Evaluation of Probiotics Solutions in Shrimp Aquaculture and Their Effectiveness Against Acute Hepatopancreatic Necrosis Disease Caused By Vibrio parahaemolyticus Strain A3

Pinoargote, Gustavo, Pinoargote, Gustavo

January 2017

As the demand for farmed shrimp continues to grow worldwide, the use of probiotics to address the sustainability of aquaculture fisheries has gained much attention. Emerging diseases in shrimp aquaculture, such as acute hepatopancreatic necrosis disease (AHPND), have devastating economic impacts in countries that largely depend on this activity. The relevance of this research lies on the fact that it explores the potential of using probiotics to mitigate the negative effects of AHPND in shrimp aquaculture. The scope of these studies includes survival of probiotic microbes in typical aquaculture water conditions, the effectiveness of probiotics in vitro and in vivo against the pathogenic strain of Vibrio parahaemolyticus that causes AHPND, and the effects of probiotics on the bacterial community composition in aquaculture water and gastrointestinal tract of shrimp after an induced AHPND infection. The microorganisms chosen as probiotics for this research include a lactic acid bacterium, a yeast and a photosynthetic bacterium. Informal feedback from shrimp farmers in Thailand and Vietnam revealed positive results against AHPND when using a commercially available probiotic containing multiple species of microorganisms from these probiotic groups. This research was divided into four studies. The first study (Chapter 2) evaluated the growth of the three different probiotic microbes in two different salinity conditions commonly found in intensive shrimp production systems to determine whether they could be further considered as potential candidates. The hypothesis was that the NaCl concentrations of the media may not have an effect on acid production, growth and cell morphology of the microorganisms being evaluated due to their metabolic mechanisms of adaptation to differences in osmotic pressure. The probiotic microbes were cultured in nutrient media enriched with 1 and 2% NaCl. Microbial survival, acidity and cell morphology between treatments were compared using enumeration by serial dilutions and plating, pH measurements and scanning electron microscopy imaging, respectively. The results showed that salinity levels up to 2% NaCl did not affect the growth of lactic acid bacteria and yeast. Photosynthetic bacteria grown in media with 1% NaCl showed a 24-hour delay in comparison to the control and a prolonged lag phase that lasted 48 hours when the media contained 2% NaCl. Therefore, the hypothesis was partially supported. Based on these results, all three probiotic microbes demonstrated to be suitable for application in aquaculture ponds with up to 2% salinity. The second study (chapter 3) aimed at determining the inhibitory effects of eight different formulations of probiotic solutions against the pathogenic strain of V. parahaemolyticus in vitro. The hypothesis of this study was that probiotic solutions containing whole microbial cultures of multiple microbial types including lactic acid bacteria may have a greater inactivation of the pathogen. The probiotic formulations consisted of individual cultures, combinations of the three probiotic microbes, and a commercially available probiotic formulation. The inhibitory effects were evaluated following a disk diffusion test on solid media by comparing diameters of zones of inhibition, and a challenge test in liquid media by comparing pathogen survival after exposure to probiotic solutions. Findings revealed inhibition zones with greater diameters in disks treated with whole microbial cultures (min: 7.83 mm, max: 11.33 mm) versus disks treated with only supernatants (min: 7.00 mm, max: 8.50 mm). Results from the challenge in liquid media tests showed greater inactivation of the pathogen after 48 h (6.56±0.07 to 5.43±0.03 log10 reduction) when treated with lactic acid bacteria alone and in combination with other microbial types. From these results, the hypothesis was supported and it was concluded that probiotic solutions including a lactic acid bacterium, the combination of lactic acid bacterium and photosynthetic bacterium and the combination of lactic acid bacterium, yeast and photosynthetic bacterium may be used to effectively inhibit AHPND in shrimp aquaculture. The third study (chapter 4) explored the effects of probiotic solutions on live shrimp (Litopenaeus vannamei) pretreated with probiotics for 7 days prior to challenging them with the pathogenic V. parahaemolyticus strain causing AHPND. The hypothesis of this study was that higher shrimp survival and weight gains would be observed when shrimps are exposed to probiotics solutions with multiple microbial types in the water and feed. Water quality parameters (dissolved oxygen, temperature, acidity, salinity and total ammonia nitrogen), difference in shrimp weight increase and shrimp survival were compared between probiotic treatments and controls. Treatments included: (1) a lactic acid bacterium alone (Pro.Sol1), (2) a lactic acid bacterium and a photosynthetic bacterium (Pro.Sol2), (3) the combination of a lactic acid bacterium, a yeast, and a photosynthetic bacterium (Pro.Sol3), and (4) a commercial probiotic (Com.Pro) and the results showed shrimp survival of 11.7, 26.7, 36.7 and 73.3%, respectively. Also, treatments Pro.Sol3 and Com.Pro resulted in higher weight gains (19.7 and 31.2%, respectively) versus the negative control (11.2%). Moreover, onset of the disease was delayed in all treatments as follows: 12 h with Pro.Sol1, 20 h with Pro.Sol2, 22 h with Pro.Sol3, and 26 h with Com.Pro. From these results, the hypothesis was supported and it was concluded that probiotics have the potential to effectively mitigate the effects of AHPND in the shrimp aquaculture. Finally, the fourth study (chapter 5) evaluated the effects of probiotics on the bacterial diversity of the gastrointestinal tract of shrimp as well as variation of bacterial and fungal diversity in the water before and after challenging shrimp with the pathogenic V. parahaemolyticus strain causing AHPND. The hypothesis of this study was that probiotic solutions with multiple microbial types may be able to maintain the microbial composition of the shrimp GI tract and aquaculture water preventing an increase in relative abundance of the family Vibrionaceae. Next generation sequencing was conducted using an Illumina MiSeq™ and primers specific for bacterial V4 hypervariable region of the 16S rRNA gene. The results obtained from the GI tract of shrimp revealed that the relative abundance of the family Vibrionaceae significantly increased in treatments with high mortalities, whereas treatments with higher survivals showed no significant difference in relative abundance of Vibrionaceae family members (P>0.05) in comparison to the negative control. The Shannon diversity index values (abundance and evenness) of the bacterial communities revealed that the treatment with the highest survival had the highest Shannon index value (4.69±0.133) whereas the treatment with lowest survival had the lowest Shannon index value (0.17±0.004). The results obtained from water samples did not show a higher abundance of the family Vibrionaceae, and diversity was maintained after infection (Shannon index 4.64±0.58). Regarding fungal diversity in water samples, Shannon index values revealed no significant changes before (3.627±0.37) and after infection (3.664±0.18) except for Pro.Sol3 (2.859±0.56) and Com.Pro (1.795±0.50), which included yeast in their formulation. Thus, the hypothesis of this study was partially supported since the results revealed that while all probiotics maintained the diversity of microbial composition in the water, only those probiotic solutions with various microbial types in the formulation maintained the diversity of the microbial composition in the GI tract of shrimp providing protection against AHPND.

Acute Hepatopancreatic Necrosis Disease

Lactic Acid Bacteria

Photosynthetic bacteria

Probiotics

Shrimp Aquaculture

Yeast

The Influence of Prebiotics, Probiotics, and Exposure to an Opportunistic Pathogen on the Intestinal Microbiome of White Shrimp (Litopenaeus vannamei)

Kesselring, Julia Jiang Hao

13 June 2022

Prebiotics and probiotics, proposed alternatives to antibiotics in shrimp aquaculture, are reported to improve growth parameters, promote disease resistance, and influence the gut microbial community. This study aimed to investigate the influence of prebiotic- or probiotic-coated feed and/or exposure to the Early Mortality Syndrome-causing strain of Vibrio parahaemolyticus ( VP-EMS) on the mid and hindgut microbiome of Pacific white shrimp (Litopenaeus vannamei). A monoculture probiotic strain of Bacillus subtilis spores: O14VRQ, and a prebiotic product of cultured Saccharomyces cerevisiae cell walls: MOS, were administered to shrimp as feed additives for 14 days, before a pathogen challenge to VP-EMS. Based on previous efforts, animals in this study were fed experimental diets for 14 days to allow ample amount of time for the prebiotic to be metabolized by health-promoting bacteria and for the probiotic spores to germinate. The pathogen challenge consisted of negative disease control (no VP-EMS exposure, commercial feed), positive disease control (VP-EMS exposure, commercial feed) and two treatment groups, probiotic (VP-EMS exposure) and prebiotic (VP-EMS exposure). DNA extraction, 16S rRNA gene amplicon sequencing, polymerase chain reaction (PCR), and sequencing were utilized to create an overview of the mid and hindgut microbial composition. No significant differences in survival were shown between experimental diets following exposure to sublethal levels of VP-EMS. Bioinformatic analyses revealed no distinct shifts in the mid and hindgut microbiome of shrimp across experimental diets and time points. Results of this data revealed that dominant members of the intestinal microbiome, Proteobacteria, Actinobacteriota, Bacteroidota, Verrucomicrobiota, Flavobacteriaceae, Demequinaceae, Vibrionaceae, Shewanellaceae, Rhodobacteriaceae, and Rubritaleaceae were relatively stable across treatments and time points. Sequencing methods such as metagenomics or metatranscriptomics should be utilized for a higher microbiome resolution. Furthermore, the use of quantitative polymerase chain reaction to quantify ingested probiotic spores, prebiotic-associated bacteria, and VP-EMS is recommended. / Master of Science in Life Sciences / Shrimp aquaculture is one of the fastest-growing aquaculture sectors that provides another supply of feed that save wild fish populations. The use of prebiotics and probiotics are reported to improve growth, provide disease protection, influence the gut community, improve the immune system, and serve as substitutes to antibiotics. In this study, the effect of probiotic-, or prebiotic-coated diets and/or exposure to the Early Mortality Syndrome-causing Vibrio parahaemolyticus (VP-EMS) strain on the gut communty of shrimp (Litopenaeus vannamei) was investigated. DNA extraction, 16S rRNA gene amplification, and sequencing were utilized to identify the microbes in the intestines of shrimp. Based on previous studies, animals in this study were fed experimental diets for 14 days to allow enough time for prebiotic-associated bacteria and probiotic spores to multiply within the intestines. Exposure to a sublethal level of VP-EMS did not significantly affect shrimp survival between treatments. Analyses showed no noticeable differences in the intestinal microbial communities between treatments and time points. This research provided initial proof of what microbes occupy the mid and hindgut microbiome. A higher resolution sequencing method is recommended to gain a better understanding of the microbes and their roles in the intestines. The use of quantitative polymerase chain reaction is warranted to evaluate the amount of ingested probiotic spores, prebiotic-associated bacteria, and VP-EMS.

Vibrio parahaemolyticus

Early Mortality Syndrome (EMS)

Bacillus subtilis

Saccharomyces cerevisiae

intestinal microbiome