Effect of lipid level in a compound diet on the development of red drum (Sciaenops ocellatus) larvae Auteur(s) : Buchet, Vincent Zambonino, Jose-luis Cahu, Chantal Éditeur(s) : Elsevier Résumé : Red drum larvae were fed from day 11 to day 24 post-hatch, with Artemia (LP group) or two isoproteinic-formulated diets with varying lipid levels, 15% (L15 group) and 30% (L30 group). The lipid fraction was composed of a mixture of cod liver oil and soy lecithin. Larvae fed Artemia exhibited the greatest length, L30 diet induced a larvae length significantly greater than that obtained with L15 diet (P < 0,05). No difference was observed in larvae survival among the three dietary groups. The increase in dietary lipid concentration led to an increase in amylase and trypsin secretion levels in 24-day-old larvae. The pancreatic secretion level measured in L30 group was close to that of LP group, suggesting that the maturation of the pancreatic functions was normally developed. Red drum larvae fed the diet containing the higher lipid content (L30) exhibited a more developed brush border membrane digestion in the intestine than larvae fed L15 diet (P < 0.05). Phospholipase A2 was stimulated by the increase of phospholipids in the diet, but no difference was observed for lipase between the two compound diet-fed groups; the LP group exhibited the lowest lipase activity. A plateau in lipase activity may have occurred in red drum larvae from 15% fat level in the diet, suggesting that the maximal lipase activity was reached with 12% neutral lipid in the diet. The positive effects observed with high dietary fat may be due to the phospholipid fraction of the lipid mixture used. Aquaculture (0044-8486) (Elsevier), 2000-04 , Vol. 184 , N. 3-4 , P. 339-347 Droits : 2000 Elsevier http://archimer.ifremer.fr/doc/2000/publication-503.pdf DOI:10.1016/S0044-8486(99)00325-7 http://archimer.ifremer.fr/doc/00000/503/ | Partager |
Ontogeny of the gastrointestinal tract of marine fish larvae Auteur(s) : Zambonino, Jose-luis Cahu, Chantal Éditeur(s) : Elsevier Résumé : Marine fish larvae undergo major morphological and cellular changes during the first month of life. The ontogeny of the gastrointestinal tract combines these two aspects of the larval development and is very interesting in that the timing of functional changes appears genetically hard-wired. The goal of this paper is to give an overview of the gastrointestinal development process in marine fish larvae, with particular attention to three species: sea bass; red drum; and sole, since the description of gut maturation in fish larvae was initiated during the last decade with these species. During the early stages, marine fish larvae exhibit particular digestive features. Concerning the exocrine pancreas, amylase expression decreases with age from the third week post-hatching in sea bass and red drum (approximately 400 degree days), whereas expression of other enzymes (trypsin, lipase, phospholipase A2...) increases until the end of the larva period. Moreover, secretory function of the exocrine pancreas progressively develops and becomes efficient after the third week of life. Concerning the intestine, enzymes of the enterocyte cytosol (in particular peptidase) have higher activity in young larvae than in older. Approximately in the fourth week of post-hatching development in sea bass, red drum and sole larvae, the cytosolic activities dramatically decline concurrently with a sharp increase in membranous enzyme activities of the brush border, such as alkaline phosphatase, aminopeptidase N, maltase... This process characterises the normal maturation of enterocytes in developing fish larvae and also in other vertebrates' species. The establishment of an efficient brush border membrane digestion represents the adult mode of digestion of enterocytes. This paper also describes the role of diet on the development of the gastrointestinal tract. Indeed, the maturational process of digestive enzyme can be enhanced, stopped, or delayed depending on the composition of the diet. Comparative Biochemistry and Physiology Part C: Toxicology & Pharmacology (1532-0456) (Elsevier), 2001-12 , Vol. 130 , N. 4 , P. 477-487 Droits : 2001 Elsevier Science Inc. All rights reserved http://archimer.ifremer.fr/doc/2001/publication-650.pdf DOI:10.1016/S1532-0456(01)00274-5 http://archimer.ifremer.fr/doc/00000/650/ | Partager Voir aussi Proteins Pancreatic enzymes Lipids Larvae feeds Intestinal enzymes Glucides Fish larvae Enzyme expression Digestion Development Télécharger |
Potentiel probiotique de levures productrices des polyamines dans le développement du système digestif du bar Dicentrarchus labrax et de la cabrilla arenera Paralabrax maculatofasciatus Auteur(s) : Tovar, Dariel Éditeur(s) : Co-tutelle Al Centro de Investigaciones Biológicas del Noroeste - Université de Bretagne occidentale Résumé : The interest in probiotics for aquaculture is increasing rapidly. In the present work we evaluated the potential of some yeast to induce the larvae gut maturation in sea bass larvae Dicentrarchus labrax. The production of polyamines putrescine, spermidine and spermine was quantified in ten yeast strains using high performance liquid chromatography (HPLC). Afterwards, fluorescently labelled yeast adhesion to the intestine of sea bass larvae and the spotted sand bass (Paralabrax maculatofasciatus) was evaluated by fluorescent microscopy. Two of them, CBS 8339 strain (Debaryomyces hansenii) and X2180 strain (Saccharomyces cerevisiae) produce the polyamines of our interest. The same strains showed the best adhering capabilities to the sea bass and spotted sand bass intestine. Both strains were selected and introduced by pulverization into the diet of larvae. The larvae fed with CBS 8339 strain, increase survival in 8.3% but not in their weight. The secretion of trypsin and amylase as well as those from the brush border membrane: alkaline phosphatase, maltase and leucine aminopeptidase, are incresed at 27 days after hatching (dah). At 42 dah difference in the enzyme activity of the different groups does not exist, suggesting a maturation of the digestive system in early stages of larval development. A second experiment was carried out to know the effect of different levels of incorporation into the diet of CBS 8339 strain: 1.1% and 5.7%. The minimum level, 1.1% of yeast produce best growth and survival rates, as well as lower deformed larvae than those obtained by 5.7% and the control one. Both level of yeast inclusion favored the trypsin secretion and lipase activity at 26 dah. Whereas mRNA levels for trypsin and amylase were influenced by both yeast concentrations at 26 and 36 dah, which suggest a development of digestive capacity of larvae as a result of the presence of polyamines secreted by the yeast. Les probiotiques ont été définis comme des préparations microbiennes vivantes utilisées comme additif alimentaire, et qui ont une action bénéfique sur l'animal hôte en améliorant la digestion et l'hygiène intestinale. L'application de tels traitements aux productions aquacoles suscite un intérêt qui s'accroît rapidement. Dans ce travail, nous avons étudié l'effet de souches de levures sur la maturation de l'intestin des larves du bar Dicentrarchus labrax. Ces souches produisent des polyamines qui sont impliquées dans la réplication et la différentiation cellulaire, ainsi que dans la synthèse des protéines et des acides nucléiques. Dix souches de levures ont été testées pour leur production de polyamines (putrescine, spermidine et spermine), et pour leur adhérence à la paroi intestinale du bar et la cabrilla (Paralabrax maculatofasciatus). La production des polyamines a été analysée en utilisant la chromatographie liquide à haute performance (HPLC). Les levures selectionées ont été marquées avec un composé fluorescent pour tester leur adhérence a l'intestin de larves de bar et de juvéniles de cabrilla. L'adhérence a pu ainsi être evaluée par observation microscopique en épifluorescence. Les souches CBS 8339 (Debaryomyces hansenii) et X2180 (Saccharomyces cerevisiae) ont été choisies pour leur forte production de spermidine et de spermine, respectivement, et pour leur capacité d'adhérence à l'intestin du bar et de la cabrilla. Les deux souches ont été ajoutées par pulvérisation au régime des larves. Nous avons observé une augmentation de 8.3% du taux de survie avec les larves alimentées avec la souche CBS 8339, mais le poids moyen de ces larves était inférieur à celui obtenu sans ajout de levure. Une augmentation de l'activité de la trypsine et de l'amylase, aussi bien que des activités enzymatiques dans la bordure en brosse, aminopeptidase, phosphatase alkaline et maltase, ont été observées dans les larves âgées de 27 jours alimentées avec la souche CBS 8339. Au jour 42, il n'existait plus de différence d'activité enzymatique entre les larves traitées ou non avec la levure. Ces résultats suggèrent que la maturation du système digestif a été accélérée chez les larves nourries avec la levure, la maturation étant achevée chez les larves de 42 jours, qu'elles aient reçu l'un ou l'autre régime. Une deuxième expérience a été effectuée pour étudier l'effet de différents niveaux d'incorporation dans le régime contenant 1,1% et 5,7% de levure CBS 8339. L'incorporation de 1,1% a induit une augmentation du poids moyen et du taux de survie des larves, ainsi qu'une réduction du taux de malformation de la colonne vertébrale, par rapport aux résultats obtenus avec 0 ou 5,7% de levure. Les deux niveaux d'incorporation de la levure ont favorisé l'activité de la trypsine et de la lipase au jour 26. Les niveaux d'ARNm codant pour la synthèse de la trypsine et de l'amylase ont été influencés par les deux doses de levure aux jours 26 et 36. Ces résultats suggèrent qu'une faible dose de levure améliore le développement et la capacité digestive des larves, et nous formulons l'hypothèse que cette efficacité est due à la production de polyamines in situ. Le rôle des polyamines est particulièrement important pendant les phases de forte croissance comme les stades larvaires, mais elles peuvent être toxiques à dose trop élevée. L'incorporation de levure dans l'aliment destiné aux larves semble donc une excellente méthode pour délivrer les polyamines chez l'animal hôte. Droits : info:eu-repo/semantics/openAccess http://archimer.ifremer.fr/doc/2002/these-103.pdf http://archimer.ifremer.fr/doc/00000/103/ | Partager Voir aussi Ontogeny Digestive enzymes Fish larvae Polyamines Probiotics Ontogénèse Enzymes digestives Larves de poisson Polyamines Probiotiques Télécharger |
Substitution of live food by formulated diets in marine fish larvae Auteur(s) : Cahu, Chantal Zambonino, Jose-luis Éditeur(s) : Elsevier Résumé : Until recently, it was considered impossible to feed newly hatched marine fish species with a compound diet. Substituting a compound diet for live prey was performed several weeks after hatching, depending on the species. Compound diets were well ingested at the early stage but larvae died with a gut full of food, suggesting that larvae were unable to digest the compound diet. The hypothesis was that younger larvae have insufficient digestive enzymes to thrive on compound diets, and that exogenous enzymes, provided from live prey, are necessary for early stages.The organogenesis of marine fish larvae is not completely achieved at hatching and histological studies have revealed that the anatomy of the digestive tract undergoes developmental changes over some weeks. Nevertheless, biochemical studies over 20 years have shown that most of the digestive enzymes are present in young larvae. Recent studies have provided better understanding of digestion mechanisms in larvae and have led to proposed dietary compositions meeting larvae nutritional requirements. Pancreatic digestive enzymes are detected before mouth opening. Their synthesis is not induced by diet ingestion, but secretory mechanisms in the pancreas, and so enzymatic action, become efficient chronologically after those of synthesis. Inadequate diets can delay the onset of secretion mechanisms. The ratio of secreted enzymes to total enzymes indicates the nutritional value of the diet ingested by the larvae.At the intestinal level, cytosolic enzymes, which are peptidases, exhibit high activity in the early stages, suggesting a high capacity in larvae to digest protein hydrolysate. Indeed, larvae growth and survival is improved by the incorporation of a moderate concentration of peptide or hydrolysate in the diet. Peptidase activity abruptly decreases around day 25 in sea bass, concurrent with an increase in enzymes of the brush border membranes. This corresponds to a normal maturation process of enterocytes. Compound diets can slightly delay the onset of this maturation process, and inadequate diet can prevent it, leading to near death of the larvae. A proper onset of the maturation process has been associated with high larvae survival.The early developmental stage larvae exhibit high hydrolytic capacity, related to their weight. Enzyme activity pattern is age-dependent, but can be modulated by diet composition. Thus, larvae have the ability to digest and thrive on compound diet, if this diet is well adapted. Larvae have different specificities in digestion and nutritional requirements when compared to juveniles. Taking these specificities into consideration, recent research has led to the formulation of a compound diet that was well adapted for larvae from mouth opening, and could totally replace live prey. Aquaculture (0044-8486) (Elsevier), 2001-08 , Vol. 200 , N. 1-2 , P. 161-180 Droits : 2001 Elsevier Science B.V. All rights reserved http://archimer.ifremer.fr/doc/2001/publication-447.pdf DOI:10.1016/S0044-8486(01)00699-8 http://archimer.ifremer.fr/doc/00000/447/ | Partager Voir aussi Protein Phospholipid Pancreatic enzymes Microparticulate diet Intestinal enzymes Protein hydrolysate Gut maturation Fish larvae Télécharger |