Reports

Photoperiod and genetics of growth and maturity in cod (Gadus morhua)

Published:

01/04/2010

Authors:

Guðmundur Óli Hreggviðsson, Ólafur H. Friðjónsson, Þorleifur Ágústsson, Sigríður Hjörleifsdóttir, Kjell Hellman, Filipe Figueiredo, Helgi Thorarensen

Supported by:

Technology Development Fund, The Icelandic Center for Research

Contact

Guðmundur Óli Hreggviðsson

Strategic Scientist

gudmundo@matis.is

Photoperiod and genetics of growth and maturity in cod (Gadus morhua)

One of the main problems of cod farming is premature puberty, which results in slower growth and a much longer rearing period. Preliminary studies carried out in pots on land indicated that a new type of light, the so-called CC light, which emits light of one wavelength (green light) had a much greater effect on growth (up to 60% growth increase) and timing of puberty than conventional halogen light. This study examined the role of genotype and expression of certain key genes in response to light cycles, the determination of premature puberty and the association with increased cod growth in aquaculture. It was investigated whether, body size, weight and premature puberty were familial traits. At the end of a six-month indoor spawning season with two types of lighting, one with white halogen light and the other with continuous CC light, the cod was warlike in sea cages. In the sea cages he was also subjected to different light cycle treatments on the one hand with continuous CC light and on the other hand with natural light. After two years of sea farming, the fish were slaughtered, the phenotype of growth and sexual maturity was determined and it was divided into sibling groups, a total of approx. 2000 fish from each treatment separately. It was found that CCL light had a clear effect on delaying puberty and was much more noticeable in hens. The gonads developed much more slowly and not at all to the full compared to cod raised during the natural light cycle at the same time. There was also some variation between sibling groups in the effect of light on the development of gonads. On the other hand, this delay in puberty did not lead to such a sensitive growth rate. The familial similarity of growth patterns was also examined and a clear difference in mean weight was found between sibling groups. Responses to CCL treatment, however, were very divergent and appeared to vary between sibling groups. CCL treatment appeared to increase growth rate in some groups but slow growth rate in others. This could vary by gender. It was also investigated whether pretreatment of broths with CCL light during the coastal spawning season made the cod more sensitive to the effects of CCL light at sea level. That did not turn out to be the case. Certain key genes in growth and puberty control were isolated, along with some or all of their infiltrates. These were growth hormone (GH) genes, growth hormone receptors, growth hormone releasing factor (GHRF) receptors and insulin-like growth factor receptor2 (IGF2) receptors. In the sequences of three of these genes, GH, GHR and IGF2, variable mutations were found and a method for genetic marking was developed based on these sequences. The effect of light cycles on growth expression was also assessed by measuring the expression of two of these genes, GH and GHR. The relative expression of GHR was not found to be greater in larger fish and no association was found between CCL delayed puberty and GHR expression. GH expression was also examined in fish at sea level. Significant differences in GH expression were measured at only one sampling point, early in the first year in the sea cages in the CCL-treated group. This increase did not occur in the corresponding changes in the staging characteristics of growth and puberty measured at the same time.

Light and photoperiod is a powerful environmental regulator of growth and sexual maturation in fish. Initial studies had indicated that a new type of lights, Cold Cathode ‐ lights (CCL), had much greater effect on growth and sexual development than white halogen light traditionally used in fish farming. In this study we investigated selected candidate gene expression in cod in response to CC ‐ light photoperiod treatment and possible genetic contribution to this response. This effect was evaluated by quantitatively comparing phenotypic traits under the different treatments. On December 2008 (“*”), significant differences were found fish farmed under natural light, in combination with gene expression studies and genotypic family assignments. After hatching the fish was reared from 6 months in indoor tanks under two different light regimes, white halogen light and CC ‐ light. The fish was then transported to sea cages and divided into two groups, one that received continuous CC ‐ light and another that received only natural light treatment. The fish was reared in these sea cages for an additional two years until harvesting. Approximately 2000 individuals from each treatment were genotyped and assigned to different full sib groups. Total body weight, length and gonadal weight were also measured for all individuals. Physiologically, the fish responded clearly to CCL treatment regarding maturity related traits, with less gonadal development in the CCL treated fish. The difference was substantial and the same trend could be observed in all families. The degree of response however differed somewhat between families to some which may signify underlying genetic differences. The effect of CCL treatment on growth related traits was less clear. Apparent growth responses to CCL treatment varied greatly between families and they appeared to be either negative or positive, depending on family and sex. Opposite effects were even observed within families on different sexes. In this project genes associated with growth and maturity were retrieved partly or completely from cod (Gadus morhua). These genes were: Growth hormone (GH), growth hormone receptor (GHR), growth hormone releasing factor (GHR F) and insulin like growth factor 2 receptor (IGF2R). A number of their introns were also obtained and variable microsatellite regions could be identified in intron regions of three of these genes, GH, GHR F, and IGF2R. A method was developed based on the GH and GHR gene sequences to amplify and evaluate expression of these genes in different tissues of cod. GHR expression levels were measured at different sampling points both during the indoor stage where different size groups and treatments were compared and at the outdoor stage where different light treatments were mainly compared. Differences in expression levels between different size groups and between different light treatment groups were insignificant. The light influence is on the GH gene expression, was only observed in the beginning of March early at the sea cage stage and could not be associated with increased growth or delayed reproductive development. The CCL (Cold ‐ Cathode Light) has a single green wavelength that diffuses more effectively throughout the water column than white light. It may therefore mask natural light more efficiently. Still it may be necessary to train fish for the CCL lights and at the indoor stage one half of the juveniles received CCL treatment before transportation to the sea cages. When imprinted and not imprinted were compared negligible difference in gonadal development were, however, observed strongly indicating that prior imprinting to sea cage rearing had no effect.  

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Reports

Development of industrialized cod farming: Control of growth and sexual maturation with advanced lighting equipment / Improved lighting technology for regulating sexual maturation of farmed cod

Published:

01/11/2009

Authors:

Rannveig Björnsdóttir, Jónína Þ Jóhannsdóttir, Jón Árnason, Þorleifur Eiríksson, Cristian Gallo, Böðvar Þórisson, Þorleifur Ágústsson, Björn Þrándur Björnsson, Guðbjörg Stella Árnadóttir

Supported by:

AVS Fisheries Research Fund

Development of industrialized cod farming: Control of growth and sexual maturation with advanced lighting equipment / Improved lighting technology for regulating sexual maturation of farmed cod

The overall goal of the project was to improve farming techniques in cod farming with the use of a new type of light in the goal of controlling the sexual maturity of cod. These are lights that emit a single wavelength that is better distributed over the aqueous phase compared to halogen lights that are traditionally used, and this new type of light has proven to be very effective in preliminary research. It was also investigated whether light control immediately at the juvenile stage could possibly contribute to this effect in the heifer fire. Continuous treatment with the lights at the juvenile stage did not affect the juveniles' growth, but there were indications of fewer growth defects in the juveniles. However, light control at the juvenile stage seemed to have a negative effect on the growth of the fish after transport to sea cages, in addition to which there were many unexplained declines in that group. Light control of fish in cages had a positive effect on the growth of the fish compared to fish kept during the natural light cycle in sea cage farming. The project also developed and standardized new methods for measuring the concentration of growth hormones in cod, and the method proved to be both sensitive and safe. The relationship between growth rate and concentration of growth hormone in the blood of the fish could not be demonstrated in this study, but the method offers great future potential in studies of, for example, the growth rate of wild cod. The project also carried out a detailed study of the effects of seaweed farming on the diversity and species composition of benthic fauna under pens. Extensive changes in the species composition of benthic animals were observed despite a small load associated with fire in the pens over a three-year period.

The overall aim of the project was to improve cod farming technology by delaying sexual maturation of cod by the use of a new lighting technology. The novel lights emit only one wavelength that is more effectively dispersed in water compared to the metal halogen lights traditionally used. Continuous manipulation using the novel light technology during the juvenile stage did not affect fish growth or survival. Indications of reduced frequency of deformities were however observed in this group. Light manipulation during the juvenile stage was further found to negatively affect fish growth following transfer to sea cages and significantly higher unexplained loss of fish was observed in this group. Continuous light manipulation during on growing in sea cages resulted in significantly improved growth of the fish compared with fish exposed to ambient light. New methods were furthermore developed for measuring the concentration of growth hormones in cod. A relationship between fish growth and the concentration of growth hormones could not be established. The method however provides an important tool for future studies of the growth of eg wild cod. Detailed studies of species diversity in bottom layers below the sea cages were also carried out, revealing extensive changes in species composition during the three-year study.

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