Abstract
Melatonin is a hormone synthesized and secreted by the pineal gland. Its production is regulated by
daylength with increasing amounts of the hormone being produced in the autumn and winter, as daylight hours decrease.
Melatonin has become the newest craze on the U.S. health supplement market and has been described as a panacea for many
human ailments. Research in the last decade has elucidated immunoregulatory properties of this hormone in human and rodent
studies. In human medicine, melatonin has several clinical applications for enhancing the immune response against certain
types of cancer. Field and laboratory studies of mammals have shown that seasonal changes can affect various immune
parameters. It has been suggested that melatonin serves to up-regulate the immune system in temperate climates as a natural
defense against higher energetic demands and seasonal hardships associated with the winter months. There has been no
research to date investigating whether melatonin could alter immune parameters of fish, although there are a few reports
indicating that seasonal changes can affect fish immune responsiveness. This study showed increased innate immune responses
for extracellular O2 and lysozyme and near significant increases in phagocytosis, survival, and antibody titers
in melatonin implanted fish compared to control fish. If melatonin is shown to enhance the immune response of fish, this
hormone may also prove beneficial for the aquaculture industry. Some practical applications would be to prevent disease
related losses, either as an immunomodulator in commercial fish feeds and/or as a vaccine adjuvant, boosting overall immune
responses against specific aquatic pathogens.
Introduction
Zapata13 reviewed seasonal variation of immune function in several poikilotherm animals,
failing to find any consistent trends linking season with immunity for ectotherms. Steroid hormones in poikilotherms down
regulated immune function similar to observations in homeotherms. There has been no specific investigation to date examining
the effects of photoperiod or melatonin on the immune response of these animals. Reviewing an entire group as diverse as the
poikilotherms, does not account for the myriad of differences between and within classes. Phylogenetic differences between
cyprinids and salmonids are greater than differences between rodents and primates.
Seasonal trends in immune function have been reported in some fish. Earlier records of disease
occurrence and mortalities in wild fisheries have been based on an individual fish species or pathogen.11,12 More
recent work has elaborated on the general function of the immune system with regard to seasonal changes. Collazos et
al.1-4 reported seasonal variations in hematologic parameters, immune parameters, and immune function in the
tench (Tinca tinca), and Hutchinson and Manning5 observed seasonal trends in lysozyme activity in dab
(Limanda limanda) from Lyme Bay, U.K. Research investigating seasonal effects on basic immune function may ultimately
serve to advance our understanding of the epidemiology of specific fish pathogens.
Methods and Results
Three hundred female rainbow trout were divided into two experimental groups; each consisting of three
replicates (ca. 50 fish/replicate). The fish were maintained at 12°C in an outdoor recirculating system under ambient
photoperiod. One group was implanted with constant-release melatonin implants (Regulin; Hoechst UK Ltd.), while the other
group received a sham-operation but no implant. Fish were sampled for immunologic analysis at 3 and 6 wk post melatonin
implantation and subjected to bacterial challenge 10 wk after implantation.
Melatonin Levels
A radioimmunoassay was used to assess the level of melatonin in the plasma of implanted fish and
control fish. As measured post implantation, the treated group had levels of melatonin 3-4 times typical of night-time
values compared with the normal daytime values observed in the control group at week three and week six.
Cellular Components of the Innate Immune Response
Detection of the Superoxide Anion
The following two assays were used to quantify the intensity of macrophage respiratory burst
activity.10
Intracellular O2 was detected by dissolving insoluble formazan that was produced by the
reduction of the dye nitroblue tetrazolium (NBT). Although the group receiving melatonin implants exhibited a slightly
higher production of intracellular O2, the differences were not significant.
Extracellular O2 was measured using a solution of ferricytochrome c. The difference, between
phorbol myristate acetate (PMA) stimulated cells and unstimulated cells, was significantly higher (P < 0.05) for
the melatonin-implanted group compared with the control group at 3 wk post-implant (Table 1). There was no significant
difference between the melatonin implanted and control fish at 6 wk post-implantation, although a slight increase in
extracellular O2 was observed in the control group.
Phagocytosis Assay
Phagocytosis of yeast by head kidney macrophages isolated from experimental fish was assessed 6 wk
after melatonin implantation. Yeast were used for phagocytosis at 6 wk and media alone was used as a negative control. The
melatonin-implanted group had both a higher phagocytic ratio and index (Table 2), indicating, respectively, that there were
a higher percentage of phagocytosing macrophages and a larger number of phagocytosed yeast particles. However, neither of
these differences was statistically significant. The control group had a standard deviation twice that of the treatment
group for the phagocytic ratio.
Lysozyme
The ability of plasma lysozyme to degrade Micrococcus lysodeikticus was measured using
spectrophotometry at both 3 and 6 wk post implantation. The data were statistically analyzed and results indicated in Table
3. At 3 wk, post-implantation lysozyme values for melatonin-implanted and control fish appeared nearly identical, but
lysozyme was significantly higher (P < 0.05) in the treated group compared with the control group at 6 wk post
melatonin implant (Table 3).
Bacterial Challenge and ELISA
The fish were artificially challenged with Vibrio anguillarum and percent survival determined.
These were calculated from pooled replicates (note that only two replicates were pooled for the melatonin-implanted group,
because the third replicate was lost due to a system malfunction just prior to bacterial challenge):
Control: Pooled % survival =
(27+26+34)/(34+36+39)= 87/109 = 79.82%; SE = 0.0386
95% CL = 0.0757; Upper 95% CL =
87.39%; Lower 95% CL = 72.25%
Melatonin Treated: Pooled %
Survival = (32 + 28)/(36+32) = 60/68 = 88.24 %; SE = 0.0394
95% CL = 0.0771; Upper 95% CL =
95.56%; Lower 95% CL = 80.53%
Levels of antibodies against Vibrio anguillarum, which were elicited by fish 3 wk
post-challenge, were determined using ELISA (Table 4).
Discussion
This study provides the first reported data on the effects of melatonin on immunoregulation in fish.
In the last decade, literature relating to the effects of melatonin on the immune response of humans has expanded greatly.
Numerous articles report the immunoregulatory effects of melatonin, from triggering novel opioid peptides that activate
T-cells,6 to enhancing the production of tumor necrosis factor.9 Although fish are poikilotherms they
share many of the same cellular and humoral immune components seen in mammals. Melatonin is a widely conserved molecule
found in single alga, edible plants, invertebrates and vertebrates.8 If ontogeny recapitulates phylogeny, than
certainly melatonin may arbitrate similar mechanisms across vertebrate phyla.
This study attempted to elucidate the effects of melatonin on the immune response of rainbow trout
(Oncorhynchus mykiss). Several parameters of both cell-mediated and humoral components of the non-specific immune
system, as well as humoral components of the specific immune response, were assayed, comparing melatonin-implanted fish with
control fish. In comparison with control fish, melatonin-implanted fish had significantly higher values for both the
cytochrome c assay at 3 wk post-implant and lysozyme activity at 6 wk post-implant. There was a near-significant increase in
phagocytic ratio at 6 wk post-implant, and a tendency towards increased survival and enhanced humoral antibody responses
post Vibrio challenge.
In conclusion, these findings provide the first evidence that melatonin may enhance the immune system of
rainbow trout, acting to stimulate bactericidal activity and eventually leading to stronger adaptive responses. These
results and their significance provide a foundation for further investigations designed to explore neuroendocrine
immunoregulation in fish.
Table 1. Statistical data for quantifying extracellular O2 released by macrophage monolayers
from control and melatonin-implanted rainbow trout 3 wk after melatonin implantation.
|
|
n |
Mean |
SD |
Median |
Max |
Min |
|
Cytochrome C Assay (OD 550 nm) |
|
1. Unstimulated |
|
Control |
6 |
0.0823 |
0.02335 |
0.0812 |
0.1163 |
0.053 |
|
Melatonin-implanted |
6 |
0.05522 |
0.01944 |
0.0537 |
0.0887 |
0.0363 |
|
2. PMA Stimulated |
|
Control |
6 |
0.1118 |
0.02221 |
0.1179 |
0.1314 |
0.0748 |
|
Melatonin-implanted |
6 |
0.1097 |
0.02148 |
0.1036 |
0.1404 |
0.0892 |
|
3. Difference (PMA-No PMA) * |
|
Control |
6 |
0.0295 |
0.01605 |
0.0285 |
0.0534 |
0.0121 |
|
Melatonin-implanted |
6 |
0.0545 |
0.00727 |
0.0521 |
0.0689 |
0.0484 |
T-test (1) P = 0.0537
T-test (2) P = 0.8731
T-test (3)* P = 0.0260*
* Denotes significant difference in values
** Results are expressed as OD 550 nm for 2 x 105 cells well -1.
Table 2. Statistical analysis for the phagocytosis of yeast particles by head kidney macrophages from
melatonin-implanted or control rainbow trout at 6 wk post-implant.
|
|
n |
Mean |
SD |
Med. |
Max. |
Min. |
|
1. Phagocytic Ratio % |
|
Control |
11 |
0.48955 |
0.13118 |
0.335 |
0.97 |
0.25 |
|
Melatonin-Implanted |
10 |
0.645 |
0.07556 |
0.635 |
1.06 |
0.43 |
|
2. Phagocytic Index |
|
Control |
11 |
0.27909 |
0.026307 |
0.205 |
0.49 |
0.15 |
|
Melatonin-implanted |
10 |
0.331 |
0.022156 |
0.3275 |
0.46 |
0.18 |
1. Mann-Whitney Between both Treatment T = 134.5 P = 0.091
2. T-Test and Control Groups t = 1.10 P = 0.2870
Table 3. Lysozyme values (OD 540nm) measured at 3 and 6 wk post-implant in control and
melatonin-implanted fish.
|
|
n |
Mean |
SD |
Med. |
Max. |
Min. |
|
1. Lysozyme at Wk 3 Difference at OD 540nm |
|
Control |
12 |
0.00500 |
0.00195 |
0.00450 |
0.00800 |
0.003 |
|
Melatonin-implanted |
12 |
0.00567 |
0.00458 |
0.00400 |
0.01800 |
0.00200 |
|
2. Lysozyme at Wk 6* Difference at OD 540nm |
|
Control |
12 |
0.00283 |
0.00185 |
0.00250 |
0.00600 |
0.00 |
|
Melatonin-implanted |
12 |
0.00433 |
0.00123 |
0.00400 |
0.00700 |
0.00 |
* Denotes a statistical difference between treatment and control groups.
1. Mann-Whitney Week 3 Between both Treatment T=145 P = 0.795
2. T-Test Week 6* and Control Groups t = 2.34 P = 0.0289*
Table 4. Antibody titers produced by fish challenged with Vibrio anguillarum were determined by
ELISA at 3 wk post-challenge.
|
Titre (1/) |
Control OD |
Melatonin-treated OD P (2-tailed) |
|
|
Mean |
SEM |
n |
Mean |
SEM |
n |
|
|
8 |
0.786 |
0.121 |
6 |
1.044 |
0.096 |
6 |
0.0676 |
|
16 |
1.035 |
0.087 |
6 |
1.177 |
0.06 |
6 |
0.209 |
|
32 |
1.047 |
0.072 |
6 |
1.21 |
0.037 |
6 |
0.073 |
|
64 |
0.978 |
0.101 |
6 |
1.196 |
0.049 |
6 |
0.081 |
|
128 |
0.856 |
0.129 |
6 |
1.152 |
0.062 |
6 |
0.066 |
|
56 |
0.727 |
0.141 |
6 |
1.02 |
0.068 |
6 |
0.0906 |
|
|
0.588 |
0.131 |
6 |
0.896 |
0.074 |
6 |
0.0676 |
Acknowledgments
This research was supported by a grant (GR3/R927) from the Natural Environment Research Council of the
United Kingdom and a Thouron Fellowship from the University of Pennsylvania.
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