Dietary histidine requirement to reduce the risk and severity of cataracts is higher than the requirement for growth in Atlantic salmon smolts, independently of the dietary lipid source.

The present study was carried out to investigate whether the dietary histidine requirement to reduce cataract development is higher than that for growth in Atlantic salmon smolts (Salmo salar L.) after seawater transfer and whether dietary vegetable oils contribute to cataractogenesis. Duplicate groups of salmon smolts were fed ten experimental diets with either fish oil (FO) or a vegetable oil (VO) mix replacing 70 % FO and histidine at five target levels (10, 12, 14, 16 and 18 g His/kg diet) for 13 weeks after seawater transfer. The VO diet-fed fish exhibited somewhat inferior growth and feed intakes compared with the FO diet-fed fish, irrespective of the dietary histidine concentration. Both cataract prevalence and severity were negatively correlated with the dietary histidine concentration, while lens N-acetyl-histidine (NAH) concentrations were positively correlated with it. The fatty acid profiles of muscle, heart and lens reflected that of the dietary oils to a descending degree and did not affect the observed cataract development. Muscle, heart and brain histidine concentrations reflected dietary histidine concentrations, while the corresponding tissue imidazole (anserine, carnosine and NAH) concentrations appeared to saturate differently with time. The expression level of liver histidase was not affected by the dietary histidine concentration, while the liver antioxidant response was affected in the VO diet-fed fish on a transcriptional level. The lowest severity of cataracts could be achieved by feeding 13·4 g His/kg feed, independently of the dietary lipid source. However, the present study also suggests that the dietary histidine requirement to minimise the risk of cataract development is 14·4 g His/kg feed.

Susceptibility of Atlantic salmon lenses to hydrogen peroxide oxidation ex vivo after being fed diets with vegetable oil and methylmercury.

The development of cataract in farmed Atlantic salmon (Salmo salar L.) has been related to changes in feed composition resulting in sub-optimal lens nutrition. The present study was performed to investigate the ability of Atlantic salmon lenses to withstand oxidative stress ex vivo, with focus on the nutritional lipid history and exposure to methylmercury (MeHg) as a relevant dietary contaminant. Since dietary histidine has been shown to have a mitigating effect on the prevalence of cataract in farmed salmon, the antioxidative abilities of histidine and NAH, a major imidazole in the salmon lens, was also investigated ex vivo. Lenses from Atlantic salmon prefed diets based on either fish oil (FO) or vegetable oil (VO) as lipid source, with or without addition of 5 mg MeHgkg(-1) feed, were cultured for 96 h in normal medium (control), medium added 5 mM H(2)O(2) or in histidine enriched medium. Lipid class composition of the lenses was not affected by the dietary lipids; while VO fed fish had a decrease in lens n-3/n-6 fatty acid ratio due to minor but significant increase in the concentration of 18:2 n-6 and 20:4 n-6, and decrease in 20:5 n-3 fatty acids compared to FO fed fish. The lenses accumulated mercury in response to dietary levels, but neither the oxidative status nor any physiological responses were affected. The cultured lenses responded to H(2)O(2) exposure with loss of transparency, accumulation of auto-fluorescent compounds, volume increase and reduced glutathione concentration similarly and irrespective of the dietary history. Lenses extracted histidine from the media, and synthesised NAH during the culture period. The innate antioxidative defence system appeared to be influenced both by the dietary lipid history and histidine enrichment on a transcriptional level. Catalase and SPARC were expressed higher in lenses from FO fed fish, and glutaredoxin showed elevated expression levels in FO lenses cultured in histidine enriched medium, suggesting that histidine is related to the innate antioxidant defence in salmon lenses. Further, the concentration of NAH was significantly reduced in oxidatively stressed lenses. Based on the results from this study it is suggested that NAH has a novel role as antioxidant in the Atlantic salmon lens.

Dietary histidine supplementation prevents cataract development in adult Atlantic salmon, Salmo salar L., in seawater.

The aim of the present study was to investigate the cataract preventive effect of dietary histidine regimes in adult Atlantic salmon (Salmo salar L.) in seawater, both through manipulating the dietary histidine level and feeding period. Mean body weight of individually tagged Atlantic salmon at the start of the experiment was 1662 (sd 333) g. Low prevalence of mild cataracts were recorded in the beginning of June. Three fishmeal and fish oil-based extruded diets (crude protein: 375 g/kg and fat: 342 g/kg), differing only in histidine content (low (L): 9.3, medium (M): 12.8 and high (H): 17.2 g histidine/kg diets), were fed to duplicate net pens in seawater. The experimental period was divided into three seasons (June-July; July-September; September-October), each starting and ending with individual cataract examination, assessment of somatic data, and sampling of lens and muscle tissues for analysis of histidine and histidine derivatives. In July and September, a part of the population fed L- and H-histidine feeds were transferred (crossed over) to respective series of replicate net pens fed L-, M- and H-histidine diets (i.e. eleven experimental feeding groups at trial conclusion). The fish doubled their body weight from June to October, with no systematic effects on weight gain of dietary histidine feeding regimes. Development of severe cataracts was observed between July and September. The cataract severity was directly related to the dietary histidine level fed during the first and second periods. Feeding histidine-supplemented diets (M or H) in the first period from June to July mitigated later cataract outbreaks. The status of selected free imidazoles in muscle and lens tissues reflected the dietary histidine feeding regimes, relative to both feed concentration and feeding duration. The study shows the risk for cataract development for adult Atlantic salmon, 1 year after the transfer of salmon smolts from freshwater to seawater, which to a major extent can be prevented by histidine supplementation just before and during the early phase of cataract development.

Histidine nutrition and genotype affect cataract development in Atlantic salmon, Salmo salar L.

The aim of this study was to investigate effects of dietary levels of histidine (His) and iron (Fe) on cataract development in two strains of Atlantic salmon monitored through parr-smolt transformation. Three experimental diets were fed: (i) a control diet (CD) with 110 mg kg(-1) Fe and 11.7 g kg(-1) His; (ii) CD supplemented with crystalline His to a level of 18 g kg(-1) (HD); and (iii) HD with added iron up to 220 mg kg(-1) (HID). A cross-over design, with two feeding periods was used. A 6-week freshwater (FW) period was followed by a 20-week period, of which the first three were in FW and the following 17 weeks in sea water (SW). Fish were sampled for weighing, cataract assessment and tissue analysis at five time points. Cataracts developed in all groups in SW, but scores were lower in those fed high His diets (P < 0.05). This effect was most pronounced when HD or HID was given in SW, but was also observed when these diets were given in FW only. Histidine supplementation had a positive effect on growth performance and feed conversion ratio (P < 0.05), whereas this did not occur when iron was added. Groups fed HD or HID had higher lens levels of His and N-acetyl histidine (NAH), the latter showing a marked increase post-smoltification (P < 0.05). The HD or HID groups also showed higher muscle concentrations of the His dipeptide anserine (P < 0.05). There was a strong genetic influence on cataract development in the CD groups (P < 0.001), not associated with tissue levels of His or NAH. The role of His and His-related compounds in cataractogenesis is discussed in relation to tissue buffering, osmoregulation and antioxidation.