Sylvatic and domestic Trichinella spp. in wild boars; infectivity, muscle larvae distribution, and antibody response

Thirty-six wild boars were inoculated with Trichinella spiralis, Trichinella nativa, Trichinella britovi, Trichinella pseudospiralis (USSR), T. pseudospiralis (USA), T. pseudospiralis (AUST), Trichinella murrelli, Trichinella T6, and Trichinella nelsoni. The wild boars were killed at 5 and 10 wk postinoculation (PI), and the number of muscle larvae per g (lpg) of tissue was determined for 18 muscles or muscle groups. Five weeks PI, all Trichinella genotypes had established as muscle larvae, but their infectivity varied widely: T. spiralis established in high numbers (mean = 296 lpg), T. britovi, T. nelsoni, and 1 of the T. pseudospiralis genotypes (AUST) in moderate numbers (mean = 53-74 lpg), whereas the remaining genotypes were poorly infective (mean 2-16 lpg). Because of considerable weight gain of the wild boars, an estimated total larval burden (live weight x lpg) was calculated for each animal. The total larval burden did not change significantly over time for T. spiralis, T. murrelli, T. britovi, T. nelsoni, and T. pseudospiralis (USA and USSR), whereas a significant reduction could be demonstrated for T. nativa, Trichinella T6, and T. pseudospiralis (AUST). Diaphragm and tongue were predilection sites in wild boars, independent of Trichinella genotype and infection level. At low infection levels, a greater percentage of larvae were found in diaphragm and tongue at 10 wk than 5 wk PI. Antibody responses increased rapidly between weeks 3 and 5 PI. For T. spiralis and T. nelsoni, the high antibody level persisted throughout the experimental period, but for T. nativa, T. britovi, T. murrelli, or Trichinella T6, the levels declined. For T. pseudospiralis, the antibody response increased more gradually between weeks 3 to 10 PI. Infection with all genotypes of Trichinella were detected using any of 7 excretory-secretory antigens, which points to the potential use of 1 common antigen for epidemiological studies on Trichinella in wild boars. In conclusion, T. spiralis is highly infective to wild boars, T. britovi, T. nelsoni, T. pseudospiralis (USA), and T. pseudospiralis (USSR) are moderately infective, and T. nativa, T. murrelli, T. pseudospiralis (AUST), and Trichinella T6 are poorly adapted to this host species.     

Muscle fiber selectivity of Trichinella spiralis and Trichinella pseudospiralis (1983)

The biceps, semimembranosus, biceps femoris, and soleus muscles of female Rockland Wistar mice infected with either 1,000 Trichinella spiralis or 1,000 Trichinella pseudospiralis larvae were removed on days 12, 14, 16, and 18 post-infection (PI), sectioned and stained histochemically for their myosin ATPase activity. Light microscopic examination of the sections revealed that larvae of T. spiralis invade only the slow twitch muscle fibers, and those of T. pseudospiralis invade both the fast twitch and the slow twitch fibers. In sections obtained from mice infected with either parasite and killed on days 16 and 18 PI, identification of the majority of the infected fibers as fast twitch or slow twitch was not possible due to pathological modification of infected fibers.     

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.     

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.     

Tolerance to low temperatures of domestic and sylvatic Trichinella spp. in rat muscle tissue

The present study was designed to investigate the tolerance to low temperatures of 9 Trichinella isolates in rat muscle tissue. Nine groups of 24 rats were infected with encapsulated Trichinella spiralis, Trichinella nativa, Trichinella britovi, Trichinella murrelli, Trichinella T6, Trichinella nelsoni, and 3 nonencapsulated Trichinella pseudospiralis strains. Six rats from each of the groups were necropsied at 5, 10, 20, and 40 wk postinfection (wpi). Muscle tissues containing Trichinella larvae were exposed to temperatures of -18, -5, and 5 C for 1 or 4 wk, and afterward the reproductive capacity index (RCI) in mice was determined for the 9 individual Trichinella isolates. Only T. nativa muscle larvae were infective after freezing at a temperature of -18 C. At 5 wpi all encapsulated isolates, except for the tropical species T. nelsoni, remained infective after exposure to a temperature of -5 C for both 1 and 4 wk, whereas nonencapsulated T. pseudospiralis survived only 1 wk of exposure. All Trichinella spp. remained infective after exposure to a temperature of 5 C. Muscle larvae for all investigated species remained infective as long as they persisted in live rats during the experiment. Analysis of variance showed a significant effect of age on the temperature tolerance of encapsulated T. spiralis and nonencapsulated T. pseudospiralis. In addition, significant interaction between age of muscle larvae and length of exposure was found. In general Trichinella muscle larvae of medium age (10 and 20 wpi) tolerated freezing better than early and late stages of infection (5 and 40 wpi). This is the first study to demonstrate such a relationship between age of infection and temperature tolerance of Trichinella spp. muscle larvae.     

Stimulated chemotactic response in neutrophils from Trichinella pseudospiralis-infected mice and the neutrophilotactic potential of Trichinella extracts.

During infection with Trichinella pseudospiralis a strong neutrophil response is evident in the peripheral circulation of the mouse. This study compared the chemotactic response of neutrophils from uninfected, T. pseudospiralis-infected and Trichinella spiralis-infected mice to extracts from adult worms, newborn larvae and muscle-stage larvae of both species of parasite. The chemotactic response of neutrophils from T. pseudospiralis-infected mice to Zymosan-activated mouse serum (ZAMS) was significantly greater than that seen with neutrophils from either uninfected or T. spiralis-infected mice. Unstimulated chemotactic response of neutrophils from these three groups of animals to medium alone was similar. The chemotactic response of neutrophils from the three groups of animals was unaffected by either the concentration or source of serum. The chemotactic response of neutrophils from T. pseudospiralis-infected mice was significantly greater than that observed with cells from uninfected or T. spiralis-infected mice. Among parasite extracts, those from newborn larvae displayed the strongest chemotactic potential for neutrophils. Extracts from muscle larvae of T. spiralis and T. pseudospiralis and extracts of T. spiralis adult worms showed the weakest attraction for neutrophils. Extracts from adult T. pseudospiralis and from newborn larvae of both species elevated the chemotactic response of uninfected mouse neutrophils to a significantly greater level than that seen with ZAMS alone, while a significant reduction in this response was evident only when ZAMS was presented to neutrophils with 500 micrograms of extract from muscle larvae of T. pseudospiralis or T. spiralis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Differentiation between Trichinella spiralis and T. pseudospiralis infective larvae by a monoclonal antibody

Crude saline extracts of Trichinella spiralis and T. pseudospiralis infective larvae were studied by Western blot analysis using a monoclonal antibody, named ES/TA2 and produced against T. spiralis larvae. This monoclonal antibody recognized seven major antigenic components in T. spiralis larvae with apparent Mr: 45, 48, 50, 68, 70, 92 and 105 kDa and five in T. pseudospiralis larvae: 38, 50, 70, 72 and 92 kDa. SDS-PAGE of both extracts did not reveal appreciable differences in the range of molecular weights recognized by ES/TA2. These facts show the existence of immunological differences among proteins with apparently identical molecular weights.     

Biological variation in Trichinella species and genotypes

At present, the genus Trichinella comprises seven species of which five have encapsulated muscle larvae (T. spiralis, T. nativa, T. britovi, T. nelsoni and T. murrelli) and two do not (T. pseudospiralis and T. papuae) plus three genotypes of non-specific status (T6, T8 and T9). The diagnostic characteristics of these species are based on biological, biochemical and genetic criteria. Of biological significance is variation observed among species and isolates in parameters such as infectivity and immunogenicity. Infectivity of Trichinella species or isolates is determined, among other considerations, by the immune status of the host in response to species- or isolate-specific antigens. Common and particular antigens determine the extent of protective responses against homologous or heterologous challenge. The kinetics of isotype, cytokine and inflammatory responses against T. spiralis infections are isolate-dependent. Trichinella spiralis and T. pseudospiralis induce different dose-dependent T-cell polarizations in the early host response, with T. spiralis initially preferentially promoting Th1-type responses before switching to Th2 and T. pseudospiralis driving Th2-type responses from the outset.     

Alterations in the longevity and fecundity of adult Trichinella pseudospiralis related to method of isolation of infective larvae

The infectivity of Trichinella pseudospiralis infective larvae was reduced significantly following exposure to low pH or a combination of 1% pepsin at low pH compared to that for larvae isolated in phosphate-buffered saline (PBS) at pH 7.0. Reduction of host gastric pH by administration to mice of sodium bicarbonate solution in PBS was accompanied by an increase in the infectivity of larvae isolated in 1% pepsin/HCl (P/HCl) compared to that for worms inoculated into hosts given PBS alone. Fewer adult worms developing from larvae isolated in P/HCl became established in the host small bowel than was seen with larvae isolated in PBS; moreover, the fecundity in vitro of adult worms developing from P/HCl-isolated larvae was reduced below that for adults developing from larvae isolated from host muscle in PBS. More adult worms were recovered following infection of immune hosts with PBS-isolated larvae than were recovered from immune mice challenged with larvae isolated in P/HCl. Similar findings were observed in mice immunized by infection with Trichinella spiralis and challenged with T. pseudospiralis larvae isolated in either P/HCl or PBS. Immunization of mice with T. pseudospiralis larvae isolated by either method and challenged with larvae of T. spiralis resulted in recovery of similar percentages of the challenge inoculum.     

A mechanism for anti-asialo GM 1 antibody-induced anaphylactoid response in mice infected with Trichinella pseudospiralis

Intravenous injection of anti-asialo GM 1 antibody into mice infected with Trichinella pseudospiralis resulted in rapid acute illness or death accompanied by a dramatic rise in hematocrit values in these animals. The described antibody-induced changes were reversible by intravenous infusion of Hanks' balanced salt solution (HBSS). These effects were not seen in uninfected mice or in Trichinella spiralis-infected mice injected with anti-asialo GM 1 antibody. Viability of T. spiralis or T. pseudospiralis infective L1 larvae, both isolated worms and those housed in muscle, was unaffected by exposure to anti-asialo GM 1 antibody and complement. Infectivity of larvae of T. pseudospiralis decreased significantly following exposure to anti-asialo GM 1 antibody. Release of protein by T. pseudospiralis infective L1 larvae during incubation in the presence of anti-asialo GM 1 antibody was significantly greater than that released by worms incubated in normal rabbit serum or HBSS. Protein released by infective L1 larvae of T. pseudospiralis was identified as Trichinella excretory/secretory antigens by immunoblot. Intravenous injection of T. pseudospiralis excretory/secretory products resulted in anaphylaxis in T. pseudospiralis-infected mice but not in uninfected or T. spiralis-infected mice. Excretory/secretory product-induced anaphylactoid response also was reversible by the intravenous injection of HBSS or by injection of an antihistamine. Significantly higher levels of total IgE were observed in sera from mice infected with T. pseudospiralis compared to uninfected or T. spiralis-infected mice. Binding of anti-asialo GM 1 antibody to the surface of T. pseudospiralis muscle larvae induced release of excretory/secretory antigen by the parasite.(ABSTRACT TRUNCATED AT 250 WORDS)     

Nonenzymatic isolation of Trichinella pseudospiralis infective L1 larvae at pH 7.4

Over half of the number of Trichinella pseudospiralis infective L1 larvae recovered from host carcasses by pepsin-HCl digestion were isolated from homogenized carcasses incubated in HBSS. More worms isolated by the latter method were viable compared to those isolated by pepsin-HCl digestion. When host carcasses infected with T. pseudospiralis were diced into pieces and incubated in HBSS, 30% more worms were recovered than from homogenized carcasses incubated in HBSS as above, and the majority of worms acquired by the former method were viable. The infectivity of T. pseudospiralis infective L1 larvae isolated from homogenized muscle in HBSS was 3.9 times greater than that for larvae recovered from homogenized carcasses by pepsin-HCl digestion. Only 4% and 0.8% of the number of T. spiralis recovered from homogenized muscle by pepsin-HCl digestion were isolated from homogenized or diced muscle incubated in HBSS, respectively. Fewer T. spiralis isolated from homogenized tissue in HBSS were viable compared to those recovered from homogenized carcasses digested in pepsin-HCl or diced carcasses incubated in HBSS.     

Detection of Trichinella spiralis, T. britovi and T. pseudospiralis in muscle tissue with real-time PCR

Infections caused by Trichinella species occur throughout the world in many wild and domestic animals resulting in trichinellosis in men. In Europe, domestic pigs are predominantly infected by three Trichinella species: T. spiralis, T. britovi and T. pseudospiralis. Present methods for detection of Trichinella spp. (compressorium method, artificial digestion) do not always sufficiently recognize Trichinella larvae and these techniques are labor-intensive, time consuming and do not differentiate isolates on the species level since there are no distinguishing morphological features. Additionally, conventional PCRs cannot quantify numbers of larvae in infectious material. In order to better meet these requirements, we developed a real-time PCR assay for the accurate, rapid and specific identification of the three common European species of the genus Trichinella. The assay targets the large subunit of the mitochondrial rRNA (rrnL) and enables sensitive determination and discrimination of larvae in muscle tissue samples. The real-time PCR assay was developed and validated using reference and field strains from T. spiralis, T. britovi and T. pseudospiralis. In the described real-time PCR assay, the melting points of specific amplificates were always discernable via the melting curve from melting points of unspecific amplificates. This is important for the methods workflow because only C(T) values connected with the additional melting curve analysis allow a distinction of the individual species with confidence. The sensitivity of the technique enabled detection down to 0.1 Trichinella larva per gram meat sample. High disruption levels of tissues by mincing generally resulted in higher sensitivities than protocols without mincing. With its short completion time as well as accurate and specific detection of selected species this assay could become a convenient tool for the fast detection of Trichinella larvae in meat.     

Comparative analysis of the excretory-secretory proteome of the muscle larva of Trichinella pseudospiralis and Trichinella spiralis

The nematodes Trichinella spiralis and Trichinella pseudospiralis are both intracellular parasites of skeletal muscle cells and induce profound alterations in the host cell resulting in a re-alignment of muscle-specific gene expression. While T. spiralis induces the production of a collagen capsule surrounding the host-parasite complex, T. pseudospiralis exists in a non-encapsulated form and is also characterised by suppression of the host inflammatory response in the muscle. These observed differences between the two species are thought to be due to variation in the proteins excreted or secreted (ES proteins) by the muscle larva. In this study, we use a global proteomics approach to compare the ES protein profiles from both species and to identify individual T. pseudospiralis proteins that complement earlier studies with T. spiralis. Following two-dimensional gel electrophoresis, tandem mass spectrometry was used to identify the peptide spots. In many cases identification was aided by the determination of partial peptide sequence from selected mass ions. The T. pseudospiralis spots identified included the major secreted glycoproteins and the secreted 5'-nucleotidase. Furthermore, two major groups of T. spiralis-specific proteins and several T. pseudospiralis-specific proteins were identified. Our results demonstrate the value of proteomics as a tool for the identification of ES proteins that are differentially expressed between Trichinella species and as an aid to identifying key parasite proteins that are involved in the host-parasite interaction. The value of this approach will be further enhanced by data arising out the current T. spiralis genome sequencing project.     

Differences and similarities of nurse cells in cysts of Trichinella spiralis and T. pseudospiralis

The nurse cell in the cyst of Trichinella spiralis comprises at least two kinds of cytoplasm, derived from muscle or satellite cells, as indicated by the pattern of staining using regular dye (haematoxylin and eosin, or toluidine blue), alkaline phosphatase (ALP) expression, acid phosphatase (ACP) expression and immunostaining with an anti-intermediate filament protein (desmin or keratin). Muscle cells undergo basophilic changes following a T. spiralis infection and transform to the nurse cells, accompanied by an increase in ACP activity and the disappearance of desmin. Satellite cells are activated, transformed and joined to the nurse cells but remain eosinophilic. The eosinophilic cytoplasm is accompanied by an increase in desmin and ALP expression but not an increase in ACP activity. Differences in the staining results for ALP or ACP suggest that the two kinds of cytoplasm have different functions. Trichinella pseudospiralis infection results in an increase of ACP activity at a later stage than T. spiralis. There is also a difference in the location pattern of ACP in the cyst of T. spiralis compared with T. pseudospiralis. In T. spiralis, ACP is diffused within the cell, but in T. pseudospiralis, ACP distribution is spotty corresponding to the location of the nucleus. Trichinella pseudospiralis infection is accompanied by a slight increase in ALP activity. Activated satellite cells following a T. pseudospiralis infection exhibit an increase in desmin expression. The present study therefore reveals that nurse cell cytoplasm differs between the two Trichinella species and between the two origins of cytoplasm in the cyst of T. spiralis.     

Studies on the cryopreservation of Trichinella species

Methods for the cryopreservation of different stages of Trichinella parasites have been studied. For the cryopreservation of muscle stage larvae (MSL) of T. spiralis s.str. and T. nativa, four cryoprotectants were tested: dimethylsulfoxide, ethanediol, hydroxyethyl starch, and polyvinylpyrrolidone at different concentrations, times, and temperatures of incubation. The cooling rate was approximately 0.6 C min-1. After thawing and an incubation period of 3 hr, a high percentage (80%) of cryopreserved MSL were motile but were not infective for mice. For the cryopreservation of newborn larvae (NBL) of T. spiralis s.str., T. nativa, T. nelsoni, and T. pseudospiralis, 10% dimethylsulfoxide was used as cryoprotectant incubated at 37 C for 15 min. The cooling rate was also 0.6 C min-1. After storage in liquid nitrogen, thawing, and incubation of NBL in culture medium for 3 hr, 80% of NBL were motile. An average of 8% of T. spiralis, 6% T. nativa, and 0.5% T. pseudospiralis developed into MSL in mice. No cryopreserved NBL of T. nelsoni developed into MSL. Compared to unfrozen control groups NBL infectivity was 33% for T. spiralis, 21% for T. nativa, and 2% for T. pseudospiralis.     

Biological characterization of Trichinella isolates from various host species and geographical regions.

Forty isolates of Trichinella collected from 5 continents were compared for 7 biological characters: newborn larvae produced per female worm cultured in vitro at the seventh, eighth, and ninth day postinfection, host muscle nurse cell development time, reproductive capacity index in rats and chickens, and resistance of muscle larvae to freezing. The isolates also were compared by analyses of an environmental character of the location from which they were isolated: the isotherms for January and July. By factorial analysis of correspondence of the biological and environmental data, the 40 isolates were grouped into 8 gene pools (T1-T8). The environmental temperature-related distribution was more evident for the sylvatic isolates (T2, T3, T5, T6, T7, T8), than for T1, which was isolated from domestic pigs, and for T4, a bird-adapted, nonencapsulating genetic type. The 8 biological groups correlated closely with the 8 gene pools previously identified on the basis of allozyme analysis. These results support the concept that the genus Trichinella is composed of at least 5 distinct gene pools or sibling species: Trichinella spiralis sensu stricto (T1), Trichinella nativa (T2), Trichinella sp. (T3), Trichinella pseudospiralis (T4), and Trichinella nelsoni (T7), and 3 other groups of uncertain taxonomic status (i.e., T5, T6, and T8).     

Ribo HRM--detection of inter- and intra-species polymorphisms within ribosomal DNA by high resolution melting analysis supported by application of artificial allelic standards

Ribo HRM, a single-tube PCR and high resolution melting (HRM) assay for detection of polymorphisms in the large subunit ribosomal DNA expansion segment V, was developed on a Trichinella model. Four Trichinella species: T. spiralis (isolates ISS3 and ISS160), T. nativa (isolates ISS10 and ISS70), T. britovi (isolates ISS2 and ISS392) and T. pseudospiralis (isolates ISS13 and ISS1348) were genotyped. Cloned allelic variants of the expansion segment V were used as standards to prepare reference HRM curves characteristic for single sequences and mixtures of several cloned sequences imitating allelic composition detected in Trichinella isolates. Using the primer pair Tsr1 and Trich1bi, it was possible to amplify a fragment of the ESV and detect PCR products obtained from the genomic DNA of pools of larvae belonging to the four investigated species: T. pseudospiralis, T. spiralis, T. britovi and T. nativa, in a single tube Real-Time PCR reaction. Differences in the shape of the HRM curves of Trichinella isolates suggested the presence of differences between examined isolates of T. nativa, T. britovi and T. pseudospiralis species. No differences were observed between T. spiralis isolates. The presence of polymorphisms within the amplified ESV sequence fragment of T. nativa T. britovi and T. pseudospiralis was confirmed by sequencing of the cloned PCR products. Novel sequences were discovered and deposited in GenBank (GenBank IDs: JN971020-JN971027, JN120902.1, JN120903.1, JN120904.1, JN120906.1, JN120905.1). Screening the ESV region of Trichinella for polymorphism is possible using the genotyping assay Ribo HRM at the current state of its development. The Ribo HRM assay could be useful in phylogenetic studies of the Trichinella genus.     

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.     

Characterization of a noncyst-forming isolate of Trichinella from a wild boar in Yugoslavia.

An isolate of Trichinella obtained from a wild boar in Yugoslavia did not form cysts in the musculature of its natural host. Subsequent inoculation into experimental hosts demonstrated that some larvae became encysted only after extended time periods, whereas others remained unencapsulated. Histological staining of larvae in the musculature demonstrated no deposition of collagen typically seen for Trichinella spiralis spiralis, Trichinella spiralis nativa, or Trichinella spiralis nelsoni. The Yugoslavian isolate, given the name of Zagreb isolate after the University where it was first studied, had low infectivity for pigs and mice. Isozyme analysis demonstrated greater homology with T. s. nelsoni than with other subspecies of Trichinella. Restriction fragment length polymorphisms and dot blot analyses further demonstrated the distinctive nature of this isolate. These results suggest that lack of cyst formation might be characteristic of isolates other than those designated Trichinella pseudospiralis and that this character might be important in the classification of Trichinella.