Organic Acids and Autolyzed Yeast Reduce the Impact of Pathogens in Fish


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Bacterial threats

Bacteria can survive very well in aquatic environments, especially when water temperatures rise or when farming systems are unbalanced. But these bacteria can cause significant economic losses. Bacteria from the Aeromonas, Edwardsiella, Pseudomonas, Streptococcus, Vibrio and Yersinia genera can all be pathogenic to aquatic animals.

There are many ways to control bacterial disease outbreaks in aquaculture and one of the most common control methods is to use antibiotics. However, a growing awareness of consumers opposing the use of antibiotics in aquaculture production means that some farmers are now banned from selling aquatic products to export markets. The extensive use of such antimicrobials is linked to the development of antibiotic-resistant bacterial strains and the transfer of resistant genes between different bacterial species. The emergence of pathogenic-resistant bacteria has negative impacts, not only on aquaculture, but also on human health. It also negatively affects consumer perception. Therefore, the demand for more environmentally-friendly alternatives is higher than ever. Anti-microbial substances such as organic acids and plant extracts are now commonly used in the fish farming industry. Additionally, other solutions like yeast cell walls can prevent disease by enhancing the innate immune system of fish whereas vaccines only enhance adaptive (acquired) immunity.

Organic acids to control pathogens in fish

Organic acids, or combinations of acids, are an efficient tool for improving growth performance, gut morphology and pathogen control in aquaculture. Recently researchers have focused on the role of organic acids and their salts to prevent and control diseases with great success. They demonstrated, for example, that dietary supplementation with organic salts, such as propionate and butyrate, improved gut morphology under hypoxia and reduced enteritis symptoms (in high soya bean meal diets) in O. niloticus (Tran-Ngoc et al., 2016). Similarly, scientists have demonstrated the very strong anti-microbial effect of organic acids under challenge with Streptococcus agalactiae (Ng et al., 2009) and a high potential to exert beneficial effects on growth, nutrient utilization and disease resistance in tilapia.

While the effects of organic acids on pathogenic bacteria are not yet fully clear, it is commonly understood that they can exert either bacteriostatic or bactericidal effects depending on the physiological status of the organism and the physicochemical characteristics of the environment. Un-dissociated organic acids are lipophilic and can easily bypass the plasma membrane of bacteria. Once inside the cells, where pH levels are usually more neutral than in the outer environment, organic acids dissociate in their anions and protons. Traditionally, it has been assumed that the cytoplasmic pH drop caused by this mechanism is the main toxic efficacy of organic acids. Recently, other toxicity mechanisms have been proposed such as the capability of these acids to interfere with cytoplasmic membrane structure and functionality, as well as interference with nutrient transport, electron transport and macromolecular synthesis inside the cells.

Scientists cultured a number of pathogens in growth medium, with and without the enhanced organic acid Biotronic® Top3 from BIOMIN. The pathogens were chosen based on their ability to cause widespread disease and high economic losses in aquaculture, and included Aeromonas spp., Edwardsiella sp., Pseudomonas sp., Streptococcus sp., Vibrio spp. and Yersinia sp. Researchers observed that Biotronic® Top3 effectively reduced the growth of all pathogens (Figure 1).

Biotronic® Top3 was most effective against Gram-negative pathogens, although inhibition of Streptococcus was also observed. This is not surprising, since the formulation contains a unique BIOMIN® Permeabilizing Complex, specifically designed to weaken the outer membrane of Gram-negative bacteria.

Figure 1. Growth inhibition of aquatic pathogens by Biotronic® Top3
Figure 1. Growth inhibition of aquatic pathogens by Biotronic® Top3

Choosing a science-backed solution

The organic acid market within aquaculture is vast, and choosing the correct solution can be confusing. It is important that products are assessed using both in vitro and in vivo models. A recent peer-reviewed publication demonstrated how Biotronic® Top3, an enhanced acidifier, can be used to reduce pathogens and improve disease resistance in aquaculture (Menanteau-Ledouble et al. 2017).

In one in vivo study, specific pathogen free (SPF) rainbow trout (Oncorhynchus mykiss) were split into two groups, and received either a commercial feed or the same feed supplemented with Biotronic® Top3. After 25 weeks, fish were artificially infected with Aeromonas salmonicida by intraperitoneal (IP) injection, immersion and cohabitation. For quality control purposes, fish in both treatments were also ‘mock’ infected to take into account background mortality. Once the infection had taken its course, the survival rate was calculated (Figure 2). In control tanks, mortalities were observed immediately indicating the virulence of the pathogen. In the Biotronic® Top3 treatments, much slower death rates were seen, indicating that the infection could be slowed down. This may benefit fish farmers as they can identify and treat diseases before incurring huge losses. After 35 days of challenge, Biotronic® Top3 supplemented fish showed a considerably higher survival rate (80%), compared to just 60% in control tanks, indicating the protective capabilities of Biotronic® Top3. Furthermore, the rainbow trout that received Biotronic® Top3 had a significantly higher survival rate (70%) than those not receiving the supplement (25%) when challenged via IP injection.

Figure 2. Survival curves of fish during pathogen challenge. Data represents the average mortality across three infection routes
Figure 2. Survival curves of fish during pathogen challenge. Data represents the average mortality across three infection routes

Autolyzed yeast to enhance marine fish immunity (Lates calcarifer)

The immune system is a set of cellular and humoral components used to defend the body against foreign substances, such as microorganisms, toxins or malignant cells. They respond to factors such as endogenous or exogenous components that stimulate the immune system. The fish immune system is divided into innate and adaptive (memory), both further divided into cell mediated defense and humoral factors (soluble substances). Today, it is known that these systems work together in order to destroy invaders or to trigger defense processes. The innate system includes all components present in the body before the appearance of the pathologic agent and acts as the first line of defense with a faster reaction than the specific system. Among these components are the skin as a physical barrier, the complement system, the antimicrobial enzymes, the interleukins, the interferons and the organic defense cells, such as granulocytes, monocytes, macrophages and natural killer cells (Bayne and Gerwick, 2001; Ellis, 1999; Magnadottir et al., 2011).

Autolyzed yeast (containing the cell walls and available nutrients) is well known in the aquaculture industry to support immune defense mechanisms. Autolyzed yeast consists of concentrations of yeast cells that are allowed to die and break up, so that the endogenous enzymes of the yeast break their proteins down into simpler compounds which are then available for animals (e.g. amino acids, peptides, nucleotides). Autolyzed yeast cell walls contain mannan-oligosaccharides (MOS), β1,3 and β1,6 glucan, chitin and nucleotides. β-glucans are glucose-based polysaccharides that have an immune-stimulant effect in aqua species. They activate several immune cells including macrophages, neutrophils, monocytes, natural killer cells and dendritic cells. MOS have three main modes of action: improvement of gastrointestinal health, modulation of the immune system and pathogen absorption.

Figure 3. Asian seabass (Lates calcarifer)
Figure 3. Asian seabass (Lates calcarifer)

A study was conducted to evaluate the effect of several immune-stimulants in Asian seabass (Lates calcarifer; Figure 3). A total of four treatments were tested: a control (commercial feed), the commercial feed supplemented with Levabon® Aquagrow (autolyzed yeast), the commercial feed supplemented with β-glucan, and the commercial feed supplemented with nucleotides. After eight weeks, fish were artificially infected with Streptococcus iniae by IP injection at 107 CFU/ml. The results showed that in control tanks, the survival rate was only 37% 11 days post-challenge. The treatment containing the autolyzed yeast Levabon® Aquagrow gave the highest survival rate at 57%. Single immune-stimulants (β-glucan and nucleotides) showed an intermediate survival rate of 43% (Figure 4).

Fish fed Levabon® Aquagrow had higher circulating white blood cells (Figure 5). Considering the important protective role leukocytes play, it is not surprising that fish with higher numbers of these immune cells can fight pathogens more effectively, improving survival.

 

Figure 4. Survival rate of Seabass (Lates calcarifer) after S. iniae challenge
Figure 4. Survival rate of Seabass (Lates calcarifer) after S. iniae challenge

Figure 5. Circulating leukocytes (white blood cells) after eight weeks of feeding experimental diets and prior to pathogen challenge
Figure 5. Circulating leukocytes (white blood cells) after eight weeks of feeding experimental diets and prior to pathogen challenge

Conclusion

Disease outbreaks are a persistent threat to the profitability of aquaculture farms. Dietary supplementation with the organic acid blend Biotronic® Top3 can improve survival in trout during a challenge with Aeromonas salmonicida but also inhibits the growth of a wider range of Gram-negative and Gram-positive bacteria pathogens. Acidifiers can improve gut health, increase nutrient utilization by reducing the pathogen load, and increase disease resistance without compromising growth performance.

Additionally, several immune-stimulant substances have demonstrated a positive improvement on the survival rate of Asian seabass after a bacterial disease challenge with Streptococcus iniae. In this study, the autolyzed yeast Levabon® Aquagrow containing the full blend of immuno-stimulants had better efficacy than the single β-glucan or nucleotide application. For aquaculture producers who want to avoid the sub-therapeutic use of antibiotics, Biotronic® Top3 and the autolyzed yeast Levabon® Aquagrow offer an interesting alternative to traditional pathogen control medication, opening the door to higher profitability.

In Brief
  • Antibiotic use in aqua production is falling due to customer demand, but the threat of economic loss from disease is ever present.
  • Alternatives to antibiotics include organic acids, autolyzed yeast and plant extracts.
  • Organic acids have antimicrobial properties, which control and prevent disease.
  • Autolyzed yeast supports the immune defense systems.
  • As shown in trials, Biotronic® Top3 and Levabon® Aquagrow are interesting alternatives to traditional pathogen control medication.

References

Bayne, C.J. and Gerwick, L. (2001). The acute phase response and innate immunity of fish. Dev Comp Immunol. 25(8-9). 725-743.

Ellis, A.E. 1999. Immunity to bacteria in fish. Fish Shellfish Immunol. 9. 291-308.

Magnadottir, B., Audunsdottir, S.S., Bragason, B.T.H., Gisladottir, B., Jonsson, Z.O. and Gudmundsdottir, S. (2011). The acute phase response of Atlantic cod (Gadus morhua): Humoral and cellular responses. Fish Shellfish Immunol. 30. 1124-1130.

Menanteau-Ledouble, S., Krauss, I., Gonçalves, R.A., Weber, B., Santos, G.A. and El-Matbouli, M. (2017). Antimicrobial effect of Biotronic® Top3 supplement and efficacy in protecting rainbow trout (Oncorhynchus mykiss) from infection by Aeromonas salmonicida subsp. salmonicida. Research in Veterinary Science. 114.

Ng, W-K., Koh, C-B., Sudesh, K. and Siti-Zahrah, A. (2009). Effects of dietary organic acids on growth, nutrient digestibility and gut microflora of red hybrid tilapia, Oreochromis sp., and subsequent survival during a challenge test with Streptococcus agalactiae. Aquaculture Research, 40(13). 1490-1500.

Tran-Ngoc, K.T., Haidar, M.N., Roem, A.J., Verreth, J.A.J. and Schrama, J.W. (2016). Effects of feed ingredients on nutrient digestibility, nitrogen/energy balance and morphology changes in the intestine of Nile tilapia (Oreochromis niloticus). Aquaculture. Submitted.

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