Estimating the genetic divergence and identification of three Trichinella species by isoenzyme analysis

Isoenzyme-based approach was applied to compare Trichinella spiralis, T. britovi and T. pseudospiralis species. Among 13 enzyme systems examined, esterase (EST), malic enzyme (ME) and phosphoglucomutase (PGM) have been found as fully diagnostic, with no common allele in species studied. Adenosine deaminase (ADA), adenylate kinase (AK), hexokinase (HK), peptidase leucyl-alanine (PEP-C) and fructose-bis-phosphatase (FBP) have been capable of distinguishing the two species from resulting profiles. In addition, ADA, AK and PGM displayed the enzyme expression in the lowest amounts of muscle larvae in systems tested (100 larvae/100 microliters of extracts). Based on allozyme data, T. pseudospiralis has been found as the most distinct species within the group of taxa. Only a subtle genetic variability was recorded for T. pseudospiralis in which solely phosphoglucomutase exhibited variant patterns. In addition to the study of reference isolates, T. spiralis from lowland fox in Eastern Slovakia has been evidenced by use of genetic markers. This finding has proved that T. britovi is not the exclusive species parasitizing in the sylvatic ecosystem of the Slovak region.

The relevance of evolutionary genetics for identification of Trichinella sp. and other pathogens at the strain, subspecies and species levels

In the specific field of Trichinella research, the impact of evolutionary methods has been until now limited. This is all the more distressing, since this group of parasites is characterized by hard taxonomical problems. Moreover, for the epidemiological tracking of Trichinella populations, high-discriminating genetic typing, conveniently analyzed by population genetic methods, could be of considerable help. With no additional efforts, many molecular data are already available and could be used for retrospective analyses able to solve many taxonomical problems. It is desirable that coming studies are specifically designed according to evolutionary genetics principles and the question under study (sample size, selection of the appropriate marker).

Genetic diversity within the genus Trichinella as shown by cleavage fragment length polymorphism analysis

The genetic diversity within the genus Trichinella was studied using cleavage fragment length polymorphism (CFLP) analysis. The CFLP method generates specific fingerprints based on single nucleotide mutations. By this method the amplified intergenic regions of the 5S rRNA genes of the eight different genotypes of Trichinella were analysed. The CFLP pattern of T. spiralis was completely different compared with the sylvatic species T. britovi, T. nativa, T. nelsoni, and the genotypes Trichinella T5, Trichinella T6 and Trichinella T8. The T. pseudospiralis intergenic region can be differentiated by size from the other species of Trichinella.

Trichinella pseudospiralis populations of the Palearctic region and their relationship with populations of the Nearctic and Australian regions

Since few non-encapsulated isolates of Trichinella have been studied to date, their level of differentiation from encapsulated species and the taxonomic value of the observed polymorphisms remain to be determined. To this end, biological, biochemical and molecular data from 11 isolates of Trichinella pseudospiralis and one isolate of Trichinella papuae were examined using the broad group of encapsulated species and genotypes for comparison. Single-worm cross-breeding experiments and reproductivity capacity indices revealed F1 progeny only among T. pseudospiralis isolates from different zoogeographical regions, whereas no F1 were produced when T. pseudospiralis was crossed with T. papuae. Furthermore, unlike T. pseudospiralis, T. papuae failed to infect chickens. Comparative analysis of 12 allozymes revealed a single difference between Nearctic and Australian isolates of T. pseudospiralis, but substantial differences when compared with T. papuae (i.e. two unique and six diagnostic markers). Molecular studies involving mitochondrial-derived genes encoding cytochrome oxidase I and the large subunit ribosomal DNA indicated a high level of sequence similarity among T. pseudospiralis isolates; however, a concomitantly high level of variation was observed in expansion segment five of the genomic large subunit ribosomal DNAs among T. pseudospiralis isolates and between this species and T. papuae. Collectively, these results demonstrate high uniformity among isolates of T. pseudospiralis from Eurasia and polymorphism among isolates of T. pseudospiralis belonging to different zoogeographical regions; the results corroborate the classification of T. papuae as a differentiated species.

Detection and identification of eight Trichinella genotypes by reverse line blot hybridization

A reverse line blot (RLB) assay was developed to identify different Trichinella genotypes. The RLB assay accomplishes detection and specific identification of the different Trichinella genotypes and relies on hybridization of the amplified 5S ribosomal DNA intergenic spacer regions to specific, membrane-bound oligonucleotide probes. After one single amplification, we were able to detect and genetically identify six sibling species, i.e., T. spiralis, T. britovi, T. nativa, T. murrelli, T. nelsoni, and T. pseudospiralis, and two additional Trichinella genotypes, T6 and T8. Twenty-four Trichinella strains of different genotypes were unequivocally identified evaluated using one simple PCR-based assay based on single larvae. This assay allows the specific identification of Trichinella species without the need to passage larvae in laboratory animals.

Host diversity and biological characteristics of the Trichinella genotypes and their effect on transmission

The host spectra and biological diversity of the Trichinella genotypes are reviewed. While all genotypes appear to reproduce equally well in carnivore hosts, their infectivity and persistence in omnivores and herbivores show remarkable differences. Most of the genotypes found in wildlife have low infectivity for pigs and some persist only for a few weeks; in herbivores this tendency is even more profound, but malnourished, environmentally stressed, or otherwise immuno-suppressed hosts are likely to be more susceptible to Trichinella genotypes that would otherwise cause no, or only low level infection in that particular host species. In the domestic habitat (e.g. domestic pig farms), Trichinella spiralis is found almost exclusively, but in the sylvatic habitat the other Trichinella genotypes have found individual ecological niches. Thus, when environmental stress is limited in the domestic habitat, the high reproductive capacity of T. spiralis has a selective advantage, but in nature, the tolerance of other (sylvatic) genotypes to high and low temperatures and decomposition of host tissue might be more important. Parasite distribution according to muscle appear to be independent of the genotype of Trichinella and predilection sites are primarily determined by host species and secondarily by the age and level of infection. The biological diversity of the Trichinella genotypes should definitely be considered when planning experimental studies, as the uniform high infectivity of all genotypes in carnivores probably make them more suited for comparative studies than rodents.

The systematics of the genus Trichinella with a key to species

The authors review the major biological, biochemical, and molecular characters that are used to distinguish the seven Trichinella species (T. spiralis, T. nativa, T. britovi, T. pseudospiralis, T. murrelli, T. nelsoni, T. papuae) and three genotypes whose taxonomic status is yet uncertain (T-6, T-8, T-9). A comparison of host specificity, morphology, reproductive abilities, nurse cell development and freeze resistance is presented, along with useful biochemical and molecular markers. Finally, this information is used to construct a diagnostic key for the species. A phylogenetic classification of the species is needed.

Factors affecting the flow among domestic, synanthropic and sylvatic cycles of Trichinella

Nematodes of the genus Trichinella are maintained in nature by sylvatic or domestic cycles. The sylvatic cycle is widespread on all continents, from frigid to torrid zones, and it is maintained by cannibalism and scavenging behavior of carnivores. Trichinella is primarily a parasite of carnivorous mammals, although one non-encapsulated species, Trichinella pseudospiralis, has also been detected in birds. The anaerobic metabolism of larvae in nurse cells allows their survival in extremely decayed meat. Encapsulated larvae in the decomposing carcass function similarly to the species-dispersing population of eggs or larvae of other nematodes, suggesting that the natural cycle of Trichinella includes a free-living stage when the parasite is no longer protected by the homeothermy of the host. Consequently, environmental temperature and humidity play an important role in the transmission of Trichinella among wildlife. Of the 10 recognized genotypes of Trichinella, only Trichinella spiralis is transmitted and maintained in a domestic cycle, although it can be present also in wildlife. All other genotypes (Trichinella nativa, Trichinella britovi, T. pseudospiralis, Trichinella murrelli, Trichinella nelsoni and Trichinella papuae, Trichinella T6, T8, and T9) are transmitted and maintained only in a sylvatic cycle. This generalization does not preclude sylvatic species of Trichinella from invading the domestic habitat, and T. spiralis may return to this habitat when humans fail in the management of wildlife and domestic animals. However, the presence of sylvatic genotypes of Trichinella in the domestic habitat represents a "dead-end" for the sylvatic cycle. Synanthropic animals (rats, foxes, mustelids, cats, dogs, etc.) contribute to the flow of sylvatic Trichinella genotypes from wildlife to domestic animals and of T. spiralis from domestic to sylvatic animals. Furthermore, human behavior not only influences the transmission patterns of Trichinella genotypes in the domestic habitat, but also it can contribute to the transmission and spread of this infection among wildlife, for example by improper hunting practices.

DNA fingerprints of Trichinella as revealed by restriction fragment length polymorphism and single-strand conformational polymorphism (RFLP-SSCP)

A method was developed for gene fingerprinting, combining the principles of restriction fragment length polymorphism and single-strand conformational polymorphism (PCR-RFLP-SSCP). Taking advantage of this method, we analysed the genotypes of 20 isolates from five species of Trichinella (Trichinella spiralis, Trichinella britovi, Trichinella nativa, Trichinella murrelli and Trichinella pseudospiralis) and two uncertain genotypes (Trichinella T6 and Trichinella T8). Target genes for the analysis included three kinds of random amplified polymorphic DNA (RAPD), the gene encoding 43 kDa excretory-secretory protein, the gene encoding mitochondrial cytochrome c -oxidase subunit I and the gene of 18 S rRNA. The genotype revealed by this method was in good concordance with the taxonomy of Trichinella (six species and two uncertain genotypes which is currently accepted based on morphology, isozyme pattern and reproductive isolation). More important, this method revealed intraspecies polymorphism among geographical isolates of T. spiralis and T. britovi.

Molecular investigation of African isolates of Trichinella reveals genetic polymorphism in Trichinella nelsoni

Molecular genetic studies were carried out on three isolates of Trichinella nelsoni (from Kenya, Tanzania and South Africa) and three isolates of Trichinella T8 (from South Africa and Namibia) from sylvatic carnivores and from a sylvatic swine. A probe (pT7.3) specific for T. nelsoni was obtained by screening a pUC18 genomic library. The pT7.3 sequence was 346 bp in length with an AT content of 70%. The sequence is present approximately 200 times per haploid genome. Southern blot analysis of Hind III digested DNAs of the three isolates of T. nelsoni revealed that the hybridisation patterns of the isolates from Kenya and Tanzania were identical and that they differed from that of the isolate from South Africa, indicating the presence of polymorphism in this species. A pUC18 genomic library of Trichinella T8 was also screened, and one clone (pT8.3) was found to be specific for homologous DNA by dot blot, but Southern blot analysis of DNA samples from eight genotypes showed different hybridisation signals for both Trichinella T8 and Trichinella britovi DNAs. No differences in the nucleotide sequences of the expansion segment V were observed for the T. nelsoni isolates. However, they differed from those of Trichinella T8. The presence of Trichinella T8 in Africa south of the Sahara and its genetic relationship with T. britovi remain unclear and warrant detailed investigations.

Infectivity, persistence, and antibody response to domestic and sylvatic Trichinella spp. in experimentally infected pigs

Groups of pigs were inoculated with genotypes of Trichinella belonging to: Trichinella spiralis, Trichinella nativa, Trichinella britovi, Trichinella pseudospiralis (from Caucasus), T. pseudospiralis (from USA), Trichinella murrelli, Trichinella sp. (from North America), and Trichinella nelsoni. The pigs were sacrificed between 5 and 40weeks p.i., and the number of muscle larvae per gram (l.p.g.) of tissue was determined as an average of 18 muscles. All Trichinella genotypes were infective for pigs, but both their infectivity and persistence varied: 5weeks p.i., T. spiralis muscle larvae were present in high numbers (mean=427l.p.g.), while T. britovi, T. nelsoni, and T. pseudospiralis larvae were present in moderate numbers (means=24-52l.p.g.); larvae of the remaining genotypes were recovered only in low numbers (means=0.05-5. 00l.p.g.). The total larval burden (live weight of pigxl.p.g.) was constant over time for T. spiralis, T. britovi, and T. nelsoni, but declined significantly (P<0.05) for the other genotypes. Antibody responses could be detected 3-4weeks p.i. by seven different Trichinella ES antigens, but the antibody levels and dynamics differed significantly among the experimental groups. In pigs inoculated with T. spiralis, T. britovi, or T. nelsoni, the antibody level increased rapidly between weeks 3 and 5 p.i. and was stable or increased slightly throughout the experimental period. In pigs inoculated with T. nativa, T. murrelli, or Trichinella (T6) (from North America), a rapid increase was detected between weeks 3 and 5 p.i., but for these genotypes a reduction in the antibody levels was seen thereafter. In the pigs inoculated with T. pseudospiralis, the antibody level increased more gradually over a period from week 3 p. i. to weeks 15-20 p.i., and decreased thereafter. In general, all species of Trichinella were detected by any of the seven ES antigens, which points to the potential use of one common antigen for surveillance and epidemiological studies on both domestic and sylvatic Trichinella in pigs. Homologous ES antigens were slightly more sensitive in detecting antibodies to the corresponding Trichinella species.

The genetic analysis of F1 hybrid larvae between female Trichinella spiralis and male Trichinella britovi

Hybrids between female Trichinella spiralis and male Trichinella britovi were constructed. Then, hybrid genotype was characterized by DNA markers including mitochondrial cytochrome c oxidase subunit I (CO I) gene, the gene encoding the 43-kDa excretory-secretory (ES) protein, and genomic DNA fragments specific for T. spiralis and T. britovi identified from random amplified polymorphism DNA (RAPD). PCR-restriction fragment length polymorphism (PCR-RFLP) analysis of the mitochondrial CO I gene revealed that all hybrids carried a T. spiralis pattern. The same analysis of the gene encoding the 43-kDa ES protein showed that each hybrid carried both T. spiralis and T. britovi gene type simultaneously. In the analysis of genomic DNA using RAPD-derived PCR primers, some hybrids carried T. spiralis and T. britovi-specific RAPD markers, while others carried the RAPD marker of T. spiralis only.

Trichinella spp.: differential expression of two genes in the muscle larva of encapsulating and nonencapsulating species

Kuratli, S., Lindh, J. G., Gottstein, B., Smith, D. F., and Connolly, B. 1999. Trichinella spp.: Differential expression of two genes in the muscle larva of encapsulating and nonencapsulating species. Experimental Parasitology 93, 153-159. The expression of the two genes tsmyd-1 and tsJ5 was studied in the muscle stage larva of three different species of Trichinella. T. spiralis and T. britovi are both encapsulating species, while T. pseudospiralis is a nonencapsulating species. Expression of tsJ5 is developmentally regulated in T. spiralis and has been shown in this study to be down-regulated in the T. pseudospiralis muscle larva compared with the other two species. Immunoblot analysis has also revealed that the relative abundance of the protein product of this gene, TSJ5, is lower in T. pseudospiralis muscle larvae. It has previously been shown that expression of tsmyd-1 is not developmentally regulated in T. spiralis (Connolly et al. 1996). In contrast, expression of this gene is slightly increased in the muscle larvae of T. pseudospiralis. Southern analysis of genomic DNA from the three Trichinella species shows that both genes are highly conserved.

Trichinella papuae n.sp. (Nematoda), a new non-encapsulated species from domestic and sylvatic swine of Papua New Guinea

Encapsulated and non-encapsulated species of the genus Trichinella are widespread in sylvatic animals in almost all zoogeographical regions. In sylvatic animals from Tasmania (Australian region), only the non-encapsulated species Trichinella pseudospiralis has been reported. Between 1988 and 1998, non-encapsulated larvae of Trichinella were detected in five domestic pigs and six wild boars from a remote area of Papua New Guinea. Morphological, biological, and molecular studies carried out on one strain isolated from a wild boar in 1997 suggest that these parasites belong to a new species, which has been named Trichinella papuae n.sp. This species can be identified by the morphology of muscle larvae, which lack a nurse cell in host muscles, and whose total length is one-third greater than that of the other non-encapsulated species, T. pseudospiralis. Adults of T. papuae do not cross with adults of the other species and genotypes. Muscle larvae of T. papuae are unable to infect birds, whereas those of T. pseudospiralis do. The expansion segment V of the large subunit of the ribosomal DNA differs from that of the other species and genotypes. All of these features allow for the easy identification of T. papuae, even in poorly equipped laboratories. The discovery and identification of a second non-encapsulated species in the Australian region strongly supports the existence of two evolutionary lines in the genus Trichinella, which differ in terms of the capacity of larvae to induce a modification of the muscle cell into a nurse cell.

A multiplex PCR for unequivocal differentiation of all encapsulated and non-encapsulated genotypes of Trichinella

We have developed a single PCR test for the simple and unequivocal differentiation of all currently recognised genotypes of Trichilnella. Partial DNA sequence data were generated from internal transcribed spacers ITS1 and ITS2, and from the expansion segment V region of the ribosomal DNA repeat from five species of Trichinella and two additional genotypes, designated T5 and T6. Five different PCR primer sets were identified which, when used simultaneously in a multiplex PCR, produce a unique electrophoretic DNA banding pattern for each species and genotype including three distinct genotypes of Trichinella pseudospiralis. The banding patterns for each parasite genotype consist of no more than two well-defined DNA fragments, except isolates of T. pseudospiralis which generate multiple, closely migrating bands. The expansion segment V-derived primer set contributes at least one fragment to each genotypic pattern and, therefore, functions both as a means for differentiation as well as an internal control for the PCR. The reliability and reproducibility of each DNA banding pattern were verified using multiple geographical isolates of each Trichinella genotype. The technique was developed further to distinguish genotypes at the level of single muscle larvae using a nested, multiplex PCR, whereby the entire internal transcribed spacer region as well as the gap region of the expansion segment V of the large subunit ribosomal DNA are amplified concurrently in a first-round PCR using primer sets specific for each region, followed by the multiplex PCR for final diagnosis.

A novel cDNA clone encoding a specific excretory/secretory antigen of larval Trichinella pseudospiralis

A cDNA library for Trichinella pseudospiralis was constructed to study the expression of specific antigens. Four positive clones were identified using antibodies against the excretory/secretory (ES) products of the nematode as probe. Sequence analysis showed that they contained identical cDNA inserts of 606 bp, including a 5' non-translated region of 96 bp, a core translated segment of 408 bp and a poly(A)+ 3' terminus. It encoded a novel 136-amino-acid polypeptide. Southern blot analysis indicated that the cDNA did not cross-hybridize to the genomic digests of T. spiralis, mouse, or rat. A single copy only of its complementary sequence was found in the genome of T. pseudospiralis. Using the lambda ZAP expression system, the cDNA was induced to express a 23-kDa beta-galactosidase-fusion protein which did not cross-react with polyclonal and monoclonal antibodies against T. spiralis, heat shock proteins, or four heterologous species of nematodes. The antiserum against the fusion protein recognized a 15-kDa band from the ES products of T. pseudospiralis in immunoblotting. Immunocytolocalization demonstrated that the anti-fusion protein serum only recognized an epitope in the stichosome of T. pseudospiralis and not in T. spiralis. The protein can therefore serve as a specific antigen for the differential diagnosis of trichinellosis.

Identification of Trichinella isolates by polymerase chain reaction--restriction fragment length polymorphism of the mitochondrial cytochrome c-oxidase subunit I gene

We developed a polymerase chain reaction based approach using restriction fragment length polymorphisms of the mitochondrial cytochrome c-oxidase subunit I to identify nine genotypes (Trichinella spiralis, Trichinella britovi-European strains, Trichinella britovi-Japanese strains, Trichinella nativa, Trichinella nelsoni, Trichinella T5, Trichinella T6, Trichinella T8 and Trichinella pseudospiralis) in the genus Trichinella. Partial mitochondrial cytochrome c-oxidase subunit I genes of nine genotypes were amplified by polymerase chain reaction, sequenced, and digested with three restriction endonucleases (Mse I, Alu I and Bsp1248 I). This polymerase chain reaction based restriction fragment length polymorphism method allowed the identification of Trichinella genotypes. Trichinella spiralis, Trichinella britovi-Japanese strains, Trichinella nelsoni, T5 and Trichinella pseudospiralis were distinguishable by digestion with Mse I. Trichinella britovi-European strains and Trichinella T8 were distinguishable by digestion using Alu I, and Trichinella nativa and Trichinella T6 were distinguishable by double-digestion with Mse I and Bsp1286 I. The results obtained with this polymerase chain reaction based restriction fragment length polymorphism assay confirmed those previously reported by others and support the separation of the Japanese isolates as a new genotype, namely Trichinella T9.

Cloning and analysis of a Trichinella britovi gene encoding a cytoplasmic heat shock protein of 72 kDa

A gene encoding a protein of 646 amino acid residues with a molecular mass of 71.3 kDa showing homology to the cytoplasmic form of the 70 kDa heat shock protein was cloned and sequenced from the nematode parasite Trichinella britovi (Tb). The gene was expressed in vitro as a protein of 71 kDa that was immunoprecipitated by a Trichinella-infected rabbit serum. Monospecific polyclonal antibodies raised against the recombinant Tb Hsp70 expressed in Escherichia coli, recognized a protein of 70 kDa by Western blot analysis of Tb soluble antigen (muscular stage). Tb Hsp70 was located in the nuclei of the muscle larvae as determined by the indirect immunofluorescent pattern on cross-sections of the worm. The expression of this protein was not detected in adult worm nuclei suggesting a differential expression of Hsp70 between the 2 stages of Trichinella.

Cloning and characterization of Rab and Ran/TC4 cDNA clones in Trichinella spp

The cloning and characterization of seven Rab and three Ran/TC4 partial cDNA sequences in both cystic (Trichinella spiralis and T. britovi) and noncystic species (T. pseudospiralis) are reported. These molecules were cloned by rapid amplification of cDNA ends via polymerase chain reaction (RACE-PCR), using cDNA from the aforementioned Trichinella spp. coupled to the AP1 adaptor. As primers, AP1 and 5B (derived from the WDTAGQE sequence of region 2 specific for Rab and Ran proteins) sequences were included in the PCR. The cloned cDNAs were sequenced and characterized by both Southern-blot and Northern-blot analysis. Trichinella spp. Rab- and Ran-like molecules showed divergences in both the nucleotide and the deduced amino acid sequences as compared with the corresponding homologues previously described in other organisms. In addition, differences were observed among the Trichinella species, mainly between the cystic and the noncystic species, in both DNA restriction-enzyme polymorphism and expression of the six GTPases isolated.

Differentiation of Trichinella genotypes by polymerase chain reaction using sequence-specific primers

A method was developed to identify species and genotypes within the genus Trichinella using polymerase chain reaction (PCR) and specific primers. Enzymatic amplification of 2 partially conserved and repetitive genomic DNA sequences that have been shown to be variable in length within the different Trichinella genotypes form the basis of this test. Within these regions of the genome, 4 sets of primers were evaluated from which 2 were chosen for their ability to differentiate among the genotypes under stringent primer annealing conditions while maintaining high yields of amplification product. Differences in the size of PCR products from multiple isolates of each genotype indicate sufficient variation to identify 7 of the 8 parasite groups within this genus. One primer set can differentiate among some genotypes working from a single larva. Identification of Trichinella genotypes will assist in distinguishing between sylvatic and synanthropic life cycles. Such information will be critical in tracing sources of trichinellosis by easily and unambiguously identifying likely host reservoirs and will provide valuable information for instituting methods of control.

Specificity and sensitivity of random amplified polymorphic DNA analysis for the identification of single larvae of Trichinella after experimental infection of pigs

Single muscle larvae (ML) of Trichinella belonging to 5 species and 2 genotypes collected from 126 experimentally infected pigs and preserved in 75% ethyl alcohol at room temperature were identified by random amplified polymorphic DNA (RAPD) analysis to evaluate the specificity and sensitivity of this assay. A double-blind protocol was used to ensure that the interpretation of electrophoretic patterns after RAPD amplification was not influenced by an expected result. RAPD analysis of one larva from each sample showed a sensitivity of 100% when only samples with undamaged DNA were considered, and the specificity resulted in an 88% match with the species or genotype that had been used to infect pigs, whereas the identification reached 100% specificity when an additional one to four ML were examined.

Polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) for the identification of Trichinella isolates

In the present study, polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) analysis was developed to identify 5 species (Trichinella spiralis, Trichinella britovi, Trichinella nativa, Trichinella nelsoni and Trichinella pseudospiralis) and 3 phenotypes of uncertain taxonomic status (Trichinella T5, T6, and T8). Eleven restriction endonucleases were used to restrict 3 DNA fragments (1) a 2800 bp fragment of the 43 kDa excretory-secretory (E-S) protein gene, (2) a 1250 bp fragment amplified with the primer pair SB147A and (3) a 372 bp fragment amplified with the primer pair SB372A. This RFLP method allows the identification of the 8 Trichinella phenotypes as follows: T. spiralis by the HinfI or DdeI endonuclease restriction of the 2800 bp fragment; T. nativa by the RsaI restriction of the 2800 bp fragment, or by the AluI restriction of the 1250 bp fragment; T. britovi and Trichinella T8 by the AluI restriction of the 1250 bp fragments, and can be discriminated between them by the SspI restriction of the 2800 bp fragment; T. pseudospiralis by the MspI restriction of the 372 bp fragment; T. nelsoni by the HhaI or AluI restriction of the 2800 bp fragment; Trichinella T5 by the HhaI restriction of the 2800 bp fragment; Trichinella T6 by the AluI restriction of the 1250 bp fragment; and Trichinella T8 by the SspI or RsaI restriction of the 2800 bp fragment. This study reveals also an intraspecifies polymorphism in the 2800 bp and 1250 bp fragments for T. britovi, Trichinella T5 and T6.

Trichinella britovi in foxes in The Netherlands

An overall prevalence of 3.9% of Trichinella infection was observed in the fox population in The Netherlands. Random amplified polymorphic DNA analysis of individual muscle larvae demonstrated the presence of Trichinella britovi. This is the first report of T. britovi, etiological agent of sylvatic trichinellosis, in one of the most densely populated countries in Europe and, consequently, the occurrence of cannibalism and scavenger behavior of foxes in areas with a high human population density. The presence of T. britovi in the fox population in these areas appears to be without consequences for commercial pig farming.

The detection of Trichinella with polymerase chain reaction (PCR) primers constructed using sequences of random amplified polymorphic DNA (RAPD) or sequences of complementary DNA encoding excretory-secretory (E-S) glycoproteins

Diagnostic PCR primers for Trichinella were constructed. Twelve pairs of primers were designed based on the sequences of random amplified polymorphic DNA, and 4 pairs of primers were designed based on the reported sequences of complementary DNA encoding excretory-secretory glycoproteins. With these primers, 31 samples of DNA from different strains of Trichinella including 5 species (Trichinella spiralis, Trichinella britovi, Trichinella nativa, Trichinella nelsoni and Trichinella pseudospiralis) and 3 phenotypes of uncertain taxonomic level (Trichinella T5, T6 and T8) were tested with PCR. Genus Trichinella can be identified by 4 different primer pairs (SB147D, SB372A, SB153, or Ts43). Trichinella spiralis can be identified by the presence of a 673 bp amplicon in PCR with the primer pair SB147B. Trichinella nelsoni can be identified using primer pair SB147F or by the presence of 673 bp and ca. 380 bp amplicon in PCR with the primer pair SB147B. Trichinella pseudospiralis can be identified by 2 primer pairs (SB147E or SB372B). Trichinella T5 can be identified by the primer pair SB147G. Trichinella T8 can be identified by its positivity by the primer pair SB147C and its negativity by the primer pair SB372C. A group of Trichinella species (T. britovi, T. nativa and Trichinella T6) can be identified by the primer pair SB372C.