Search engine for discovering works of Art, research articles, and books related to Art and Culture
Javascript must be enabled to continue!
Morphological characterization of the tunic in the edible ascidian, Halocynthia roretzi (Drasche), with remarks on ‘soft tunic syndrome’ in aquaculture
View through CrossRef
Abstract‘Soft tunic syndrome’ is a serious problem in the aquaculture of the edible ascidian, Halocynthia roretzi (Drasche), and often leads to mass mortality. Here, we describe the tunic morphology of intact and diseased ascidians to reveal structural differences between them. Morphologically, diseased tunics are not very different from intact tunics, although the former are thinner and softer than the latter. While several types of cells are distributed in the tunic, the cell types and their cytomorphologies were almost identical in both groups. As bacterial/protozoan cells were not found in either intact or diseased tunics, they are not the direct cause of soft tunic syndrome. The most remarkable difference was in the bundles of tunic fibres that compose the tunic matrix; in intact tunics, the thick bundles interlace to form a firm matrix, whereas in soft tunics, the tunic fibres do not form thick bundles. Furthermore, areas of low fibre density were found in diseased tunics. Therefore, soft tunic syndrome probably causes inhibition of bundle formation and degradation of tunic bundles, creating areas of low fibre density, although the causes remain unknown.
Title: Morphological characterization of the tunic in the edible ascidian, Halocynthia roretzi (Drasche), with remarks on ‘soft tunic syndrome’ in aquaculture
Description:
Abstract‘Soft tunic syndrome’ is a serious problem in the aquaculture of the edible ascidian, Halocynthia roretzi (Drasche), and often leads to mass mortality.
Here, we describe the tunic morphology of intact and diseased ascidians to reveal structural differences between them.
Morphologically, diseased tunics are not very different from intact tunics, although the former are thinner and softer than the latter.
While several types of cells are distributed in the tunic, the cell types and their cytomorphologies were almost identical in both groups.
As bacterial/protozoan cells were not found in either intact or diseased tunics, they are not the direct cause of soft tunic syndrome.
The most remarkable difference was in the bundles of tunic fibres that compose the tunic matrix; in intact tunics, the thick bundles interlace to form a firm matrix, whereas in soft tunics, the tunic fibres do not form thick bundles.
Furthermore, areas of low fibre density were found in diseased tunics.
Therefore, soft tunic syndrome probably causes inhibition of bundle formation and degradation of tunic bundles, creating areas of low fibre density, although the causes remain unknown.
Related Results
Regeneration of tunic cuticle is suppressed in edible ascidian Halocynthia roretzi contracting soft tunic syndrome
Regeneration of tunic cuticle is suppressed in edible ascidian Halocynthia roretzi contracting soft tunic syndrome
Soft tunic syndrome is an infectious disease caused by the flagellate Azumiobodo hoyamushi, which severely damages the aquaculture of the edible ascidian Halocynthia roretzi. Tunic...
Tunic morphology and viral surveillance in diseased Korean ascidians: soft tunic syndrome in the edible ascidian, Halocynthia roretzi (Drasche), in aquaculture
Tunic morphology and viral surveillance in diseased Korean ascidians: soft tunic syndrome in the edible ascidian, Halocynthia roretzi (Drasche), in aquaculture
Abstract‘Soft tunic syndrome’ causes mass mortality in the edible ascidian Halocynthia roretzi in Korean and Japanese aquaculture. In histopathological comparison, there were no sp...
Active Contraction in the Stable Mechanical Environment of the Tunic of the Ascidian, Halocynthia roretzi, a Polysaccharide-Based Tissue with Blood Circulatory System
Active Contraction in the Stable Mechanical Environment of the Tunic of the Ascidian, Halocynthia roretzi, a Polysaccharide-Based Tissue with Blood Circulatory System
Halocynthia roretzi, a member of Ascidiacea, is covered with its own tunic, which is composed of polysaccharides, such as cellulose Iβ and sulfated chitin. H. roretzi has an open-v...
Deformation Control and Mass Transfer in the Tunic of Halocynthia roretzi
Deformation Control and Mass Transfer in the Tunic of Halocynthia roretzi
Background:It has been previously reported that the tunic ofHalocynthia roretzi, mainly composed of cellulose, is actively deformed with mass transfer by the mechanical stimuli.Obj...
Visioning the future of Aquaculture in Hawai‘i
Visioning the future of Aquaculture in Hawai‘i
The University of Hawai‘i Aquaculture Program and the National Oceanic and Atmospheric
Administration’s (NOAA) Hawaiian Islands Humpback Whale National Marine San...
Ethnobotanical study of edible wild plants in Ensaro district, Amhara regional state, Ethiopia
Ethnobotanical study of edible wild plants in Ensaro district, Amhara regional state, Ethiopia
Abstract
Background: Ethiopia is one of the biodiversity-rich countries in Africa. Most rural communities are highly dependent on forest products including edible wild plan...
Satellite observed rapid inland aquaculture expansion in Jianghan Plain, China from 2016 to 2022
Satellite observed rapid inland aquaculture expansion in Jianghan Plain, China from 2016 to 2022
Inland freshwater aquaculture which includes a new crop-aquaculture system accounts for 77 % of aquaculture production worldwide and contributed significantly to the global demand ...
Active Deformation in the Tunic ofHalocynthia roretzi: How the Tissue Composed of Cellulose Responds to Stimuli and Deforms
Active Deformation in the Tunic ofHalocynthia roretzi: How the Tissue Composed of Cellulose Responds to Stimuli and Deforms
Halocynthia roretzi, belonging to class Ascidiacea, has highly pure and crystalline cellulose Iβ, and sulfated chitin in its tunic. Cells, including hemocytes in the open circulato...