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Scientific Reports Mar 2022The family Anisakidae, mainly represented by Anisakis simplex s.l. and Pseudoterranova decipiens, encompasses zoonotic nematodes infecting many marine fish. Both are...
The family Anisakidae, mainly represented by Anisakis simplex s.l. and Pseudoterranova decipiens, encompasses zoonotic nematodes infecting many marine fish. Both are responsible for gastrointestinal disease in humans after ingestion of a live larva by consumption of undercooked fish, and, in the case of A. simplex, an allergic reaction may occur after consuming or even handling infected fish. Due to its phylogenetic relatedness with A. simplex, few studies investigated the allergenic potential of P. decipiens, yet none of them focused on its excretory/secretory (E/S) proteins that easily get missed when working solely on extracts from crushed nematodes. Moreover, these E/S allergens remain behind even when the larva has been removed during fish quality processing. Therefore, the aim was to investigate if Anisakis-like allergens could also be detected in both crushed and E/S P. decipiens protein extract using targeted mass spectrometry analysis and immunological methods. The results confirmed that at least five A. simplex allergens have homologous proteins in P. decipiens; a result that emphasizes the importance of also including E/S protein extracts in proteomic studies. Not only A. simplex, but also P. decipiens should therefore be considered a potential source of allergens that could lead to hypersensitivity reactions in humans.
Topics: Allergens; Animals; Anisakis; Ascaridoidea; Fishes; Hypersensitivity; Immunoassay; Larva; Phylogeny; Proteomics
PubMed: 35260766
DOI: 10.1038/s41598-022-08113-3 -
International Journal of Food... Apr 2022Anisakidae, mainly represented by the species Anisakis simplex and Pseudoterranova decipiens, are one of the most commonly zoonotic nematodes present in marine fish...
Anisakidae, mainly represented by the species Anisakis simplex and Pseudoterranova decipiens, are one of the most commonly zoonotic nematodes present in marine fish species. Apart from public health risks directly linked to the parasite itself, little is known on the effects of the migrating nematodes on the hygienic quality of the fish fillet due to bacteria it carries. In the present study, the cultivated bacterial community on and in individual P. decipiens larvae deriving from codfish is reported. Four isolation media were included and evaluated to increase the bacterial diversity isolated, and identification of the bacterial growth was performed by a combination of Matrix-Assisted Laser Desorption Ionization Time-Of-Flight mass spectrometry and 16S rRNA gene sequencing. Results revealed that the microbiota of P. decipiens larvae comprises both potential spoilage bacteria and human opportunistic pathogens, and that a combined isolation on the general isolation medium tryptone soy agar and a medium supplemented with artificial seawater resulted in the highest bacterial recovery in terms of diversity and enumeration. Dissimilarity analysis also revealed similar, though unique, bacterial communities between nematodes originating from the same fish suggesting that anisakid microbiota compositions are reflections of the microbial assemblages in the fish host as an individual, and that the gut microbiome is diverse within gadoid fish species originating from the same geographical habitat. Future research should, based on the results in the present study, further elaborate on the comparison of the bacterial communities of both the larva and the codfish from which it was isolated, and, explore the extrapolation potential towards other fish and nematode species. Also, the actual degree of risk beyond the simple presence of the parasite due to carriage of opportunistic bacteria should be examined, as well as the nematode's true effect on spoilage.
Topics: Animals; Anisakis; Bacteria; Fish Diseases; Fishes; Gadus morhua; Larva; Microbiota; Parasites; RNA, Ribosomal, 16S
PubMed: 35231680
DOI: 10.1016/j.ijfoodmicro.2022.109591 -
Laeknabladid Feb 2022During 2004-2020 in total 18 anisakid larvae (Nematoda) were sent in to the Laboratory of Parasitology at Keldur for investigation and species identification. Fourteen...
During 2004-2020 in total 18 anisakid larvae (Nematoda) were sent in to the Laboratory of Parasitology at Keldur for investigation and species identification. Fourteen had temporarily lived within the human body and were alive when detected, three were noticed alive in food just before being consumed, one larva was found dead. Pseudoterranova decipiens was found í 16 instances (89%), Anisakis simplex in two (11%). The one Anisakis case was a wriggling larva detected in the diaper of a baby that was believed to have ingested the larva with undercooked fish three days earlier in the kindergarten. In the other case a dead larva was found entangled in fish chew, spit out by a baby being fed with boiled haddock. Pseudoterranova larvae in humans (n=13) were most frequently detected in the mouth (11 persons). In one instance winding movements of larva in vomit of a baby attracted the attention of the mother, in another case a person detected tickling movements of a larva when cleaning the anal area after defecation. Length of the 13 Pseudoterranova larvae varied between 30 and 47 mm. They were believed to have lived in their hosts from one up to nine days. Nine larvae had already developed to the L4, stage, four were still in the L3 stage. Cod was the most frequently mentioned source of infection (5 of 14 cases), two persons regarded catfish to be the culprit, one named both fish species. In one case either sushi or plaice was believed to be the infection source, one person presumably got the larva participating in a sushi feast. In four cases the fish source remained unknown. Most often the larva was consumed in private homes, three persons believed to have gotten the larva when dining in a restaurant, a harbour worker got the worm when eating raw fish and the same baby got a larva on two different occasions in the kindergarten.
Topics: Animals; Anisakiasis; Anisakis; Ascaridoidea; Humans; Iceland; Larva
PubMed: 35103620
DOI: 10.17992/lbl.2022.01.676 -
Acta Parasitologica Mar 2022Studies of parasite communities and patterns in the Antarctic are an important knowledge base with the potential to track shifts in ecological relations and study the...
BACKGROUND
Studies of parasite communities and patterns in the Antarctic are an important knowledge base with the potential to track shifts in ecological relations and study the effects of climate change on host-parasite systems. Endemic Nototheniinae is the dominant fish group found in Antarctic marine habitats. Through their intermediate position within the food web, Nototheniinae link lower to higher trophic levels and thereby also form an important component of parasite life cycles. The study was set out to gain insight into the parasite fauna of Nototheniops larseni, N. nudifrons and Lepidonotothen squamifrons (Nototheniinae) from Elephant Island (Antarctica).
METHODS
Sampling was conducted at three locations around Elephant Island during the ANT-XXVIII/4 expedition of the research vessel Polarstern. The parasite fauna of three Nototheniine species was analysed, and findings were compared to previous parasitological and ecological research collated from a literature review.
RESULTS
All host species shared the parasites Neolebouria antarctica (Digenea), Corynosoma bullosum (Acanthocephala) and Pseudoterranova decipiens E (Nematoda). Other parasite taxa were exclusive to one host species in this study. Nototheniops nudifrons was infected by Ascarophis nototheniae (Nematoda), occasional infections of N. larseni with Echinorhynchus petrotschenkoi (Acanthocephala) and L. squamifrons with Elytrophalloides oatesi (Digenea) and larval tetraphyllidean Cestoda were detected.
CONCLUSION
All examined fish species' parasites were predominantly euryxenous regarding their fish hosts. The infection of Lepidonotothen squamifrons with Lepidapedon garrardi (Digenea) and Nototheniops larseni with Echinorhynchus petrotschenkoi represent new host records. Despite the challenges and limited opportunities for fishing in remote areas, future studies should continue sampling on a more regular basis and include a larger number of fish species and sampling sites within different habitats.
Topics: Animals; Antarctic Regions; Ascaridoidea; Fish Diseases; Host-Parasite Interactions; Parasites; Perciformes; Trematoda
PubMed: 34275092
DOI: 10.1007/s11686-021-00455-8 -
International Journal of Food... Apr 2021Anisakid nematode larvae (NL) in fish products comprise a risk to human health and, if visible, lead to the rejection of these products by consumers. Therefore, great... (Review)
Review
Anisakid nematode larvae (NL) in fish products comprise a risk to human health and, if visible, lead to the rejection of these products by consumers. Therefore, great efforts are being made for the identification of these anisakid larvae to estimate the potential consumer health risk as well as to develop effective detection methods in order to prevent the introduction of heavily infected fish products into the market. The tasks of national reference laboratories include the improvement of detection methods and to promote their further development. As a prerequisite for improved detection, it is important to understand the structural properties of anisakid NL and compounds produced during host-parasite interactions. This review provides an overview of the intrinsic properties of anisakid NL and reports the latest detection methods in published literature. First, in order to define the potentially interesting intrinsic properties of anisakid nematodes for their detection, anatomy and compounds involved in host-parasite interactions are summarised. These can be used for various detection approaches, such as in the medical field or for allergen detection in fish products. In addition, fluorescence characteristics and their use as both established and promising candidates for detection methods, especially in the field of optical sensing technologies, are presented. Finally, different detection and identification methods applied by the fish processing industries and by control laboratories are listed. The review intends to highlight trends and provide suggestions for the development of improved detection and identification methods of anisakid NL in fish products.
Topics: Animals; Anisakiasis; Anisakis; Fish Products; Fluorescence; Food Microbiology; Food-Processing Industry; Host-Parasite Interactions; Humans; Larva
PubMed: 33621832
DOI: 10.1016/j.ijfoodmicro.2021.109094 -
Animals : An Open Access Journal From... Dec 2020Nematodes of the Anisakidae family have the ability to infest a wide variety of aquatic hosts during the development of their larval stages, mainly marine mammals,... (Review)
Review
Nematodes of the Anisakidae family have the ability to infest a wide variety of aquatic hosts during the development of their larval stages, mainly marine mammals, aquatic birds, such as pelicans, and freshwater fish, such crucian carp, these being the hosts where the life cycle is completed. The participation of intermediate hosts such as cephalopods, shrimp, crustaceans and marine fish, is an important part of this cycle. Due to morphological changes and updates to the genetic information of the different members of the family, the purpose of this review was to carry out a bibliographic search of the genus and species of the Anisakidae family identified by molecular tests, as well as the geographical area in which they were collected. The Anisakidae family is made up of eight different parasitic genera and 46 different species. Those of clinical importance to human health are highlighted: , . , , , . , . and . . The geographical distribution of these genera and species is located mainly in the European continent, Asia and South America, as well as in North and Central America and Australia. Based on the information collected from the Anisakidae family, it was determined that the geographical distribution is affected by different environmental factors, the host and the ability of the parasite itself to adapt. Its ability to adapt to the human organism has led to it being considered as a zoonotic agent. The disease in humans manifests nonspecifically, however the consumption of raw or semi-raw seafood is crucial information to link the presentation of the parasite with the disease. The use of morphological and molecular tests is of utmost importance for the correct diagnosis of the genus and species of the Anisakidae family.
PubMed: 33322260
DOI: 10.3390/ani10122374 -
Journal of Helminthology Sep 2020Pseudoterranoviasis is a zoonotic disease caused by nematode larvae of species within the genus Pseudoterranova (seal worm, cod worm). Most infections are...
Pseudoterranoviasis is a zoonotic disease caused by nematode larvae of species within the genus Pseudoterranova (seal worm, cod worm). Most infections are gastrointestinal, oesophageal or pharyngeal, but here we report a nasal infection. A 33-year-old patient suffering from rhinitis for 1.5 years recovered a worm larva from the nose. Diagnosis was performed by morphological and molecular characterization, showing the causative agent to be a third-stage larva of Pseudoterranova decipiens (sensu stricto). Various infection routes are discussed.
Topics: Adrenal Cortex Hormones; Adult; Animals; Ascaridida Infections; Ascaridoidea; Denmark; Humans; Larva; Male; Nose; Rhinitis, Allergic
PubMed: 32921327
DOI: 10.1017/S0022149X20000681 -
The Journal of Parasitology Oct 2020Anisakis simplex, Pseudoterranova decipiens, and Contracaecum osculatum third-stage larvae (L3) are fish-borne nematodes that can cause human anisakidosis. Although A....
Anisakis simplex, Pseudoterranova decipiens, and Contracaecum osculatum third-stage larvae (L3) are fish-borne nematodes that can cause human anisakidosis. Although A. simplex is a known source of allergens, knowledge about the allergic potential of P. decipiens and C. osculatum is limited. Therefore, we performed comparative proteomic profiling of A. simplex, P. decipiens, and C. osculatum L3 larvae using liquid chromatography-tandem mass spectrometry. In total, 645, 397, and 261 proteins were detected in A. simplex, P. decipiens, and C. osculatum L3 larvae, respectively. Western blot analysis confirmed the cross-reactivity of anti-A. simplex immunoglobulin (Ig)G antibodies with protein extracts from P. decipiens and C. osculatum L3 larvae. The identified proteins of the Anisakidae proteomes were characterized by label-free quantification and functional analysis, and proteins involved in many essential biological mechanisms, such as parasite survival, were identified. In the proteome of A. simplex 14, the following allergens were identified: Ani s 1, Ani s 2 (2 isomers), Ani s 3 (2 isomers), Ani s 4, Ani s 8, Ani s 9, Ani s 10, Ani s 11-like, Ani s 13, Ani s fructose 1,6-bisphosphatase, Ani s phosphatidylethanolamine-binding protein (PEPB), and Thu a 3.0101. The following 8 allergens were detected in P. decipiens: Ani s 2, Ani s 3 (2 isomers), Ani s 5, Ani s 8, Ani s 9, Ani s PEPB, and Ani s troponin. In C. osculatum 4, the following allergens were identified: Ani s 2, Ani s 5, Ani s 13, and Asc l 3. Furthermore, 28 probable allergens were predicted in A. simplex and P. decipiens, whereas in C. osculatum, 25 possible allergens were identified. Among the putative allergens, heat shock proteins were most frequently detected, followed by paramyosin, peptidyl-prolyl cis-trans isomerase, enolase, and tropomyosin. We provide a new proteomic data set that could be beneficial for the discovery of biomarkers or drug target candidates. Furthermore, our findings showed that in addition to A. simplex, P. decipiens and C. osculatum should also be considered as potential sources of allergens that could lead to IgE-mediated hypersensitivity.
Topics: Allergens; Animals; Anisakis; Ascaridida Infections; Ascaridoidea; Blotting, Western; Chromatography, Liquid; Cross Reactions; Electrophoresis, Polyacrylamide Gel; Helminth Proteins; Humans; Immunoglobulin G; Isomerism; Larva; Proteome; Proteomics; Rabbits; Tandem Mass Spectrometry
PubMed: 32906150
DOI: 10.1645/19-75 -
Parasitology Research Oct 2020Anisakid nematode larvae occur frequently in the liver of Atlantic cod, but merely few infection data from cod in waters around Greenland exist. The present study...
Anisakid nematode larvae occur frequently in the liver of Atlantic cod, but merely few infection data from cod in waters around Greenland exist. The present study reports the occurrence of third-stage anisakid larvae in the livers of 200 Atlantic cod caught on fishing grounds along the West coast of Greenland (fjord systems of Maniitsoq) in May, June, August and September 2017. Classical and molecular helminthological techniques were used to identify the nematodes. A total of 200 cod livers were examined, and 194 were infected with third-stage nematode larvae (overall prevalence of infection 97%) with a mean intensity of 10.3 (range between 1 and 44 parasites per fish). Prevalences recorded were 96% for Anisakis simplex (s.l.), 55% for Pseudoterranova decipiens (s.l.) and 8% for Contracaecum osculatum (s.l.). Sequencing the mtDNA cox2 from 8 out of 23 these latter larvae conferred these to C. osculatum sp. B. A clear seasonal variation was observed, with a rise in A. simplex (s.l.) and P. decipiens (s.l.) occurrence in June and August and a decline in September. The study may serve as a baseline for future investigations using the three anisakids as biological indicators in Greenland waters.
Topics: Animals; Anisakiasis; Anisakis; Atlantic Ocean; Cyclooxygenase 2; DNA, Mitochondrial; Fish Diseases; Gadus morhua; Greenland; Larva; Liver
PubMed: 32656658
DOI: 10.1007/s00436-020-06807-z -
Acta Parasitologica Mar 2021Endoparasitic nematodes of six harbour porpoises Phocoena phocoena and four grey seals Halichoerus grypus, stranded at the eastern coast of the Baltic Sea in Germany in...
PURPOSE
Endoparasitic nematodes of six harbour porpoises Phocoena phocoena and four grey seals Halichoerus grypus, stranded at the eastern coast of the Baltic Sea in Germany in winter 2019, were analysed in order to identify nematode parasites and to compare with recent studies from the same area.
METHODS
Endoparasitic nematodes were identified by using both morphological and molecular characters. The successfully obtained sequences of the rDNA marker regions ITS-1, 5.8S, ITS-2 from 29 anisakid and the rDNA marker region ITS-2 of 11 pseudalid nematodes were amplified.
RESULTS
Analyses revealed the presence of three parasite species, the anisakid nematode Contracaecum osculatum from grey seals and the pseudalid nematodes Pseudalius inflexus and Stenurus minor from the harbour porpoises. Other anisakid nematodes regularly occurring in the Baltic Sea, e.g. Anisakis simplex or Pseudoterranova decipiens, were not found.
CONCLUSIONS
The prevalence of 100% and a severe parasite load in grey seals demonstrated a very high C. osculatum infection of Baltic Sea fish as their regular prey. Prevalence of 33% for parasites in harbour porpoises and minor infection rates, combined with a distinct lack of anisakid nematodes, are typical for the current situation of the porpoise parasite fauna in the Baltic Sea. Invasive parasite species as possible indicators for climate change could not be detected.
Topics: Animals; Anisakis; Ascaridoidea; Parasites; Phocoena; Seals, Earless
PubMed: 32642980
DOI: 10.1007/s11686-020-00246-7