Morphological features of the Black Sea turbot (Scophthalmus maeoticus) during the period of embryonic development

Q4 Environmental Science Marine Biological Journal Pub Date : 2019-12-30 DOI:10.21072/mbj.2019.04.4.06
A. Khanaychenko, V. Giragosov
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引用次数: 0

Abstract

Black Sea turbot (hereinafter BST), Scophthalmus maeoticus (Pallas, 1814), is a valuable fish for commercial fishery and promising object of industrial mariculture. Potential fecundity of BST is very high, 3–13 million eggs; however, survival of its progenies during early development in the sea is unpredictable and low (mortality is up to 90 %). In nature fertilized pelagic BST eggs rise to the sea surface in 2–3 hours; BST develop in upper waters being part of neuston till hatching. BST on its early stages of development could be considered the most vulnerable as the embryo is exposed to diverse adverse effects. The survival and physiological state of the larvae at hatching till exogenous feeding depend on the norm of morphological characteristics of the embryos during their development. Our aim was to study the norm of the changes in BST morphological characteristics during embryogenesis. Morphological analysis of the BST embryogenesis stages from fertilization till hatching on the basis of detailed study of intact embryos (> 2000 eggs) sampled from different experimental batches incubated under experimental conditions is presented. Digital photos and videos of alive eggs were taken with Canon PowerShot A720 using binocular microscope MBS-10 at magnification 8×4 and under light inverted microscope Nikon Eclipse TS100, equipped with analog camera, at magnification ×4, ×10, and ×40. The morphological features of embryogenesis in BST before and after fertilization, cleavage, blastulation, gastrulation, epiboly, and neurulation and until hatching are presented by photos with detailed description of transforming embryological structures. Fertilized pelagic BST eggs covered by transparent shell vary from (1.26 ± 0.14) to (1.31 ± 0.15) mm in diameter, have homogenously distributed yolk and a single round transparent oil drop of 0.20–0.21 mm, positioned at the top of the yolk. Scale of timing of morphological changes is presented in relative time units (as a time interval from fertilization until the emergence of morphological structure in percentage of the total duration of embryogenesis, % RT). Cleavage starts at 2.5 % RT. Cell division desynchronizes between the 6th and 7th cleavage, at 128 blastomeres. Yolk syncytial layer controlling processes of epiboly, cells differentiation, and morphogenesis is formed during the 10th–11th mitotic cycle (12 % RT, about 512–1024 cells). From the germ ring registered at 21 % RT, the embryonic shield develops (at 25 % RT), and organize formation of embryonic axis from 20 to 50 % epiboly (31 % RT). During 70–75 % epiboly (40–45 % RT), the neural keel is formed; notochord and optical primordia become visible; Kupffer’s vesicle emerges at the start of segmentation. Optic cups develop, and more than 20 somites are observed at the end of epiboly (49 % RT). By 60 % RT the Kupffer’s vesicle disappears in tail bud formed; lens placodes are formed in optic cups. Notochord vacuolization, myotomes formation, and tail growth are observed by 65 % RT. The caudal part of the body separates from the yolk by 70–75 % RT. About 80 % RT neuromuscular activity starts; heart beating initiates; free tail covers more than 60 % of the yolk; differentiating xantophores give a pinkish hue to the embryo. By 90–95 % RT eye cups with lenses; three symmetric otic capsules with otoliths, melanophores, and xantophores present in the embryo with 33–38 body somites; it performs jerky movements. Prior hatching, the egg shell becomes elastic, stretches, and breaks in the head area. Hatching occurs 114–94 hours after fertilization at +14…+16 °С. By hatching, all organs are formed in bilateral symmetrical BST larva (standard length is (2.53 ± 0.13) to (2.91 ± 0.10) mm), three auditory chambers with otoliths exist, eyes are non-pigmented, intestinal tract is closed; within 3–5 days it develops at the expense of yolk. Description of morphological changes in the BST embryo at norm of development could be used for elaboration of criteria of developing BST eggs both in natural environment and under cultivation conditions.
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黑海大菱鲆(Scophthalmus maeoticus)胚胎发育时期的形态特征
黑海大菱鲆(以下简称BST),学名为Scophthalmus maeoticus (Pallas, 1814),是一种具有商业渔业价值的鱼类,也是工业海水养殖的理想对象。BST的潜在繁殖力非常高,300 - 1300万个卵;然而,其后代在海洋早期发育期间的存活率是不可预测的,而且很低(死亡率高达90%)。在自然界中,受精的远洋BST卵在2-3小时内上升到海面;BST在上游水域发展,作为纽斯顿的一部分,直到孵化。由于胚胎暴露于各种不利影响,早期发育阶段的BST可能被认为是最脆弱的。幼虫从孵化到外源摄食的生存和生理状态取决于胚胎发育过程中形态特征的正常。我们的目的是研究胚胎发生过程中BST形态特征的变化规律。本文在对不同实验批次的完整胚胎(约2000个卵)进行详细研究的基础上,对在实验条件下培养的BST胚胎发生阶段从受精到孵化进行了形态学分析。用佳能PowerShot A720用MBS-10双目镜显微镜(放大倍数为8×4)和尼康Eclipse TS100光学倒置显微镜(放大倍数为×4、×10和×40)拍摄活卵的数码照片和视频。通过照片展示了BST胚胎发生的形态特征,包括受精前后、卵裂、囊胚、原肠胚、卵裂期、胚乳期、神经期和孵化期,并详细描述了胚胎结构的转变。透明壳覆盖的受精卵BST蛋直径为(1.26±0.14)~(1.31±0.15)mm,蛋黄分布均匀,蛋黄顶部有一个圆形透明油滴,直径为0.20-0.21 mm。形态变化的时间尺度以相对时间单位表示(从受精到形态结构出现的时间间隔,占胚胎发生总持续时间的百分比,% RT)。细胞分裂在第6次和第7次分裂(128个卵裂球)之间不同步。卵黄合胞层在第10 - 11个有丝分裂周期(12% RT,约512-1024个细胞)形成,控制表观代谢、细胞分化和形态发生过程。胚环在21%发育时发育成胚盾(25%发育时),胚轴在20% - 50%发育时组织形成(31%发育时)。在70 - 75%的表观代谢(40 - 45%的RT)期间,神经龙骨形成;脊索和光原基变得可见;库普弗氏囊泡在分割开始时出现。视神经杯发育,在离体期末期观察到超过20个小体(49% RT)。在60%的RT时,库普弗氏囊消失在形成的尾芽中;透镜基板形成于光杯中。脊索空泡形成、肌瘤形成和尾部生长在65%时观察到。体尾部在70 - 75%时与蛋黄分离。约80%时神经肌肉活动开始;心脏开始跳动;游离尾覆盖60%以上的蛋黄;分化的黄托细胞给胚胎带来粉红色的色调。90% - 95%的RT眼罩带镜片;胚胎有3个对称的耳囊,有耳石、黑素细胞和黄质细胞,体体体数为33-38个;它的动作很急。在孵化之前,蛋壳变得有弹性,伸展,并在头部区域破裂。孵化发生在受精后114-94小时,温度为+14…+16°С。经孵化,双侧对称BST幼虫各器官发育完整(标准长度为(2.53±0.13)~(2.91±0.10)mm),存在3个耳石耳腔,眼睛无色素,肠道封闭;在3-5天内,它以蛋黄为代价发育。对BST胚胎发育常态形态变化的描述可用于制定BST卵子在自然环境和培养条件下发育的标准。
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来源期刊
Marine Biological Journal
Marine Biological Journal Environmental Science-Ecology
CiteScore
0.90
自引率
0.00%
发文量
17
审稿时长
21 weeks
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