terminal half of the molecule contains a Ca2+-insensitive actin severing domain while the COOH-terminal half contains a Ca2+-sensitive actin binding domain which does not sever filaments. These data suggest that the NH2-terminal severing domain in intact gelsolin is influenced by the Ca2+-regulated COOH-terminal half of the molecule. The primary structure of gelsolin, deduced from human plasma gelsolin cDNA clones, supports the existence of actin binding domains and suggests that these may have arisen from a gene duplication event, and diverged subsequently to adopt their respective unique functions. The plasma and cytoplasmic forms of gelsolin are encoded by a single gene, and preliminary results indicate that separate mRNAs code for the two forms. Further application of molecular biological techniques will allow exploration into the structural basis for the multifunctionality of gelsolin, as well as the molecular basis for the genesis of the cytoplasmic and secreted forms of gelsolin.     

Vestigial Brain Melanocyte Development During Embryogenesis of an Anural Ascidian

Anural development was examined in the ascidian Bostrichobranchus digonas using specific markers for differentiated urodele ascidian larval cells and tissues. In this ovoviviparous anural ascidian, eggs, embryos and developing juveniles were present in the gonads, brood sacs, and atrial cavity, respectively. Morphological studies indicated that B. digonas embryos do not develop into tailed larvae with an extended notochord and differentiated muscle cells. In addition, these embryos lack detectable expression of the muscle-specific markers acetylcholinesterase, alpha actin, and myosin heavy chain. In striking contrast to other anural ascidian embryos, however, B. digonas embryos can develop tyrosinase in several melanocyte precursor cells and eventually form a brain pigment cell. The melanocyte does not become part of a definitive brain sensory organ (otolith) and subsequently disappears during metamorphosis. A period of tyrosinase expression was also observed following metamorphosis in which many tyrosinase-positive cells appear in the body of the developing juvenile. The results demonstrate that different urodele features can be uncoupled during the evolution of anural development. The development of a vestigial brain melanocyte also suggests that B. digonas evolved from a urodele ancestor rather than from another anural ascidian lacking a brain pigment cell.     

Motile areas of leech neurites are rich in microfilaments and two actin-binding proteins: gelsolin and profilin.

Cell motility is produced by changes in the dynamics and organization of actin filaments. The aim of the experiments described here was to test whether growing neurites contain two actin-binding proteins, gelsolin and profilin, that regulate polymerization of actin and affect non-neuronal cell motility. The distribution of gelsolin, profilin and the microfilaments was compared by immunocytochemistry of leech neurons growing in culture. We observed that microfilaments are enriched in the peripheral motile areas of the neurites. Both gelsolin and profilin are also concentrated in these regions. Gelsolin is abundant in filopodia and is associated with single identifiable microfilament bundles in lamellipodia. Profilin is not prominent in filopodia and shows a diffuse staining pattern in lamellipodia. The colocalization of gelsolin and profilin in motile, microfilament-rich areas supports the hypothesis that they synergistically regulate the actin dynamics that underlie neurite growth.     

Aging-associated increase of gelsolin for apoptosis resistance

Gelsolin, a Ca(2+)-dependent actin regulatory protein, was recently suggested to participate in apoptosis regulation. In this study, we found that the level of gelsolin is elevated in senescent human diploid fibroblasts (HDFs) and also in the tissues of old rats, i.e., in the liver, kidney, heart, spleen, stomach, and brain, etc. The ubiquitous increase of gelsolin in the aged organs and cells led us to assume that it might be related with one of the cardinal senescent phenotypes, aging-associated apoptosis resistency. Thus, we tested the sensitivity of senescent cells to apoptosis by menadione, an apoptosis-inducing agent, before and after the down-regulation of gelsolin. The down-regulation of gelsolin in senescent HDFs, independently of Bcl-2 family expression, resulted in an increased sensitivity to menadione-induced apoptotic cell death. The observed ubiquitous increase of gelsolin in the senescent states of cells and tissues, and the increased sensitivity to apoptosis-induction by gelsolin down-regulation, suggests that gelsolin would be partly responsible for age-related apoptosis resistance.     

Regulation of metamorphosis in ascidians involves NO/cGMP signaling and HSP90

Treatment of larvae of the ascidians Boltenia villosa (Family: Pyuridae) and Cnemidocarpa finmarkiensis (Family: Styelidae) with drugs that inhibit the function of the molecular chaperone HSP90 increased the frequency of tail resorption, the primary morphogenetic event of metamorphosis. If treatment was initiated at hatching, metamorphic events subsequent to tail resorption failed to occur, indicating an ongoing role for HSP90 during morphogenesis. Removal of tails from heads of mature, but not newly hatched larvae, induced metamorphosis of the head. Decapitation experiments indicate that the capacity of tails to shorten in response to inhibition of HSP90 function requires communication with heads. To identify candidate proteins with which HSP90 may interact to regulate metamorphosis, we noted that in mammalian cells, nitric oxide synthase (NOS) interacts with HSP90 and its activity is sensitive to drugs that inhibit HSP90 function. In addition, nitric oxide (NO) signaling in the marine snail Ilyanassa obsoleta is an important regulator of metamorphosis. Inhibition of NOS activity in these ascidian larvae with L-NAME increased the frequency of metamorphosis, consistent with a putative interaction of NOS and HSP90. NOS is present in tail muscle cells, implicating them as targets for the drug treatments, consistent with the decapitation experiments. Inhibition of soluble guanylyl cyclase, the most common effector of NO signaling, also increased the frequency of metamorphosis. In contrast to treatment with anti-HSP90 drugs, metamorphosis induced with L-NAME or ODQ was complete. The results presented suggest that an HSP90-dependent, NO-based regulatory mechanism localized in tails represses ascidian metamorphosis. We discuss these results in relation to the induction of ascidian metamorphosis by several unrelated agents.     

Interaction between noradrenaline or adrenaline and the beta 1-adrenergic receptor in the nervous system triggers early metamorphosis of larvae in the ascidian,Ciona savignyi

Molecular mechanisms underlying the metamorphosis of larvae, e.g., ligand and receptor interaction, have to be determined and roles for the nervous system in marine invertebrates are not well understood. We report here that treatment of swimming larvae of the ascidian Ciona savignyi with noradrenaline or adrenaline promoted morphological changes in early metamorphosis, e.g., tail resorption. Antagonists of the beta-adrenergic receptor, propranolol, and the beta(1)-adrenergic receptor, metoprolol, inhibited the noradrenaline-induced tail resorption, while an antagonist of the alpha-adrenergic receptor, phentolamine, and of the beta(2)- adrenergic receptor, butoxamine, had no inhibitory effects. In addition, a selective agonist of the beta-adrenergic receptor, isoproterenol, the concentration of which was lower than the effective concentration of the neurotransmitters, facilitated tail resorption. Immunohistochemical studies, using an anti-dopamine-hydroxylase antibody, showed that neurotransmitters such as noradrenaline and adrenaline localized around the brain vesicle of the larvae during metamorphosis. The beta(1)-adrenergic receptor stained with antibodies was localized on the nervous system. Temporal expression of the beta(1)-adrenergic receptor was intense in the nervous system in the larvae competent for metamorphosis. We propose that interactions between noradrenaline or adrenaline and the beta(1)-adrenergic receptor in the nervous system mediate the process of metamorphosis of Ciona larvae.     

Regulation of neural differentiation by normal and mutant (G654A, amyloidogenic) gelsolin.

Gelsolin belongs to a family of proteins that modulate the structural dynamics of cytoskeletal actin. Gelsolin activity is required for the redistribution of actin occurring during membrane ruffling, cell crawling, and platelet activation. A point mutation (G654A) in the gelsolin gene causes a dominantly inherited systemic amyloidosis called familial amyloidosis of the Finnish type (FAF). This disease is characterized by a cranial neuropathy that cannot be explained solely by amyloid deposits. To address the question of whether gelsolin has a specific role in neural cell development, we transfected cDNA for wild type and G654A point-mutated gelsolin into a neural cell line, Paju, which can be induced to differentiate by treatment with phorbol 12-myristate 13-acetate. Overexpressed wild type gelsolin inhibited neural differentiation whereas mutated gelsolin did not, indicating that appropriate gelsolin activity is essential for neural sprouting. The G654A mutant gelsolin induced stabilization of F-actin and reduced the plasticity of neural development. This provides a novel etiopathogenetic mechanism for the neuronal dysfunction in FAF.     

Isolation and characterization of genes that are expressed during Ciona intestinalis metamorphosis

In ascidians, the events of metamorphosis transform the non-feeding, mobile tadpole larva into a filter-feeding, fixed juvenile, and the process involves rearrangements of cells, two organs and physiological changes. Differential screening was used to isolate two genes that are not expressed in swimming larvae but are expressed immediately after the initiation of metamorphosis in Ciona intestinalis. One of the genes, Ci-meta1, encodes a polypeptide with a putative secretion signal sequence, 6 epidermal growth factor (EGF)-like repeats and 13 calcium-binding EGF-like repeats. The gene begins to be expressed immediately after the beginning of metamorphosis in the adhesive organ and is likely to be associated with the signal response for metamorphosis. Another gene named Ci-meta2 encodes a protein with a putative secretion signal and three thrombospondin type-1 repeats. Ci-meta2 gene expression begins at the larval stage and is upregulated in the metamorphosing juveniles. Ci-meta2 expression is found in three regions; the adhesive organ which is also associated with settlement, the neck region between the trunk and the tail of the larva which is associated with tail resorption, and dorsal regions of the trunk which correspond to the location of the siphon primordium. This gene may be involved in the dynamic arrangement of cells during ascidian metamorphosis.     

Synthesis and secretion of serum gelsolin by smooth muscle tissue

Gelsolin is one of many actin binding proteins which regulate the structure of intracellular microfilaments. A secretory form of gelsolin, a protein also known as "actin depolymerizing factor" or "brevin," is present in animal sera. In the present studies, we: demonstrate that a 90-kDa secretory protein produced by chicken gizzard smooth muscle is serum gelsolin; show that chicken serum gelsolin, as compared with its mammalian counterparts, lacks 26 amino acid residues at its NH2-terminal end; show that gizzard smooth muscle devotes on the order of 100 times more of its total protein synthetic effort (about 1% of the total) to the production of serum gelsolin than does liver, a previously speculated major source of this protein; and give evidence that rat tissues which are rich in smooth muscle cells (blood vessels, uterine muscle) also produce serum gelsolin. Our work suggests that, in vivo, smooth muscle-containing tissues may be major producers of the serum form of this actin binding protein.