Indonesian Aquaculture Journal, 11 .
, 2016, 9-13 Available online at: http://ejournal-balitbang.
id/index.
php/iaj THE ABILITY OF FAST-GROWING TRANSGENIC AFRICAN CATFISH (Clarias gariepinu.
ON PREDATOR AVOIDANCE Huria Marnis#.
Bambang Iswanto.
Imron.
Selny Febrida, and Raden Roro Sri Pudji Sinarni Dewi Research Institute for Fish Breeding ABSTRACT Research Institute for Fish Breeding has produced transgenic African catfish (Clarias gariepinu.
containing stripped catfish growth hormone gene (PccBA-PhGH) with growth 19.
86% faster than that of non-transgenic This fish has high potential to be released and utilized for fish farming sector to increase national However, there is not yet information about environmental risk of this fish.
One of the major fitness traits determining potential environmental risk is predator avoidance.
This study aimed to determine the predator avoidance ability of transgenic African catfish in an experimental laboratory condition.
In this study, thirty five individuals each of transgenic and non-transgenic with body weight of about 0.
1 A 0.
g were communally stocked in 60 cm x 40 cm x 40 cm aquarium with limited feeding frequency .
d libitum twice a da.
One day after the fish were stocked, the predators were added to each aquarium.
The nontransgenic and transgenic with body weight of 1.
0 A 0.
024 g were stocked as predators as many as five individual in each aquarium.
After approximately two weeks of predation, all remaining fish were collected for transgenic verification by PCR method.
Genomic DNA was isolated from fin tissue of individually The results of this study showed that the transgenic fish had worse predator avoidance and lower cannibal than non-transgenic (P<0.
There was no significant difference in growth performance between transgenic and non-transgenic African catfish (P>0.
in limited food.
The transgenic fish may have lower fitness than non-transgenic.
KEYWORDS:
predator avoidance.
environmental risk.
Clarias gariepinus
INTRODUCTION
African catfish (Clarias gariepinu.
is one commodity which aquaculture development is favored by the Ministry of Marine Affairs and Fisheries.
African catfish has long been grown in Indonesia.
However, the genetic quality of African catfish in Indonesia has decreased in growth rate, so that the necessary requires genetic improvement.
Genetic improvement in the establishment of a rapid growth strain of African catfish might be achieved through transgenesis.
The phenotype of African catfish transgenic have not been shaped by many generation of selection.
A single generation, the characteristics of the organism have been modified with no opportunity for selection and adaptation to their environment.
Growth rate is one character that has been manipulated in transgenic fish.
The fast-growing transgenic African catfish was produced using the method of sperms electroporation Correspondence: Research Institute for Fish Breeding Jl.
Raya 2 Pantura Sukamandi.
Subang 41263.
West Java.
Indonesia.
Phone: .
520500 E-mail: marnis.
huria@gmail.
as a carrier PcCBA-PhGH plasmid in 2011 (Dewi, 2.
In the last study, the F2 populations of transgenic African catfish produced 2-fold fast growing performance than non-transgenic (Marnis et al.
, 2.
However, the fish from genetically modified is still Although many researches have done on transgenic fish such as growth performance of transgenic fish (Morales et al.
, 2001.
Nam et al.
, 2001.
Lu et al.
, 2.
Appetites, feeding motivation, nutritional set points, and feed conversion ratio of transgenic fish (Cook et al.
, 2000.
Sundstrym et al.
Raven et al.
, 2006.
Oakes et al.
, 2.
development and earlier maturation age of transgenic fish (Devlin et al.
, 2004.
Sundstrym et al.
, 2.
, production of elevated GH of transgenic fish (Devlin et al.
Kang & Devlin, 2.
, transgene expression throughout the body (Mori & Devlin, 1.
, only a little information is available regarding the environmental risks posed.
One of the methods that could be used for environment safety testing was by examining the predator avoidance.
There are two important factors in determining whether an animal should risk exposure The ability of fast-growing transgenic African catfish (Clarias gariepinu.
(Huria Marni.
to a predator, namely: parameters that affect mortality rates .
the probability of being killed by a predator over a discrete perio.
and growth rates .
life history characteristics of the fish, particularly the future fitness benefits associated with foo.
(Abrahams & Sutterline, 1.
This study aimed to determine the predator avoidance ability of transgenic African catfish in an experimental laboratory condition.
MATERIAL AND METHOD
Animal and Sample Collection In this study, we used F3 transgenic African catfish, carrying the pCcBA-PhGH construct (Dewi, 2.
All fish were derived from a single family of African catfish (Clarias gariepinu.
and originated from the collection in Research Institute for Fish Breeding.
Sukamandi.
Indonesia.
Predator Avoidance and Anti-Predator Responses of Transgenic African Catfish In this study, thirty five individuals each of transgenic and non-transgenic with body weight about 1 A 0.
019 g were communally stocked in each 60 cm x 40 cm x 40 cm aquaria with limited feeding frequency .
d libitum twice a da.
Normally, fish has feeding frequency ad libitum three to four times a day in regular culture.
One day after the fish were stocked, the predators were added to the aquarium.
The nontransgenic and transgenic African catfish with body weight about 1.
0 A 0.
024 g were stocked as predators .
ive individuals each aquariu.
After approximately two weeks of predation, all remaining fish were collected for transgenic verification and measured average body weight.
Transgenic fish was identified using PCR method with DNA template that has been extracted from fin tissue.
DNA Extraction Genomic DNA of each sample was extracted using DNA extraction kit following the protocols recommended by manufacturer (GeneJet Genomic DNA Purification.
Thermo Scientifi.
Briefly, the protocol consists series of steps including Cell lysis.
DNA precipitation, binding DNA to the column, washing, and Cell lysis was performed by weighing of approximately 10 mg of tissue sample and to check the success of genomic DNA extraction process, the sample was run on mini horizontal gel electrophoresis.
The sample was loaded in to the 1.
5% .
agarose gel, powered with 65 volt electricity and run for 50 minutes.
The gel was then stained with gelRed .
1 AAg/ml and viewed using gel documentation system ultraviolet transillumination.
Polymerase Chain Reaction (PCR) Amplification of transgene was performed using thermal cycling system .
Biora.
PCR standard was performed in a final volume of 25 AAL, using a commercial kit master mix fast start PCR master (Roche.
German.
The PCR was used to amplify a 1,300-bp fragment transgene with primers ACT 107F .
Ao- GTG TGT GAC GCT GGA CCA ACT Ae 3A.
and PhGH2-R .
AoCGA TAA GCA CGC CGA TGC CCA t-3 A.
(Hidayani, 2009.
Dewi, 2.
, for 35 cycles: denaturing at 94AC for 30 secs, annealing at 55AC for 30 seconds, and extension at 72AC for one min.
The amplification using the specific primer of y-actin was performed as internal control of DNA loading.
The yactin primers: bact-F .
Ao-TAT GAA GGT TAT GCT CTG c-3A.
and bact-R .
Ao-CAT ACC CAG GAA AGA TGG CTG-3A.
were designed from a catfish y-actin sequence (Accession JF303887.
The reaction was incubated at 94AC for 30 secs, annealing at 55AC for 30 secs, and extension at 72AC for one min for 30 cycle and the PCR products were then separated on 1.
5% .
agarose gel stained with gelRed .
1 AAg/mL and visualized by ultraviolet transillumination.
Data Analysis Mortality differences and mean body weights of transgenic and control of African catfish were compared using StudentAos t test.
RESULTS AND DISCUSSION
The result showed that the transgene was detected in juvenile of transgenic African catfish with the expected size product was 1,300-bp.
The transgene was not detected in non-transgenic African catfish (Figure .
The result of this study showed that transgenic had worse predator avoidance and lower cannibal than that of non-transgenic (P<0.
(Table .
Similarly, the transgenic channel catfish (Ictalurus punctatu.
containing growth hormone of salmon (RSVLTR-rtGH1 DNA complementary.
RSVLTR-rtGH2, and RSVLTR-csGH cDNA) also had worse predator avoidance (Micropterus salmoides and Lepomis cyanellu.
than that of nontransgenic (Dunham et al.
, 1.
In addition.
Sundstrym et al.
reported that transgenic Coho salmon (Oncorhynchus kisutc.
had worse predator avoidance than that of non-transgenic.
Later.
Wei & Yan .
have demonstrated that the transgenic common carp had worse predator avoidance than that of non-transgenic.
Possibly, the swimming speed of transgenic African catfish was slower than that of non-transgenic, in order to be more vulnerable to be attacked by preda- Indonesian Aquaculture Journal, 11 .
, 2016, 9-13 1500 bp 500 bp Transgenic Non-transgenic 1500 bp 392 bp 500 bp Figure 1.
Detection of transgene (PhGH) and A-actin gene in African catfish (Clarias gariepinu.
transgenic and non-transgenic juvenile using PCR method.
A).
detection transgene.
B).
detection A-actin gene, (-) indicates a negative control, ( ) indicates a positive control.
The expected size of PhGH gene the amplified fragment is 1,300 bp and the expected size of A-actin the amplified fragment is 392 bp Several experiments reported that the swimming speed of transgenic fish containing the growth hormone were slower than that of nontransgenic (DeLiang et al.
, 2007.
Lee et al.
, 2003.
Farrell et al.
, 1.
The swimming speed of each type of fish determines its ability to survive in the environment (Swanson et al.
, 1.
Furthermore, predator avoidance of transgenic African catfish correlated with willingness to risk exposure to a predator.
Abrahams & Sutterline .
reported that transgenic salmon had rate of feed consumption that were approximately five times than that of the control fish and rate of movement approximately double than that of Transgenic salmon also spent significantly more time feeding in the presence of the predator, and consumed absolutely more food at that location.
When there was a real risk of mortality, control fish almost completely avoided the dangerous location.
Transgenic fish continued to feed at this location, but at a reduced level.
These data demonstrate that the growth enhancement associated with the transgenic manipulation increases the level of risk these fish are willing to incur while for aging.
If transgenic African catfish was accidentally released into nature, they would most likely decrease in number because of their increased susceptibility to predators, and eventually the transgenic African catfish would be eliminated.
Alternatively, if the transgenic African catfish was not totally eliminated, the population fitness could be lowered because of the increased vulnerability to predation.
Dunham et .
reported that the selection theory would predict transgenic fish elimination, especially because the fitness trait is predation avoidance and predation pressure is severe in the natural environment for transgenic fish.
These research findings indicate that transgenic African catfish may have lower fitness than that of non-transgenic.
There was no significant difference in growth performance between transgenic and non-transgenic African catfish (P>0.
(Table .
These results suggest that transgenic African catfish would not exhibit their fast growth in limited food.
Possibly, transgenic African catfish did not express their growth potential where food was limited.
Dunham et al.
reported that limited food did not allow the transgenic channel catfish (Ictalurus punctatu.
to express their Likewise, the growth performance of triploid oysters would not increase where food was limited (Dunham, 1.
In Addition.
Gregory & Wood .
reported that negative growth effects were more severe in the fish with food limitation.
CONCLUSION
The result of this study showed that transgenic African catfish had worse predator avoidance and lower cannibal than non-transgenic significanly.
There was no significant difference in growth performance between transgenic and non-transgenic African catfish where treated with limited feeding frequency.
These research findings indicate that the ecological risk of transgenic African catfish would be low or non-existent.
Moreover, the transgenic fish may have lower fitness than non-transgenic.
The ability of fast-growing transgenic African catfish (Clarias gariepinu.
(Huria Marni.
Table 1.
The survival rate of transgenic African catfish and average body weight in predator avoidance test Survival rate Predator Transgenic Body weight .
Non-transgenic Transgenic Non-transgenic 21,43 b 38,57 b 34,27 b 08 A 0.
03 ns 07 A 0.
03 ns 06 A 0.
02 ns 09 A 0.
04 ns 07 A 0.
05 ns 05 A 0.
02 ns 45,71 ns 47,14 ns 38,57 ns 06 A 0.
02 ns 08 A 0.
04 ns 09 A 0.
04 ns 05 A 0.
02 ns 09 A 0.
04 ns 08 A 0.
04 ns 48,57 ns 48,57 ns 47,14 ns 09 A 0.
04 ns 09 A 0.
04 ns 07 A 0.
03 ns 10 A 0.
04 ns 08 A 0.
04 ns 07 A 0.
04 ns Non-transgenic 7,14 a 4,29 a 2,86 a Transgenic 42,86 ns 47,14 ns 40,00 ns None 50,00 ns 47,14 ns 45,71 ns Remark: ns = non significance ACKNOWLEDGEMENT The authors appreciate the funding support from APBN with DIPA No.
660052/2015 in Research Institute for Fish Breeding.
Sukamandi.
We thank to Mr.
Puji Sumargono.
Mr.
Ilma Lizandri.
Mr.
Didi.
Miss Maya Febriana Pangestika, and Miss Putri Widyastuti for the support of this research.
REFERENCES