Japo Jussila

Hemolymph clotting time as an indicator of stress in western rock lobster (Panulirus cygnus George)

Abstract A simple method to measure clotting time was introduced in an experiment studying the effects of exercise stress on western rock lobster ( Panulirus cygnus ). The treatment group lobsters ( N =8) were made to exercise (tail flipping) in a 200 l tank for 2 min. Lobsters were then sampled immediately after exercise and once again 1 h later. Controls were sampled both before the experiment started and after all the other samples were taken (pre- and post-exercise controls). Total hemocyte counts (THCs), differential hemocyte counts (DHCs), hemolymph clotting time, hemolymph protein content and lobster vigor were analyzed. THCs, DHCs, hemolymph clotting and vigor index showed response to treatment. THCs were increased significantly 1 h after exercise (6.36±0.58×10 6 cells/ml) compared to pre- and post-exercise controls (4.42±0.38 and 4.41±0.38×10 6 cells/ml, respectively). Hemolymph clotting time in the same experimental lobsters (43.7±2.0 s) were decreased compared to pre- and post-exercise control groups (56.0±4.1 and 52.7±2.2 s, respectively). Hemolymph clotting times were correlating with DHCs and hemolymph protein levels. Hemolymph clotting time is easily measured and could be a useful indicator of stress.

Detection and quantification of the crayfish plague agent in natural waters: direct monitoring approach for aquatic environments.

Aphanomyces astaci, a specialised parasite of North American freshwater crayfish, is the disease agent of crayfish plague that is lethal to European freshwater crayfish. The life cycle of A. astaci has been inferred from experimental laboratory studies, but less is known about its natural sustainability and ecology. To address such questions, tools for monitoring of A. astaci directly in aquatic environments are needed. Here, we present an approach for detecting and quantifying A. astaci directly from water samples using species-specific TaqMan minor groove binder real-time PCR. Samples of a 10-fold dilution series from approximately 10(4) to approximately 1 spore of A. astaci were repeatedly tested, and reliable detection down to 1 spore was demonstrated. Further, to simulate real-life samples from natural water bodies, water samples from lakes of various water qualities were spiked with spores. The results demonstrated that co-extracted humic acids inhibit detection significantly. However, use of bovine serum albumin or the TaqMan Environmental Master Mix largely removes this problem. The practical application of the approach was successfully demonstrated on real-life water samples from crayfish farms in Finland hosting infected North American signal crayfish Pacifastacus leniusculus. Direct monitoring of A. astaci from aquatic environments may find application in the management of wild noble crayfish Astacus astacus stocks, improved aquaculture practices and more targeted conservation actions. The approach will further facilitate studies of A. astaci spore dynamics during plague outbreaks and in carrier crayfish populations, which will broaden our knowledge of the biology of this devastating crayfish pathogen.

Differing virulence of Aphanomyces astaci isolates and elevated resistance of noble crayfish Astacus astacus against crayfish plague.

Crayfish plague epidemics (caused by Aphanomyces astaci) have been causing population collapses among native European crayfish stocks since the late 1800s. Recent indirect and direct evidence has shown that its virulence has been variable, with native European crayfish even acting as carriers. We tested the differences in A. astaci virulence under experimental conditions using both PsI- and As-genotypes with 3 Finnish noble crayfish Astacus astacus populations. We infected crayfish with adjusted quantities of A. astaci zoospores and monitored the symptoms and mortality of the crayfish. The PsI-genotype isolate caused rapid and total mortality among the tested populations, while the As-genotype isolates expressed more variable virulence. In some cases, mortality among the As-genotype-infected crayfish did not exceed the mortality level of the control group. All of the tested noble crayfish stocks showed lower mortality towards the As-genotype of A. astaci isolated from the River Kemijoki epidemic. We conclude that there are clear differences in virulence between different A. astaci genotypes and also differences in virulence within As-genotypes. Furthermore, we observed clear signs of increased resistance in different populations of noble crayfish towards some of the tested strains belonging to the As-genotype of A. astaci.

Monitoring the spore dynamics of Aphanomyces astaci in the ambient water of latent carrier crayfish.

The specialized crayfish parasite Aphanomyces astaci causes the devastating crayfish plague in European crayfish. Even though A. astaci sporulation has been thoroughly studied under pure culture conditions, little is known about the sporulation dynamic from its live host. Our purpose was to investigate the A. astaci spore dynamic in its native parasite-host relationship by monitoring the sporulation from carrier crayfish into the ambient water using agent specific qPCR. American signal crayfish (Pacifastacus leniusculus) with known positive carrier status were housed individually and communally in two experimental set-ups using multiple replicates and different temperatures. Water samples were collected weekly, and spore numbers were quantified. We demonstrate here that live latent carrier crayfish continuously released a moderate number of A. astaci spores (~2700 spores per crayfish/week) in the absence of death and moulting events. In contrast, a pronounced sporulation increase was seen already one week prior to death in moribund crayfish, suggesting a crayfish plague-like condition developing in weakened or stressed individuals. Significantly more spores were produced at 18°C compared to 4°C, while a negative correlation was detected between spore numbers and temperatures rising from 17 to 23°C. This study is the first attempt to quantify the spore release from carrier crayfish on the basis of qPCR applied on water samples, and demonstrate that the approach successfully unravel A. astaci sporulation patterns. The results emphasize that carrier crayfish pose a constant infection risk to highly susceptible crayfish species regardless of crayfish life cycle state.

Marron (Cherax tenuimanus) and noble crayfish (Astacus astacus) hepatopancreas energy and its relationship to moisture content

Abstract Hepatopancreas energy and moisture content were analyzed in farmed and wild-stock marron and wild-stock noble crayfish. Marron were sampled during April 1995 and noble crayfish during September 1995. Total hepatopancreas energy content was analyzed by bomb calorimetry and moisture content was determined from fresh hepatopancreases by oven drying to constant weight. Farmed marron had significantly higher hepatopancreas energy content (31.0 ± 0.4 kj g −1 ) than wild-stock marron (26.7 ± 0.6 kJ g −1 ), indicating better condition in farmed stocks. Wild-stock noble crayfish had similar hepatopancreas energy content (29.3 ± 0.3 kj g −1 ) to farmed marron and significantly higher levels than wild-stock marron. The relationship between hepatopancreas energy and moisture content was linear in both species with coefficients of determination ( r 2 = 0.44 and 0.73 for marron and noble crayfish, respectively). A rapid method of determining freshwater crayfish hepatopancreas energy using moisture content is suggested.

The diversity of the pathogenic Oomycete (Aphanomyces astaci) chitinase genes within the genotypes indicate adaptation to its hosts

The aim of this work was to evaluate the genetic diversity of the crayfish plague pathogen Aphanomyces astaci (Oomycete) among different isolates and genotypes. Partial chitinase genes were cloned and sequenced from 28 A. astaci isolates including four of the five previously identified RAPD (random amplification of polymorphic DNA)-genotypes. The cloned chitinase sequences (n=176) formed three main groups, CHI1, CHI2 and CHI3, with the CHI2 group then further divided into three subgroups, CHI2A, CHI2B and CHI2C. Some of these chitinases were specific for certain genotypes of A. astaci, as CHI2B and CHI2C were only found from the As-genotype and CHI3 from the Ps-genotypes of A. astaci. Highest diversity rate was observed in the CHI2 group, while the CHI3 group specific for Ps-genotypes was highly homologous. Based on our chitinase data, As- and Pc-genotypes seem to be related, while the two Ps-genotypes were identical to each other, but considerably different from the genotypes As and Pc. These are the first genotype specific differences that are located in the coding region of the chitinase gene of A. astaci and the differences observed here also enable the genotyping of A. astaci. The diversity observed here can also reflect differences in the epidemiological properties of the different genotypes.

Dose-dependent mortality of the noble crayfish (Astacus astacus) to different strains of the crayfish plague (Aphanomyces astaci)

Several reports of the European crayfish species carrying a latent infection of the crayfish plague (Aphanomyces astaci) have emerged and the discussion has focused especially on the lowered virulence of As-genotypes behind decreased mortality. The aim of this study was to compare the killing rate of different A. astaci strains in controlled infection experiments. Two separate infection experiments with three A. astaci strains (UEFT2B (As), Evira6462/06 (As) and UEF8866-2 (PsI)) were made to compare the noble crayfish populations from the Lake Viitajärvi, Tervo, (Expt I) and the Lake Mikitänjärvi, Hyrynsalmi (Expt II). In the Expt III, the Lake Koivujärvi population noble crayfish were infected with A. astaci strains UEF8866-2 (PsI) and Evira6462/06 (As) using different dosages (1, 10, 100 and 1000sporesml(-1)) of A. astaci zoospores. The results confirmed that PsI-genotype strain is highly virulent and kills all the crayfish within a few days. The tested two As-genotype strains caused the mortalities more slowly, and part of the challenged crayfish survived until the end of the follow-up period. Our results also confirmed the variance of virulence among A. astaci strains within the As-genotype and demonstrated that the mortality is dependent on the number of zoospores used in the infections. It also appeared, that some noble crayfish populations show increased resistance towards the crayfish plague, especially against the As-genotype of A. astaci.

De Novo assembly and annotation of the freshwater crayfish Astacus astacus transcriptome

We generated RNA-seq data to assemble the transcriptome of the noble crayfish (Astacus astacus) from four combined tissues (abdominal muscle, hepatopancreas, ovaries, green glands). A total of 194 million read pairs with a length of 100 bp were generated. The transcriptome was assembled de novo using Trinity software, producing 158,649 non-redundant transcripts. Lowly expressed transcripts were filtered out leaving 45,415 transcripts of which 14,559 were found to contain open reading frames with predicted gene function. The Transrate software revealed that 91% of the total reads were realigned to the assembly. Furthermore, BUSCO analysis indicated that our assembly is 64% complete. A total of 13,770 transcripts were assigned at least one GO term. This first de novo transcriptome assembly is an important foundation for future genomic research on the noble crayfish and adds to the general knowledge and further characterization of transcriptomes of non-model organisms.

Microsatellite markers reveal clear geographic structuring among threatened noble crayfish (Astacus astacus) populations in Northern and Central Europe

Noble crayfish (Astacus astacus L.), the most highly valued freshwater crayfish in Europe, is threatened due to a long-term population decline caused mainly by the spread of crayfish plague. Reintroduction of the noble crayfish into restored waters is a common practice but the geographic and genetic origin of stocking material has rarely been considered, partially because previous genetic studies have been hampered by lack of nuclear gene markers with known inheritance. This study represents the first large scale population genetic survey of the noble crayfish (633 adults from 18 locations) based on 10 newly developed microsatellite markers. We focused primarily on the Baltic Sea area (Estonia, Finland and Sweden) where the largest proportion of the remaining populations exists. To allow comparisons, samples from the Black Sea catchment (the Danube drainage) were also included. Two highly differentiated population groups were identified corresponding to the Baltic Sea and the Black Sea catchments, respectively. The Baltic Sea catchment populations had significantly lower genetic variation and private allele numbers than the Black Sea catchment populations. Within the Baltic Sea area, a clear genetic structure was revealed with population samples corresponding well to their geographic origin, suggesting little impact of long-distance translocations. The clear genetic structure strongly suggests that the choice of stocking material for re-introductions and supplemental releases needs to be based on empirical genetic knowledge.

Timing and quantifying Aphanomyces astaci sporulation from the noble crayfish suffering from the crayfish plague

Aphanomyces astaci sporulation is crucial for the spreading potential of this disease agent. For the first time, we are reporting timing and quantity of A. astaci spores released from noble crayfish (Astacus astacus) suffering from crayfish plague under practical aquatic conditions. We infected nine noble crayfish with A. astaci PsI-genotype and maintained them in individual 8L tanks. Spores (zoospores and cysts) were quantified from water samples (3 × 1 mL) taken every 12h over 10 d using A. astaci specific qPCR. A clear sporulation trend was found, together with a high individual spore estimate variation. The median spore counts from two days before death to 12h post mortem were from ~500 to ~2000 spores L(-1). A significant sporulation increase occurred after 24h post mortem (~12,000 spores L(-1)) and reached a peak after two days (~65,000 spores L(-1)) before declining to or below pre mortem levels from the fourth day. The single most sporulating crayfish released from ~75,000 to ~400,000 spores L(-1) during the mass sporulating period, yielding a maximum estimate of ~3,200,000 spores released from a single crayfish if we assume homogeneous spore distribution. The results confirm a mass A. astaci spore release from moribund and recently dead infected noble crayfish, with a sporulation peak one to three days post mortem. The acute crayfish mortality only three days after zoospore exposure confirm the lethal potential of the PsI-genotype. The powerful sporulation potential observed here may be one of the key virulence factors of this genotype.