=Paper=
{{Paper
|id=Vol-3293/paper40
|storemode=property
|title=Collection of Pathogen-free Astacus sp. Crayfish and Acclimation in Laboratory Aquaria: The First Step Towards Freshwater Crayfish Aquaculture Development
|pdfUrl=https://ceur-ws.org/Vol-3293/paper40.pdf
|volume=Vol-3293
|authors=Maria V. Alvanou,Dimitrios K. Papadopoulos,Ioannis Georgoulis,Athanasios Lattos,Konstantinos Feidantsis,Basile Michaelidis,Apostolos P. Apostolidis,Ioannis A. Giantsis
|dblpUrl=https://dblp.org/rec/conf/haicta/AlvanouPGLFMAG22
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==Collection of Pathogen-free Astacus sp. Crayfish and Acclimation in Laboratory Aquaria: The First Step Towards Freshwater Crayfish Aquaculture Development==
https://ceur-ws.org/Vol-3293/paper40.pdf
Collection of Pathogen-free Astacus sp. Crayfish and
Acclimation in Laboratory Aquaria: The First Step Towards
Freshwater Crayfish Aquaculture Development
Maria V. Alvanou 1, Dimitrios K. Papadopoulos 2, Ioannis Georgoulis 2, Athanasios Lattos 2,
Konstantinos Feidantsis 2, Basile Michaelidis 2, Apostolos P. Apostolidis 3 and Ioannis A.
Giantsis 1
1
Division of Animal Science, Faculty of Agricultural Sciences, University of Western Macedonia, Florina,
53100, Greece
2
Laboratory of Animal Physiology, Department of Zoology, School of Biology, Aristotle University of
Thessaloniki, Thessaloniki, 54124, Greece
3
Laboratory of Ichthyology & Fisheries, Department of Animal Production, Faculty of Agriculture, Forestry
and Natural Environment, Aristotle University of Thessaloniki, Thessaloniki, 54124, Greece
Abstract
Aquaculture constitutes a sector of high importance for Greece, however, so far concerns only
fish and bivalves. On the other hand, freshwater crayfish represent a product of particular
interest, encompassing a greatly export oriented character. Except from their economic value
and great protein source, freshwater crayfish species comprise important benthic invertebrates
and are considered as appropriate model organisms. Nevertheless, Aphanomyces astaci, a
fungus-like eukaryotic microorganism pathogen spread in Europe, which has been transmitted
also in Greece from North American crayfish species, devastated native populations causing
freshwater crayfish plague. Recently, crayfish populations from lake Vegoritida and
Polyphytos declined, leading local authorities to take measurements for preventing further
crayfish population reductions. Thus, the development of an aquaculture protocol
establishment is of urgently high importance not only for commercial activities of local
fishermen, but for restocking purposes and biodiversity conservation as well. Towards this
direction, detection of the aforementioned pathogen in order to be aware of a possible disease
outbreak, represents a core issue. The present study represents a small-scale monitoring for the
presence of A. astaci in freshwater crayfish populations from in North Greek wetlands, and an
initial effort for acclimation of pathogen free Astacus leptodactylus individuals collected from
lake Vegoritida as the first step for an aquaculture protocol establishment.
Keywords 1
freshwater crayfish, aquaculture, Astacus leptodactylus, Aphanomyces astaci, crayfish plague
1. Introduction
Among the various aquatic organisms that are cultivated or farmed worldwide, the vast majority
belong to fish, followed by bivalves, whereas the crustaceans and decapods are placed in the third
position [1]. Within this last category, mainly on account of the major species produced in worldwide
aquaculture, red swamp crayfish Procambarus clarkii come in the second place in terms of quantity,
after the whiteleg shrimp Penaeus vannamei [1]. Particularly in Greece, aquaculture concerns only fish
Proceedings of HAICTA 2022, September 22–25, 2022, Athens, Greece
EMAIL: mariaalvanou7@gmail.com (A. 1); dimipap93@hotmail.com (A. 2); georgoim1707@gmail.com (A. 3); aqualattos@gmail.com (A.
4); kostas.feidantsis@gmail.com (A. 5); michaeli@bio.auth.gr (A. 6); igiants@agro.auth.gr (A. 7); igiantsis@uowm.gr (A. 8)
ORCID: 0000-0003-4480-0301 (A. 1); 0000-0002-9012-8061 (A. 3); 0000-0002-0773-9604 (A. 4); 0000-0001-7606-0024 (A. 5); 0000-
0002-2312-6883 (A. 6); 0000-0002-6323-2955 (A. 8)
©️ 2022 Copyright for this paper by its authors.
Use permitted under Creative Commons License Attribution 4.0 International (CC BY 4.0).
CEUR Workshop Proceedings (CEUR-WS.org)
203
�and bivalves, but no crustacean species so far, with the only exception of few recently licensed marine
shrimp units which, however, have not initiated yet.
Freshwater crustaceans have been known to human since prehistoric times, when they were used as
a primary source of animal protein [2]. The interest in these aquatic animals is also scientific, due to the
peculiarities in the evolutionary history of this taxon and in its biology and ecology. They constitute
excellent biological models for anatomists and physiologists and in recent years they have been also
studied by molecular biologists [3].
In Greece, there are three indigenous species of freshwater crayfish, namely the Astacus astacus
(noble crayfish), the Astacus leptodactylus (narrow clawed crayfish) and the Austropotamobius
torrentium and one invasive species from North America, the Pacifastacus leniusculus [4]. Among the
aforementioned, A. leptodactylus individuals are caught in significant quantities in the Lake Polyphytos,
wherefrom there is also the largest available information regarding their production and trade, mostly
performed through small scaled exporting companies. It should be noted, that based on their great export
potential, both species (A. astacus and A.leptodactylus) are valuable for local fishing communities, and
are thus considered of high conservation priority.
Similarly to other European countries, freshwater crayfish overfishing practices resulted in
conservation issues, with sustainable fishing remaining one of the biggest question marks for inland
wetlands. Keeping this in mind, the establishment of an aquaculture protocol for freshwater crayfish is
of high importance, in order to maintain biodiversity as well as for restocking purposes [5].
The fungus-like oomycete Aphanomyces astaci, introduced in Europe by invasive North American
crayfish, is responsible for the crayfish plague that devastated many European native crayfish
populations. Worth noting that A. astaci has been listed among the 100 worst invasive species [6].
Hence, monitoring and early detection of this pathogen contributes in population screening for pathogen
carries, setting legislation in order to prevent a possible disease outbreak [7,8] The scope of the present
study was the investigation of A. astaci presence in freshwater crayfish from North Greece, the
collection of pathogen free populations and their subsequent acclimation in laboratory aquaria.
2. Materials and Methods
2.1. Sample Collection
Astacus sp. crayfish specimens were collected from three different sampling sites, namely lake
Vegoritida, lake Polyphytos and wetlands Agras-Nisi-Vrita. Collections were carried out with the use
of specific net-traps, located approximately 8-10 meters from the coast, where they remained for 8 days
(Figure 1). The 8th day the traps were removed, and the crayfish specimens were collected. Identification
of collected freshwater crayfish individuals was performed morphologically using specific keys [9]. All
crayfish individuals were initially examined morphologically for the A. astaci presence before
transportation to the laboratory [10].
204
�Figure 1: Net-traps (A) used for freshwater crayfish collections, placed in lake Vegoritida (B)
2.2. Molecular Assay for the Pathogen Aphanomyces Astaci Detection
From each sample composed by approximately 50 individuals, half of them were transferred to the
lab aquaria while the remaining ones were examined for the presence of A. astaci. A partial tissue of
the uropod, soft abdominal cuticle, eye stalk and walking leg joint of each individual were crashed and
used for DNA isolation using the NucleoSpin DNA extraction kit (Macherey Nagel, Germany) and
sterile instruments. A 569-bp fragmant of the A. astaci ITS nrDNA was targeted using the PCR as
previously described [10]. Considering that the absence of an amplified PCR product may be observed
due to insufficient amounts of DNA in the PCR reaction, control PCR reactions were run with primers
used for all Oomycetes and other microorganisms, i.e. ITS1 and ITS4 as described in Oidtmann et al.
[11].
2.3. Transfer to Laboratory and Acclimation in Aquaria
All collected freshwater crayfish samples belonging to Astacus leptodactylus species were placed in
aquaria. Each aquarium was filled with approximately 50 L of water and was equipped with air pump
(Figure 2). After alive crayfish specimens transfer in the lab, each male individual was placed with two
females in each aquarium and were fed with commercial growth diet for Sparus aurata as basal diet
once every week. The water was changed the day after feeding. The temperature was kept stable at ±15
ο
C and the conductivity was calculated at ±600 μS/cm. Also, since freshwater crayfish are more active
during darkness, all tanks were provided with PVC shelters (Figure 2).
205
�Figure 2: Aquaria where the collected crayfish were placed (left), equipped with a PVC shelter (right)
3. Results
In total, 150 individuals of freshwater crayfish belonging to two species, namely A. leptodactylus
and A. astacus, were collected, half of which were examined for the pathogen A. astaci presence,
whereas the remaining were placed in lab aquaria. Using the primers 42 and 640 [10], an amplicon of
length 569 bp would be expected if the pathogen were present. PCR products corresponding to A. astaci
were not amplified in any specimen examined (Figure 3). DNA from these individuals was successfully
amplified with primers ITS1 and ITS4 (Figure 3) that serve as internal control, corresponding to other
organism oomycetes as reported in Oidtman et al. [11]. Thus, all collected crayfish specimens were
scored as pathogen free.
Post A. astaci detection investigation, pathogen free individuals were placed in the lab aquaria.
During their acclimation process many different behaviours were observed. Firstly, some female
crayfish produced eggs as shown in Figure 4A. This specific behaviour may be observed owing to stress
response of acclimation process. In addition, mating behaviour between individuals was observed
(Figure 4B). More specifically, the male on the top observed to hold the female firmly with the chelipeds
and the ischial hooks. Similar mating behaviour has been described in Vogt et al. [12] in marbled
freshwater crayfish (Procambarus fallax). These results indicate the successful acclimation in the lab
aquaria, where freshwater crayfish were kept alive for more than two months.
Figure 3: Agarose gel electrophoresis banding patterns of the PCR performed for the investigation of
the A. astaci presence in tissues of Astacus sp. Lane N: negative control; lanes AL1-AL5: Astacus
leptodactylus tissue samples; Lane L: DNA Mass ladder (Nippon Genetics); AL1C-AL5C: internal
controls.
206
�Figure 4: A. leptodactylus individual with eggs (A) and two individuals A. leptodactylus exhibiting
mating behaviour (B)
4. Discussion
Native freshwater crayfish species are vulnerable not only to the pathogen causing the crayfish
plague but to overfishing practices as well. Based on the recently observed population reductions, local
authorities have forbidden crayfish fishing for commercial purposes in lakes Vegoritida and Polyphytos
for one year from September 2021 to September 2022. However, it should be noted that it remains
obscure, if this measurement is followed by all local fishermen (personal communication).
Despite its great economic value, freshwater crayfish aquaculture remains underdeveloped in Greece
so far. According to economic prediction models, the post-lignite era is expected to lead to increased
rates of unemployment in Western Macedonia. These problems could be at some extent mitigated with
the development of freshwater crayfish aquaculture. Additionally, aquaculture field development may
provide crayfish stock for restocking purposes in an attempt to support biodiversity balance.
All Astacus individuals examined were found negative to the pathogen A. astaci. Their transfer and
acclimation to aquaria was completed successfully and some of them exhibited physiological
behaviours such as molting, mating and egg production. However, it should be emphasized that these
behaviours may occasionally be observed due to extensive stress [13]. The above indications during
acclimation were encouraging for next experimental set ups towards the development of a freshwater
crayfish aquaculture protocol in Greece.
5. Acknowledgements
The research project was supported by the Hellenic Foundation for Research and Innovation (H.F.R.I.)
under the “2nd Call for H.F.R.I. Research Projects to support Faculty Members & Researchers” (Project
207
�Number: 3245).
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