Development of the cartilaginous skull in solea solea: trends in pleuronectiforms

The postembryonic development of the cartilaginous cephalic skeleton in Solea solea (Linné) was observed from hatching to the juvenile stage or postmetamorphic larva. Fry were trypsin-cleared and alcian-blue-stained. At hatching, Solea solea displays no cartilaginous structure. On day 3, the fry exhibit trabecular bars, Meckel's cartilages, palatoquadrates, hyosymplectics, hyoid bars, the first two ceratobranchials, and basibranchials 1–3. On day 4, ceratobranchials 3 and 4 form. On day 12, short taeniae marginales are formed on the well-developed otic capsules and the branchial basket is nearly complete. On day 14, a first cartilage reduction begins as the posterior part of the trabecula communis separates from the otic capsules. On day 18, metamorphosis begins. The tectum posterius completes posteriorly the braincase dome. On day 20, the left eye moves to the median crest of the head and the right eye shifts downwards slightly. Consequently, displacement of the right eye induces a deformation extending to the right pterygoid process. On day 23, both eyes are located on the same side. On day 29, cartilage reduction affects the hyosymplectics; it continues with the first two ceratobranchials on day 32 and with the otic capsules on day 40. On day 50, cartilage reduction has reached the lamina precerebralis. Only a few small lumps remain at the level of the neurocranium and the splanchnocranium.     

Early development of the chondrocranium in Salmo letnica(Karaman, 1924)(Teleostei: Salmonidae)

The ontogenetic development of the chondrocranium of Ohrid trout Salmo letnica was studied from hatching until 92 days post‐hatching (dph). Most of the samples were in toto trypsin cleared and stained, some specimens were used for serial histological sectioning. The serial histological sections of fish specimens at the age of 92 dph were used for a graphical reconstruction of the cartilaginous neurocranium. A chronological evaluation of the formation of the cartilaginous skull in the early development of S. letnica was performed. In order to investigate to what degree the ontogeny of the Ohrid trout is unique, the results were compared with data of the development of other salmonids, as well as some non‐salmonid teleosts. The development of the cartilaginous structures of the Ohrid trout was found to be similar to that of other salmonids. Most of the cartilage structures of the neurocranium and the viscerocranium are present at the moment of hatching of this species. A fully developed chondrocranium was observed at the age of 92 dph, when the first signs of cartilage resorption could also be observed.     

Early development of the cephalic skeleton of Barbus barbus (Teleostei, Cyprinidae)

The inception, and development of the cephalic skeleton of Barbus barbus from hatching to 24 days passes through periods of fast and slow growth; these rates are not the same in different parts of the skull. Trabeculae, parachordal plates, Meckelian cartilages and hyposymplectics are present at hatching. Then the cartilaginous floor of the neurocranium develops, the pars quadrata, the hyoid bars and branchial arches elements appear shortly before the first movable dermal bones, the dentaries, maxillae and opercles. The first bone of the braincase to appear is the parasphenoid; other bones develop subsequently and at the same time: the angular, quadrate, interopercle and fifth ceratobranchial. Later the splanchnocranium continues to develop at a relatively fast rate while the neurocranium shows little growth. The braincase does not begin to close before the 24th day, nor do the first bones of the skull roof appear, while the bucco-pharyngeal apparatus is complete, having the adult shape. The early constitution of the latter structures seems to be linked with the mechanical demands of biological functions such as breathing and feeding.     

Early development of the cephalic skeleton in the turbot

At hatching Scophthalmus maximus shows no cartilaginous and no bony structure. Mecke?s cartilages appear when the fry are 1 day old, followed on day 2, by formation of the trabecular bars, fused at the outset to form a trabecula communis. Concurrently, the palatoquadrates complete the mandibular arch, and the first two pairs of ceratobranchials, associated with a pair of hyoid bars, form the beginnings of the hyobranchial system. By day 3, the parachordals have fused with the trabecular bars, the hyosymplectics have linked to the hyoid bars by interhyals, and the first four pairs of ceratobranchials have appeared. The first bony structures appear: the preoperculars. On day 8, the frontals develop above the orbits and the maxillaries and dentaries appear. On day 10, the primordia of the taeniae marginales appear, the palatoquadrates bear a pterygoid process, and to the branchial basket have been added the fifth pair of ceratobranchials and the four pairs of epibranchials. On day 12, both pairs of posterior pharyngobranchials are present. The premaxillaries develop in front of the maxillaires, and retroarticulars and the angulars complete the lower jaws. On day 13, a thin parasphenoid contributes to the floor of the neurocranium, and ectopterygoids and entopterygoids to the splanchnocranium. The set of opercular bones is complete. On day 15, the tectum synoticum closes the braincase posteriorly. The splanchnocranium possesses a basihyal and the pharyngobranchials of the first epibranchials. On day 18, the tectum posterius completes the dome of the braincase. The rear end and lateral walls of the skull are formed by the basioccipital, the exoccipitals, the pterotics, and the parietals. The suspensorium is nearly complete. From day 10, the first resorptions begin in parallel with the construction of the chondrocranium. Mecke?s cartilages each split in two, then the posterior part of the trabecular bars disappears. On day 23, the right taenia marginalis separates from the lamina orbitonasalis and curves towards the centre. Simultaneously, the right eye begins its migration to the left. This is the only metamorphosis-linked asymmetry to appear during the development of the chondrocranium. On day 25, many more bony structures appear, a characteristic of this stage: the nasals, lateral ethmoids, mesethmoid, sphenotics, prootics, pleurosphenoids, epiotics, and supraoccipital. From this stage on, the bony structures continue to develop, while the front of the neurocranium and the jaws undergo a deep remodelling due to metamorphosis. The left taenia marginalis does not appear reduced until day 29. By day 45, there remain only a few small elements of the cartilaginous skull.     

Early development of the skull of Sander lucioperca (L.) (Teleostei: Percidae) relating to growth and mortality

The early osteological development of the skull (chondrocranium and osteocranium) of the pikeperch Sander lucioperca was studied. Specimens were reared at two temperatures, 15·5 and 18·0° C, from hatching until 47 and 43 days after fertilization (DAF), respectively. The skeletal elements characteristic for the different developmental stages were the same at both rearing temperatures, but pikeperch reared at 15·5° C reached the developmental stages later. The formation of the functional complexes, the neurocranium, jaws and suspensorium, branchial basket and hyoid arch, was evaluated chronologically. The focus was on skull development during several functional changes: at hatching, at the shift from endogenous to mixed feeding, the shift to exclusively exogenous feeding and upon reaching the final prey-capture mechanism. Growth in total length differed between fishes reared at the two temperatures, except during a phase of very slow growth from the end of the embryonic stage until the second larval stage. The latter phase, in which most of the bony elements of the viscerocranium started to form, was marked by high mortality. When exogenous feeding began, the growth rates at both temperatures increased distinctly and the first bony elements were formed in the neurocranium. Specimens reared at 18·0° C grew continuously, but those at 15·5° C showed a second period of slow growth and high mortality. Fish reared at 18·0° C reached the successive larval stages distinctly earlier than fish reared at 15·5° C.     

Early development of the head skeleton in Brycon moorei(Pisces, Ostariophysi, Characidae)

At hatching (15 h post fertilization), Brycon moorei possesses no skeletal structure. Thereafter, development is very rapid. The first oral teeth appear no later than 3 h post‐hatching, but they remain covered with epithelium until c . 45 h. At 7 h, the trabecular bars and part of the cartilaginous visceral arches are visible and at 15 h, the dentaries and premaxillaries are present. At 25 h, i.e . the onset of piscivory and cannibalism (the yolk sac is only fully resorbed after 36 h), the oral teeth are fully developed, the first pharyngeal teeth are formed, and some head movements already appear synchronized, but the mouth cavity is not completely isolated from the neurocranium by bony structures. Thereafter, no new buccal or pharyngeal bony structure is visible until 45 h, when the maxilla and opercula appear, along with a new type of cannibalistic behaviour. Cartilage resorptions also start at 45 h, but with no concomitant replacement by formation of calcified structures. Later, development gradually becomes similar to that of many previously studied teleosts. The developmental pattern of B. moorei is thus extremely rapid in comparison with other teleosts, i.e . it prioritizes feeding structures that permit the expression of piscivory at a very early age. The uniqueness of this pattern is discussed in relation to ecological constraints on early feeding and fast growth.     

异齿裂腹鱼仔鱼的黑色素分布

本文运用组织学方法对异齿裂腹鱼仔鱼发育过程中除眼睛以外的黑色素分布进行研究。结果表明: 异齿裂腹鱼孵化出膜后,黑色素在各个组织器官的出现顺序为: 脑颅外膜→围心腔、背部皮肤→腹腔内膜、脊髓腔。其中,出膜5 d时脑颅外膜处出现黑色素;7 d时围心腔和背部皮肤出现黑色素;10 d时腹腔内膜、脊髓腔出现黑色素。异齿裂腹鱼出膜10 d后,其皮肤和内脏器官(脑颅、围心腔、腹腔内膜、脊髓腔)均具有黑色素,且主要分布在背侧。黑色素在异齿裂腹鱼仔鱼发育过程中的出现时序和分布规律可能与其所处的强紫外辐射环境有关。本研究可为研究鱼类黑色素的紫外防护机制提供参考,并为今后高原鱼类仔鱼的培育条件优化提供理论支撑。     

Development of the cerebellar glomeruli in the ontogeny of hens

By means of light and electron microscopy development of the cerebellar glomeruli has been studied in the hen ontogenesis. Two successive stages have been revealed: protoglomerular (the 16th-18th days of incubation) and glomerular (the 19th day of incubation--the end of the 3d week after hatching). Specific peculiarities of their structural organization are presented. A suggestion is made on an inductive effect of the afferent mossy fibers on processes of morphological formation of the cerebellar glomeruli.     

Histological and morphological evaluations of the digestive tract and associated organs of haddock throughout post-hatching ontogeny

At hatching, the oesophagus of haddock Melanogrammus aeglefinus lacks goblet cells, the intestine is a simple undifferentiated tube, the liver is present as a rounded mass caudal to the heart, and numerous zymogen granules are present in the pancreas. The first intestinal convolution appears at day 2, at the posterior end of the digestive tract. The oesophagus displays alcian blue and PAS positive mucus secreting cells on day 12, which become numerous by day 15. By day 18, epithelial cells of the posterior intestine show evidence of protein absorption in the form of supranuclear vacuoles. The swimbladder inflates in 50% of the larvae by day 22, although inflation rate is highly variable. By day 35, or 10 mm, a pyloric caecal ridge appears which separates the presumptive stomach, which is now showing evidence of gastric gland formation, from the intestine. This marks the beginning of digestive features characteristic of the juvenile stage.     

Experimental studies on a lethal gene (t) in the Mexican axolotl, Ambystoma mexicanum

In the Mexican axolotl, Ambystoma mexicanum, the developmental mutation lethal t is inherited as a simple Mendelian recessive. Mutant larvae failed to feed and died, on the average, 17 days after hatching. Unfed wild-type larvae died an average of 23 days after hatching. By 15 days, forelimb development had progressed further in the wild type; a cartilaginous scapula and humerus were present, but no cartilage was seen in the mutant limb. Histological examination indicated that the visceral cartilage may also be abnormal, and the rectus cervicus muscle was found to have fewer and smaller fibers. Though the mutant was not rescued by parabiosis with wild-type embryos, transplants of presumptive gill and limb tissue to wild-type hosts survived, indicating that the mutation is not an autonomous cell lethal.     

Osteology and myology of the cephalic region and pectoral girdle of Pimelodus blochii, comparison with other pimelodines, and comments on the synapomorphies and phylogenetic relationships of the Pimelodinae (Ostariophysi: Siluriformes)

The cephalic and pectoral girdle structures of the pimelodin Pimelodus blochii (Pimelodus group) are described and compared to those of representatives of the two other main pimelodin groups, namely Calophysus macropterus (Calophysus group) and Pseudoplatystoma fasciatum (Sorubim group), and of a representative of the peculiar pimelodin genus Hypophthalmus, H. edentatus, and several other catfishes, as the foundation for a discussion on the synapomorphies and phylogenetic relationships of the Pimelodinae. Three new, additional potential synapomorphies to support the monophyly of the Pimelodinae are pointed out: (1) presence of a 'muscle 1 of the mandibular barbels' running from the antero-ventro-mesial surface of the cartilaginous plates carrying these barbels to the dentaries; (2) presence of a muscle tensor tripodis running from the posterior surface of the neurocranium to the dorsal surface of the swimbladder near the tripus; and (3) presence of a 'drumming muscle of the swimbladder' running from the parapophyses of the fourth vertebra and, eventually, the posterior surface of the neurocranium, to the antero and antero-ventral surface of the swimbladder. The subfamilies Pimelodinae, Heptapterinae and Pseudopimelodinae seem to constitute a monophyletic assemblage, thus contradicting the commonly accepted idea that the family Pimelodidae is a polyphyletic clade.     

Ontogenesis of 5-hydroxytryptamine-like immunoreactive cells and their relationship with bombesin in chicken proventriculus

By using a double-stain immunohistochemical procedure, the Aa. studied the onset, the behaviour and the possible interrelationship between the 5-HT-like and bombesin-like immunoreactive cells during the ontogenesis of chicken proventriculus and in adult animals. The 5-HT-like immunoreactive cells become evident from the 8th day of incubation and they reach their peak around the 16th day, then markedly decrease at hatching. In adult animal these cells are always present, but are not so numerous. Between the 14th and the 18th day many double-stained cells scattered among other only 5-HT or bombesin-like immunoreactive cells are present. They can also be observed in adults, but only occasionally.     

Differential expression and localization of brain-type and mitochondrial creatine kinase isoenzymes during development of the chicken retina: Mi-CK as a marker for differentiation of photoreceptor cells

The expression and the cellular- as well as subcellular-distribution of brain-type B-CK and mitochondrial Mi-CK during development of the chicken retina was studied by immunoblotting, immunofluorescence and immunogold methods. B-CK expression and accumulation in retina was high from early stages of embryonic development on, decreased slightly around hatching and remained high again during adulthood. At early stages of development (days 2-5), B-CK was more or less evenly distributed over the entire retina with the exception of ganglion cells, which were stained more strongly for B-CK than other retinal precursor cells. Then, at around day 10, the beginning of stratified immunostaining by anti-B-CK antibody was noted concomitant with progressing differentiation. Finally, a dramatic increase in staining of the differentiating photoreceptor cells was seen before hatching (day 18) with weaker staining of other cell types. At hatching, as in the adult state, most of the B-CK was localized within rods and cones. Thus, during retinal development marked changes in the immunostaining pattern for B-CK were evident. By contrast, Mi-CK expression was low during development in ovo and rose just before hatching with a predominant accumulation of this isoenzyme within the ellipsoid portion of the inner photoreceptor cell segments. Mi-CK accumulation in the retina coincided with functional maturation of photoreceptors and therefore represents a good marker for terminal differentiation of these cells. B-CK, present from early stages of retina development, seems to be relevant for the energetics of retinal cell proliferation, migration and differentiation, whereas the simultaneous expression of both B- and Mi-CK around the time of hatching indicates a coordinated function of the two CK isoforms as constituents of a PCr-circuit involved in the energetics of vision, which, in autophagous birds, has to be operational at this point in time.     

Anaerobic metabolism in fowl embryos during normal incubation

Lactate concentration in blood, liver, yolk, amniotic and allantoic fluid and blood pyruvate was measured in embryos in the final week of incubation. Blood lactate was low up to day 18. The blood lactate/pyruvate ratio and liver lactate increased from day 19 until hatching. From day 14 to 19, lactate concentration in amniotic fluid remained constant, it increased 2-fold in yolk and 10-fold in allantoic fluid. There was only a 48% net accumulation of lactate in the three cavities. In conclusion, fowl embryos do not turn to anaerobic metabolism until the hatching process starts on day 19.     

Electrophoretic characterization of glycosaminoglycans during development of the chick embryo skin

Glycosaminoglycans extracted by CPC precipitation from chick embryo skin at 9, 12, 15, 18, 21 days of incubation were separated by three different electrophoretic methods on acetate cellulose strips. We observed the presence of Hyaluronic acid, Dermatan Sulfate and Chondroitin-4-Sulfate during the whole period considered and of Heparan Sulfate only after the 9th day. Dermatan Sulfate increases until the 15th day then decreases progressively; on the contrary Hyaluronic acid and Chondroitin-4-Sulfate decrease during days 9 to 15 then increase until hatching. Heparan Sulfate appear the 9th day then increases progressively until hatching.     

Development of the bony skull in common sole: brief survey of morpho-functional aspects of ossification sequence

The postembryonic development of the bony cephalic skeleton in the common sole Solea solea , observed from hatching to the juvenile stage or postmetamorphic larva, appears to follow a similar chronological order to that observed in other Pleuronectiformes and Perciformes and the sequence in bone formation is a response to functional demands. At hatching, S. solea has no bony structure. On day 4, only the outlines of maxillaries and opercular bones are visible. On day 6, a thin parasphenoid appears between the orbits and isolates the braincase from the buccal cavity making food ingestion possible without any impact on the brain. On day 8, the dentaries form and two small preopercular bones appear on each side of the head. On day 9, at weaning from the yolk sac, branchial arches support the gill filaments (used for respiration and trapping phytoplankton which pass through the open mouth). On day 10, the premaxillaries develop in front of the maxillaries. The superimposing of the maxillaries and the premaxillaries is a typical feature of species possessing an acanthopterygian protractile mouth at the adult stage. On day 12, the frontals develop above the orbits and the set of opercular bones is complete. On day 18, the migration of the left eye begins. On day 20, the left eye has moved to the median crest of the head. On day 23, both eyes are located on the same side. On day 26, the braincase is formed by a basioccipital, exoccipitals, pterotics, sphenotics and a supraoccipital. On day 50, new structures have appeared, others have developed and have undergone an extensive remodeling due to metamorphosis.     

Organ differentiation in newly hatched common wolffish

Wolffish Anarhichas lupus (Anarhichadidae) hatch from large demersal eggs (c. 5–6 mm) after a long incubation period (c. 800–1000 degree days) at 20–25 mm LT with a juvenile appearance: a small yolk sac, pigmented but partly transparent skin densely supplied with mucous cells, well developed body musculature and a cartilaginous skeleton. The results of histomorphological studies illustrate the apparent functionality of tissues and organs at hatching. The mucosa of the oral cavity and various parts of the digestive channel are well differentiated and the cellular characteristics are described within each region. A stomach with gastric glands is established before hatching. The pancreas has well developed endo- and exocrine tissue and the hepatocytes are vacuolized. The kidney tissue has numerous tubuli and haematopoietic tissue in the bilobed head region. The spleen, thymus and thyroid glands also appear mature. Cones are dominant in the visual cell layer of the retina.     

Aspects of early development in the Adriatic sturgeon Acipenser naccarii

This study investigates the development of the sensory-cutaneous apparatus and digestive tract of Adriatic sturgeon (Acipenser naccarii). Light and electron microscopy observations were carried out on various developmental stages, from hatching to 180 days old.
At hatching, sturgeon pre-larvae exhibit differentiation of olfactory sensory cells. By day 4 taste buds are differentiated on lips and barbels. At 12 days after hatching, the larvae are equipped with an extensive ventral cephalic sensory apparatus. Electrosensory organs are arranged in regular lines in the rostral ventral region, and taste receptors are organised in parallel rows on and inside the lips as well as on the external side of the barbel. Ventral free neuromasts are positioned in rostral grooves. The retina is completely differentiated in each stratum. At this stage, larvae show canine-like teeth on lips and pharynx, and the specific mucosae of the different digestive regions are differentiated. By day 36 the canine-like teeth are located exclusively on the tongue and roof of the buccal cavity, and the mouth is protrusible. At 180 days differentiation is still not completed, and although teeth have disappeared from the palate, they still persist along a central line on the tongue.     

西藏巨须裂腹鱼早期发育特征

巨须裂腹鱼(Schizothorax macropogon)隶属裂腹鱼亚科, 裂腹鱼属, 是西藏特有经济鱼类, 因过度捕捞, 其种群数量和分布面积下降, 在2009年中国红色名录评为“濒危”等级。研究通过研究巨须裂腹鱼早期发育特征, 旨在为该鱼的科学养护提供技术支撑。结果表明: 巨须裂腹鱼受精卵直径3.0—3.2 mm, 遇水开始具有微黏性, 随后脱黏, 经过准备卵裂阶段、卵裂阶段、囊胚阶段、原肠胚阶段、神经胚阶段、器官分化阶段、 孵化阶段, 在水温10℃的条件下, 经过460.67h孵化出来。初孵仔鱼体长9.9—1.1 mm, 心率48—50次/min, 鳃盖骨清晰可见, 下颌原基、尾鳍下骨原基可见。第2天鼻凹出现; 第3天肝胰脏原基出现; 第4天鳃耙、肩带原基出现; 第6天仔鱼上下颌开始张合; 第7天心血管分化结束, 仔鱼开始进入混合营养期; 第14天鳔一室和体侧色素带形成; 第26天肋骨原基出现; 第35天鳔二室出现, 卵黄囊耗尽; 第63天背鳍分化结束; 第83天臀鳍分化结束。巨须裂腹鱼胚胎具有独特的发育时序: 体节的出现先于胚孔封闭, 是对高原环境的一种适应和进化。