Cherax quadricarinatus Resistant to Chequa iflavirus: A Pilot Study.

High mortalities of redclaw crayfish (Cherax quadricarinatus) were reported from northern Queensland farms, mainly attributed to two viruses, Chequa iflavirus and Athtab bunyavirus. From a research population of redclaw crayfish with these pre-existing viral infections, five individuals were found uninfected by Chequa iflavirus but infected with Athtab bunyavirus. A pilot study was designed to examine if progeny crayfish from this cohort were resistant to infections by Chequa iflavirus. Two experiments measured changes in viral load with RT-qPCR. Seven donors, four negative controls and six crayfish injected with a purified virus or saline were used. In Experiment 1, the purified viral inoculum was injected into the crayfish, and they were bled 14 days post-injection (dpi). In Experiment 2, haemolymph containing the viruses was injected into the same crayfish and they were bled at 24 hpi, 48 hpi, 7 dpi and 14 dpi. In Exp. 1, the crayfish cleared Chequa iflavirus infections within 14 dpi, while in Exp. 2, it was within 24 hpi. One mortality was observed, but that crayfish had cleared the virus before dying. The number of copies of Athtab bunyavirus and the weights of the crayfish did not differ significantly (p > 0.05) between the control and injected crayfish. Histology of crayfish all showed that the haemolymph vessels were clear of granulomas, suggesting no bacterial involvement. There was no melanisation in the gill tissue of control crayfish, but it was prominent in virus-injected crayfish. Neither group had haemocytic infiltration of the muscle fibres. Anti-viral immune mechanisms of RNA interference and Cherax quadricarinatus Down Syndrome Cell Adhesion Molecule (DSCAM) are hypothesised to be involved in viral clearance. We conclude that these crayfish were resistant to Chequa iflavirus infections and could be commercially exploited by aquaculturists as a nuclear breeding stock if numbers are increased over time.

Prevalence of infection with Dirofilaria immitis in cats in Townsville, Australia.

Studies on the prevalence of infection by Dirofilaria immitis in Australian cats are rare. The current study aimed to determine the prevalence of infection with D. immitis in a tropical region of Australia by antigen, antibody and PCR testing. 172 healthy cats over 6 months of age from the Townsville region of Australia were tested for D. immitis specific antibodies and antigen using a commercially available kit. 50 samples were subsequently retested using a second commercially available antibody kit. 48 of these samples were checked for D. immitis DNA using PCR. No cat tested positive on any test. Maximum antigen and antibody prevalence was calculated as 1.27% and 2.10%, respectively.

Establishing a gold standard method for the detection of Cherax reovirus using reverse transcriptase, quantitative, polymerase chain reaction.

Cherax reovirus infects redclaw crayfish (Cherax quadricarinatus) and it may be involved in mortalities between 5-20 % and stunting of up to 40 % of survivors. The sequence of the RNA-dependent RNA polymerase was used to develop a reverse transcription, quantitative, PCR (RT-qPCR) which was specific against seven other crustacean viruses (Athtab bunyavirus, Chequa iflavirus, Macrobrachium rosenbergii nodavirus, Gill-associated virus, Taura syndrome virus, White spot syndrome virus, and Penaeus stylirostris Penstylhamaparvovirus) although GAV produced a reaction that was easily separated by melt curve analysis. A strong linear correlation (r2 = 0.9965) was obtained between viral quantities ranging from 107 to 10 viral copies/reaction with an amplification efficiency of 0.92. This RT-qPCR is 2-times faster and 100 times more sensitive than a standard RT-PCR using agarose gel electrophoresis with the potential to detect the virus down to 7.64 copies/reaction in clinical samples. In clinical crayfish samples, it was able to detect Cherax reovirus in crayfish when the traditional RT-PCR was negative. Its' measurement of uncertainty was less than 2% (0.02-1.9), similar to PCRs for other crustacean viruses. This RT-qPCR is proposed as the gold standard and should be used for the screening of populations of C. quadricarinatus for broodstock before being used in hatcheries or on farms.

Disease risk analysis in sea turtles: A baseline study to inform conservation efforts.

The impact of a range of different threats has resulted in the listing of six out of seven sea turtle species on the IUCN Red List of endangered species. Disease risk analysis (DRA) tools are designed to provide objective, repeatable and documented assessment of the disease risks for a population and measures to reduce these risks through management options. To the best of our knowledge, DRAs have not previously been published for sea turtles, although disease is reported to contribute to sea turtle population decline. Here, a comprehensive list of health hazards is provided for all seven species of sea turtles. The possible risk these hazards pose to the health of sea turtles were assessed and "One Health" aspects of interacting with sea turtles were also investigated. The risk assessment was undertaken in collaboration with more than 30 experts in the field including veterinarians, microbiologists, social scientists, epidemiologists and stakeholders, in the form of two international workshops and one local workshop. The general finding of the DRA was the distinct lack of knowledge regarding a link between the presence of pathogens and diseases manifestation in sea turtles. A higher rate of disease in immunocompromised individuals was repeatedly reported and a possible link between immunosuppression and environmental contaminants as a result of anthropogenic influences was suggested. Society based conservation initiatives and as a result the cultural and social aspect of interacting with sea turtles appeared to need more attention and research. A risk management workshop was carried out to acquire the insights of local policy makers about management options for the risks relevant to Queensland and the options were evaluated considering their feasibility and effectiveness. The sea turtle DRA presented here, is a structured guide for future risk assessments to be used in specific scenarios such as translocation and head-starting programs.

A novel virus (order Bunyavirales) from stressed redclaw crayfish (Cherax quadricarinatus) from farms in northern Australia.

Athtabvirus, a bunya-like virus and chequa iflavirus infect redclaw crayfish (Cherax quadricarinatus) and they may cause mortality reaching 20-40% after about three weeks following transportation stress. Lesions were seen in the muscles of broodstock and juveniles and nerve cords of craylings. Using NextGen sequencing, the whole transcriptomes of a farmed case crayfish and a tank-reared, unaffected crayfish were assembled producing over 500,000 contigs. The average depth of reads was 18 replicates with a range from 15 to 44. The near complete sequences of the large and middle genome segments of a bunya-like virus were detected along with chequa iflavirus. The internal bunya-like motifs; RNA-dependent RNA polymerase on the L segment, and glycoprotein n (Gn) on the M segment were easily identified. In the opposite, positive-sense direction on the M segment, another presumed glycoprotein (glycoprotein c) with a low-density lipoprotein receptor (cysteine-rich) motif was identified by position specific iterated (psi)-BLASTp. The athtabvirus was related to Whenzhou Shrimp Virus 2 (E = 0.0, 43% amino acid identity), an unassigned, -ve sense ssRNA virus, and to peribunyaviruses (E = 10-50-20). In descending order of the number of RNA copies/0.2 mg of tissue, the organs most heavily infected were muscle (9.4 × 106), nerve cord (5.24 × 106), heart (4.07 × 106), gills (3.96 × 106), hepatopancreas (1.58 × 106) and antennal gland (6.6 × 105). Given the tissue tropism (muscle and nerves) of athtabvirus and the original lesions, this virus is implicated in being involved in the mortalities in crayfish after transportation.

Comparison of molecular detection PCR methods for chequa iflavirus in freshwater crayfish, Cherax quadricarinatus.

Chequa iflavirus (+ve sense ssRNA virus) infects redclaw crayfish (Cherax quadricarinatus) and it may cause mortality reaching 20-40% after about three weeks following stress. The sequence of the RNA-dependent RNA polymerase at nucleotide position 8383-9873 was used for developing and comparing PCR-based detection protocols. The reverse transcription, quantitative, polymerase chain reaction (RT-qPCR) was specific against nine Picornavirales and crustacean viruses and its' measurement of uncertainty (0.07-1.37) was similar to PCRs for other crustacean viruses. In vitro, the reverse transcription loop-mediated isothermal amplification (RT-LAMP) read at 60min had poor repeatability for a linearized plasmid with an iflavirus insert when compared with RT-PCR visualised on an electrophoretic gel and RT-qPCR; both sensitive to 102 copies. In a limited, comparative sample of clinical crayfish haemolymph, the lowest, non-zero copies were 2.88×104 for RT-PCR and 4.60×101 for the RT-qPCR. In 68 further clinical crayfish haemolymph samples tested by RT-qPCR only, copy numbers ranged from 0 to 1.14×106. For RT-qPCR, the amplification plots, melt curves and the CT values indicated that the CT above 34.0 is a potential negative result but examination of the melt curve is necessary for an accurate interpretation. A suggested program of testing for crayfish farmers would consist of non-destructive bleeding, labelling of crayfish and screening with RT-qPCR. Only those crayfish nominally negative (below detectable limits) would be used for broodstock or selective breeding.

Assessment of a cricket, Acheta domesticus, bioassay for Chequa Iflavirus and bunya-like virus from redclaw crayfish Cherax quadricarinatus.

Chequa iflavirus and a bunya-like virus infect redclaw crayfish (Cherax quadricarinatus) and they may cause mortality reaching 20-40% after about three weeks after a stress event. To complete River's postulates for viruses, virus-free animals are needed. Due to a lack of chequa iflavirus and bunya-like virus-free crayfish (testing shows>85% infection rate) coupled with the facts that iflavirus and bunyaviruses are found in insects and that crickets had been successful alternate hosts for crustacean viruses before, Acheta domesticus was trialled asa bioassay animal. There was no significant difference (P>0.05) in mortality rates between uninfected control crickets and infected crickets. Reverse transcriptase polymerase chain reaction for both viruses failed to find any trace of the RNA viruses in fed or inoculated crickets after 30days. The search for an alternative bioassay host will have to be widened.

Discovery of a novel Picornavirales, Chequa iflavirus, from stressed redclaw crayfish (Cherax quadricarinatus) from farms in northern Queensland, Australia.

In 2014, northern Queensland crayfish from farms affected by particularly transportation and translocation stress, started to die with mortality reaching 20-40% after about three weeks and then mortalities subsided. Crayfish from 1 farm had 65% mortalities within 11 weeks. With histological examination of broodstock and juveniles, the muscle fibres were fractured with haemocytic infiltration reminiscent of viral infection or vitamin E/selenium deficiencies. Sequence dependent and independent PCRs failed to identify a viral aetiology. However, the whole transcriptomes of a case crayfish and an unaffected crayfish from a different population were assembled producing over 500,000 contigs. The complete sequence of a positive sense, single stranded RNA virus (+ve ssRNA virus; 9933bp) and the large and medium segments of a bunya-like virus were detected. Transcript back-mapping and newly developed PCRs indicated that the viruses were in the case crayfish but not the control crayfish. The +ve ssRNA virus is clearly in the order Picornavirales, marginally in the genus Iflavirus in a clade of Chinese and Northern American terrestrial arthropod viruses. The internal Picornavirales motifs; RNA-dependent RNA polymerase, helicase (P-loop) and 2 viral capsids genes were easily identified. This is the first iflavirus identified from crustacea and is named Chequa iflavirus. Whether these viruses are responsible for the stress-related mortalities is unproven but the Chequa virus' role seems limited as it appears it has been present in crayfish from at least the early 1990s; unless low-grade, chronic mortalities have been largely unnoticed.

First complete genome of an Ambidensovirus; Cherax quadricarinatus densovirus, from freshwater crayfish Cherax quadricarinatus.

In 1999, the causative agent of an epizootic in Cherax quadricarinatus was described, and given the provisional name Cherax quadricarinatus parvovirus-like. Sequencing of the 6334 nt genome identified three open-reading frames on the top strand coding NS3 (35.55 kDa), NS1 (67.36 kDa) and NS2 (35.18 kDa) and on the bottom strand a single open reading frame which most likely encodes 4 structural proteins. Motifs characteristic of the Densovirinae were found in the ORFs. Phylogenetic analysis of the amino acids in NS1 places the genome in the genus Ambidensovirus, most closely related to the marine sea star densovirus (75%, E=0.0) and distantly related to Acheta domestica densovirus (44.1%). The virus name is proposed as species Decapod ambidensovirus, variant Cherax quadricarinatus densovirus. This is the first Ambidensovirus to be found in decapod crustaceans and the first of the subfamily Densovirinae to be sequenced from a freshwater crayfish. Cherax quadricarinatus densovirus and sea star densovirus are the first highly related Densovirinae to infect phylogenetically disparate hosts and are thus far, unique among the Densovirinae.

Effects of Colonization of the Roots of Domestic Rice (Oryza sativa L. cv. Amaroo) by Burkholderia pseudomallei.

Burkholderia pseudomallei is a saprophytic bacterium that causes melioidosis and is often isolated from rice fields in Southeast Asia, where the infection incidence is high among rice field workers. The aim of this study was to investigate the relationship between this bacterium and rice through growth experiments where the effect of colonization of domestic rice (Oryza sativa L. cv Amaroo) roots by B. pseudomallei could be observed. When B. pseudomallei was exposed to surface-sterilized seeds, the growth of both the root and the aerosphere was retarded compared to that in controls. The organism was found to localize in the root hairs and endodermis of the plant. A biofilm formed around the root and root structures that were colonized. Growth experiments with a wild rice species (Oryza meridionalis) produced similar retardation of growth, while another domestic cultivar (O. sativa L. cv Koshihikari) did not show retarded growth. Here we report B. pseudomallei infection and inhibition of O. sativa L. cv Amaroo, which might provide insights into plant interactions with this important human pathogen.

Impact of herbicide Ametryn on microbial communities in mixed liquor of a membrane bioreactor (MBR).

Ametryn, which is a second generation herbicide, was introduced to a lab-scale MBR at a concentration of 1mg/L and a 20-40% removal was observed at HRT ranging from 7.8 to 15.6h for an average influent Ametryn concentration of 0.8 mg/L. Components of EPS (protein and carbohydrates) increased in the bioreactor and the observed biomass production reduced after the addition of Ametryn. In a batch study, GAC was added to MBR mixed liquor and removal of Ametryn via biodegradation and adsorption were measured. Five common bacterial colony types (Gram negative and positive bacilli and Gram negative cocci) were identified and three of these were resistant to Ametryn up to 5mg/L. GAC was found to be a very effective Ametryn adsorption medium and in some occasions Ametryn may have acted as a nutrient source for bacteria.

Molecular characterisation of hepatopancreatic parvovirus (PmergDNV) from Australian Penaeus merguiensis.

Hepatopancreatic parvovirus infection is associated with reduced growth rates of prawns during the juvenile stages and overt mortalities. Hepatopancreatic parvovirus was purified from Penaeus merguiensis from northern Queensland and a partial consensus sequence of 5.9 kb was obtained. Nucleotide comparisons revealed that the Australian isolate of HPV has a nucleotide similarity (87%) closer to HPVchin and the full sequence of HPV Penaeus monodon (PmDNV) (6321 bp) than to HPVsemi (83%). Three putative open reading frames were identified. The first open reading frame encoded a nonstructural protein (NS2) and shared an amino acid similarity of 86% with PmDNV. The second ORF overlapped the first open reading frame and shared 93% and 26% amino acid similarity with PmDNV and PstDNV, respectively, and encoded NS1. The third ORF encoded the viral structural protein and shared an amino acid similarity of 73% with the capsid protein of PmDNV and HPVchin. The phylogeny suggests that the Australian HPV isolate is closely related to the Korean HPVchin isolate than to the Indian HPVsemi and Thai PmDNV isolates. HPV strains may be following the phylogenetic relationship of penaeid prawn hosts rather than their geography.