Carlo C. Lazado

Mucosal immunity and probiotics in fish

Teleost mucosal immunity has become the subject of unprecedented research studies in recent years because of its diversity and defining characteristics. Its immune repertoire is governed by the mucosa-associated lymphoid tissues (MALT) which are divided into gut-associated lymphoid tissues (GALT), skin-associated lymphoid tissues (SALT), and gill-associated lymphoid tissues (GIALT). The direct contact with its immediate environment makes the mucosal surfaces of fish susceptible to a wide variety of pathogens. The inherent immunocompetent cells and factors in the mucosal surfaces together with the commensal microbiota have pivotal role against pathogens. Immunomodulation is a popular prophylactic strategy in teleost and probiotics possess this beneficial feature. Most of the studies on the immunomodulatory properties of probiotics in fish mainly discussed their impacts on systemic immunity. In contrast, few of these studies discussed the immunomodulatory features of probiotics in mucosal surfaces and are concentrated on the influences in the gut. Significant attention should be devoted in understanding the relationship of mucosal immunity and probiotics as the present knowledge is limited and are mostly based on extrapolations of studies in humans and terrestrial vertebrates. In the course of the advancement of mucosal immunity and probiotics, new perspectives in probiotics research, e.g., probiogenomics have emerged. This review affirms the relevance of probiotics in the mucosal immunity of fish by revisiting and bridging the current knowledge on teleost mucosal immunity, mucosal microbiota and immunomodulation of mucosal surfaces by probiotics. Expanding the knowledge of immunomodulatory properties of probiotics especially on mucosal immunity is essential in advancing the use of probiotics as a sustainable and viable strategy for successful fish husbandry.

Infection-induced changes in expression of antibacterial and cytokine genes in the gill epithelial cells of Atlantic cod, Gadus morhua during incubation with bacterial pathogens.

The molecular processes of immune responses in mucosal tissues, such as the gills, during infection with bacterial pathogens are poorly understood. In the present study, we analyzed the transcriptional profiles of selected antibacterial genes and cytokines in the gills of a cold-water fish, Atlantic cod, Gadus morhua following in vitro infection with bacterial pathogens, Vibrio anguillarum and atypical Aeromonas salmonicida using semi-quantitative RT-PCR. There was significant upregulation in the transcripts of the antibacterial genes: bactericidal permeability-increasing protein/lipopolysaccharide-binding protein (BPI/LBP), g-type lysozyme, transferrin, metallothionein, galectin and hepcidin at 3h post-incubation with the two pathogens. The expression of cathelicidin in the gills was significantly enhanced by A. salmonicida, but not by V. anguillarum. At 24h post-incubation, most of these genes were still significantly upregulated, although some genes returned to their basal expression levels. The transcription levels of cytokines such as interleukin (IL)-1beta, IL-8 and interferon (IFN)-gamma significantly increased at 3h post-incubation with the pathogens. IL-22 and CC-chemokine type 1 transcripts were enhanced by A. salmonicida, but not by V. anguillarum. There was down-regulation of expression in CC-chemokine type-2 and -3 by V. anguillarum, while the expression levels of IL-10 remained unchanged upon infection with either of the two bacterial pathogens. The early upregulation of antibacterial genes in the gills could signal the onset of the acute phase response following bacterial infection and the differential modulation of some cytokine genes could be related to host-pathogen interactions that trigger immune response cascades in mucosal tissues of the host.

Expression profiles of genes associated with immune response and oxidative stress in Atlantic cod, Gadus morhua head kidney leukocytes modulated by live and heat-inactivated intestinal bacteria

The molecular mechanisms of immune response and antioxidant defense in Atlantic cod Gadus morhua head kidney (HK) leukocytes to live and heat-inactivated intestinal bacteria were investigated by transcriptome analyses. The HK leukocytes were incubated with Pseudomonas sp. (GP21) and Psychrobacter sp. (GP12), which are intestinal bacteria of Atlantic cod. The responses of the defense-associated genes at 3 and 24h post-incubation (hpi) were assayed by semi-quantitative RT-PCR. Live and heat-inactivated GP21 caused a significant increase in the transcript levels of bacterial defense genes in the HK leukocytes: BPI/LBP and g-type lysozyme were highest at 24hpi. The levels of BPI/LBP were significantly upregulated at 24hpi by live GP12 but not by the heat-inactivated type. The expression of g-type lysozyme was significantly elevated regardless of the type of GP12. IL-1beta was significantly upregulated by live GP21 and GP12, with maximum expression observed at 3hpi. In contrast, the expression levels of IL-8 in the HK leukocytes were not augmented by both types of GP21 and GP12. A significant upregulation of the non-specific cytotoxic cell receptor protein-1 (NCCRP-1) was observed with live GP12 at 3hpi, whereas in the case of GP21 such a change was noted only with the heat-inactivated type at 24hpi. A definite pattern of granzyme expression was not observed with both the live and heat-inactivated GP21 and GP12. The levels of antioxidant genes (catalase and GSH-Px) remained unchanged except in cells incubated with heat-inactivated GP21, where a significant elevation of GSH-Px was seen at 24hpi. Thus, this in vitro study has revealed that the defense mechanisms in the HK leukocytes can be modulated by the commensal intestinal bacteria of Atlantic cod. The extent of this activation is dependent on the bacterial species and its viability.

Differential expression of immune and stress genes in the skin of Atlantic cod (Gadus morhua).

The present study describes the transcriptional profiles of selected immune and stress genes with putative important roles in the cutaneous immune defense of Atlantic cod (Gadus morhua). In addition it shows differential expression of many genes at the dorsal and ventral sides of fish, in general having the highest expression at the latter side. Genes related to antibacterial activity, antiviral response, cytokine production, glucose transport, stress response and anti-apoptotic activity were monitored and bactericidal/permeability-increasing protein/lipopolysaccharide-binding protein (BPI-LBP), g-type lysozyme, transferrin, metallothionein, fortilin, interferon regulatory factor-1 (IRF-1), a CC chemokine isoform, interleukin-8 (IL-8), glucose transport (GLUT)-1, -3 and -4, Cu,Zn-superoxide dismutase (Cu,Zn-SOD), catalase and hsp 70 showed significantly higher expression at the ventral side. Further g-type lysozyme, metallothionein, fortilin, IRF-1, interferon γ, interleukin-1β (IL-1β), GLUT-3 and -4, catalase and anti apoptotic gene Bcl-X1 were highly expressed in adult cod skin. Therefore fish skin can be considered an immunological active site, especially at the ventral side of Atlantic cod.

In vitro adherence of two candidate probiotics from Atlantic cod and their interference with the adhesion of two pathogenic bacteria

The potential of two candidate probiotic bacteria (GP21 and GP12), isolated from the gut of Atlantic cod, to adhere to primary cultures of the epithelial cells from the different regions of the intestine and to interfere with the adhesion of two pathogens, Vibrio anguillarum and Aeromonas salmonicida subsp. salmonicida were investigated. The intestinal isolates showed clear preference in adhering to the cells from the different intestine segments. GP12 adhered strongly to the fore- and mid intestine cells. The adherence of GP21 was most to the cells from the hind intestine followed by those from the mid-segment. The adhesion of V. anguillarum was affected by both GP21 and GP12; GP12 interfered through competition, but a specific mode of action was not observed for GP21. In the case of A. salmonicida, competition was the principal mechanism by which GP21 interfered with their adhesion, while exclusion mechanism was favoured by GP12. In addition, GP21 was more auto-aggregative than GP12, but the latter was more co-aggregative with both the pathogens. The isolates were also capable of lowering lactate dehydrogenase activity compared to that by the pathogen and they reduced the caspase-3 activity in the epithelial cells from the hind intestine, to which the pathogens adhered the most. Thus it could be concluded that the adhesion of the candidate probiotics is segment-specific and their interference with the adhesion of pathogens is dependent on both source of the epithelial cells and the mechanism adopted by the isolates. This information is novel in the case of fish and the manner in which potential probiotic organisms interfere with the pathogen adhesion provides supportive information for disease control.

Nutritional impacts on fish mucosa: immunostimulants, pre- and probiotics

Preventive health care by dietary manipulation has been regarded as a sustainable approach in modern aquaculture. This strategy is substantiated by remarkable evidence that nutrition is an important modulator of the fish immune system. From a plethora of feed supplements that are being utilized as health promoters in aquaculture, there are three major groups that have generated considerable attention: immunostimulants, prebiotics, and probiotics. These feed supplements vary in their modes of action in fish but their ability to boost not only the innate immunity but also the mucosal immunity positioned them as significant promoters of fish health. This chapter provides the basic concepts of immunostimulants, prebiotics, and probiotics and their contemporary importance in the health and welfare of aquacultured fish. Specifically, this chapter highlights the current understanding of the roles of each substance through dietary administration on the mucosal immunity of fish and provides a platform for the advancement and multi-contextual understanding of these feed supplements in future studies.

Daily Rhythmicity of Clock Gene Transcripts in Atlantic Cod Fast Skeletal Muscle

The classical notion of a centralized clock that governs circadian rhythmicity has been challenged with the discovery of peripheral oscillators that enable organisms to cope with daily changes in their environment. The present study aimed to identify the molecular clock components in Atlantic cod (Gadus morhua) and to investigate their daily gene expression in fast skeletal muscle. Atlantic cod clock genes were closely related to their orthologs in teleosts and tetrapods. Synteny was conserved to varying degrees in the majority of the 18 clock genes examined. In particular, aryl hydrocarbon receptor nuclear translocator-like 2 (arntl2), RAR-related orphan receptor A (rora) and timeless (tim) displayed high degrees of conservation. Expression profiling during the early ontogenesis revealed that some transcripts were maternally transferred, namely arntl2, cryptochrome 1b and 2 (cry1b and cry2), and period 2a and 2b (per2a and per2b). Most clock genes were ubiquitously expressed in various tissues, suggesting the possible existence of multiple peripheral clock systems in Atlantic cod. In particular, they were all detected in fast skeletal muscle, with the exception of neuronal PAS (Per-Arnt-Single-minded) domain-containing protein (npas1) and rora. Rhythmicity analysis revealed 8 clock genes with daily rhythmic expression, namely arntl2, circadian locomotor output cycles kaput (clock), npas2, cry2, cry3 per2a, nuclear receptor subfamily 1, group D, member 1 (nr1d1), and nr1d2a. Transcript levels of the myogenic genes myogenic factor 5 (myf5) and muscleblind-like 1 (mbnl1) strongly correlated with clock gene expression. This is the first study to unravel the molecular components of peripheral clocks in Atlantic cod. Taken together, our data suggest that the putative clock system in fast skeletal muscle of Atlantic cod has regulatory implications on muscle physiology, particularly in the expression of genes related to myogenesis.

Probiotics–pathogen interactions elicit differential regulation of cutaneous immune responses in epidermal cells of Atlantic cod Gadus morhua

Little is known on the cutaneous immune responses during probiotics-pathogen interactions in fish. Thus, this study employed Atlantic cod primary epidermal (EP) cell cultures as a model to understand this interaction. The probiotics-pathogen interactions in the EP cell cultures were elucidated using Vibrio anguillarum 2133 (VA) as the pathogen and two host-derived bacteria (GP21 and GP12) as the probiotics. There was a regional size difference on the EP cells; i.e., EP cells from the dorsal region were significantly larger than the EP cells at the ventral side. VA significantly decreased viability of EP cells. In the presence of probiotics, this inhibition was mitigated. The probiotics reduced VA-induced cellular apoptosis and the probiotics-pathogen interactions influenced cellular myeloperoxidase activity during the latter stage of co-incubation. The probiotics-pathogen interactions triggered differential regulation of immune-related genes and the effects of the interaction were dependent on the region where the cells were isolated and the length of the co-incubation period. In most cases, the presence of probiotics alone showed no significant change on the mRNA level of immune genes in the EP cells but triggered immunostimulatory activity when incubated with VA. This study showed that the virulence of VA in EP cells could be modulated by host-derived probiotics and the immunomodulatory characteristics of the two candidate probionts advanced their immune-related probiotic potential.

In vivo modulation of immune response and antioxidant defense in Atlantic cod, Gadus morhua following oral administration of oxolinic acid and florfenicol

Oxolinic acid and florfenicol are the commonly used antibiotics for the treatment of bacterial diseases in Atlantic cod, Gadus morhua. The changes in selected innate humoral immune response of the fish, bacterial proliferation in serum and transcriptional activity of selected immune and antioxidant defense-related genes following oral administration of these antimicrobial compounds were evaluated. Juvenile cod (75-100 g) were fed commercial feed coated with either florfenicol (10 mg kg(-1) fish, active ingredient) or oxolinic acid (20 mg kg(-1) fish, active ingredient) at a ration of 0.5% body weight for 10 days. Whole blood and serum samples were collected on the 10th day of feeding the antibiotics and at 3, 5 and 10 days after their withdrawal. Serum protein was significantly higher in fish at the 10th day post-withdrawal of both antibiotics. Florfenicol-fed fish had lower myeloperoxidase activity at 3 days post-withdrawal, while there were differential effects on alkaline phosphatase activity. Vibrio anguillarum and Aeromonas salmonicida were significantly reduced in the sera of antibiotics-fed fish until the 5th day post-withdrawal. Florfenicol could inhibit V. anguillarum better than oxolinic acid, while A. salmonicida was more susceptible than V. anguillarum upon treatment with both antibiotics. Furthermore, transcriptional profiles of selected genes related to bacterial defense, inflammation and antioxidant defense were dependent on the type of antibiotics that was administered and the time of sampling. These results indicate that oral administration of antibiotics modulates the immune response and antioxidant defense in Atlantic cod and these may, in turn, affect their ability to resist bacterial pathogens.

Circadian rhythmicity and photic plasticity of myosin gene transcription in fast skeletal muscle of Atlantic cod (Gadus morhua)

The circadian rhythm is a fundamental adaptive mechanism to the daily environmental changes experienced by many organisms, including fish. Myosins constitute a large family of contractile proteins that are essential functional components of skeletal muscle. They are known to display thermal plasticity but the influence of light on myosin expression remains to be investigated in fish. In the present study, we have examined the circadian rhythmicity and photoperiodic plasticity of myosin gene transcription in Atlantic cod (Gadus morhua) fast skeletal muscle. In silico mining of the Atlantic cod genome resulted in the identification of 76 myosins representing different classes, many of which were hitherto uncharacterized. Among the 23 fast skeletal muscle myosin genes, myh_tc, myh_n1, myh_n4, myo18a_2, and myo18b_2 displayed circadian rhythmic expression and contained several circadian-related transcription factor binding sites (Creb, Mef2 and E-box motifs) within their putative promoter regions. Also, the circadian expression of these 5 myosins strongly correlated with the transcription pattern of clock genes in fast skeletal muscle. Under ex vivo conditions, myosin transcript levels lost their circadian rhythmicity. Nonetheless, different photoperiod regimes influenced the mRNA levels of myh_n4, myo18a_2 and myo18b_2 in fast skeletal muscle explants. Photoperiod manipulation in Atlantic cod juveniles revealed that continuous light significantly elevated mRNA levels of several myosins in fast skeletal muscle when compared to natural photoperiod. The daily rhythmicity observed in some fast skeletal muscle myosin genes suggests that they may be under circadian clock regulation. In addition, the influence of photoperiod on their expression implies that myosins may be involved in the photic plasticity of muscle growth observed in Atlantic cod.