The relationship between intestinal location and fecundity in adult Trichinella spiralis.

Adult female worms recovered from the jejunum of rats infected per os with 1000 larvae of Trichinella spiralis were significantly more fecund (peak jejunal fecundity = 35.7 +/- 3.1 newborn larvae per female) than females recovered from the terminal ileum (9.3 +/- 4.1 larvae per female) in the same infections. The majority of the adult worms were established in those sections of the small intestines that produced the most fecund females (r = 0.92; P less than 0.05). Worm fecundity is believed to be location-specific because adult females that were surgically implanted into the jejunum were significantly more fecund that were implanted into only the ileum. It is concluded that the physico-chemical conditions of the anterior small intestines are optimal for the parasites' reproductive fitness and this exerts a strong selective pressure on habitat selection behavior.     

Trichinella spiralis: the worm that would be virus

Trichinella spiralis is one of the world's largest intracellular parasites. Unlike most such organisms, it does not kill the host cell, but induces modifications in cell structure that enhance its own survival. In this article, Dickson Despommier describes the ways in which the parasite uses the cell for its own benefit, and discusses the extent to which this behaviour has contributed to the parasite's success.     

Trichinella spiralis: quantitative relationships between intestinal worm burden, worm rejection, and the measurement of intestinal immunity in inbred mice

The effect of widely different doses of Trichinella spiralis muscle larvae on time to rejection of intestinal adults and on host survival was assessed in mice of the three rejection phenotypes; strong, intermediate, and weak. Rejection is weak with doses of less than 50 larvae per mouse. At these doses all mice rejected worms at a similar rate and no phenotypic variation was evident among strains. In contrast, rejection time was shortest for all strains and phenotypic variation among strains was evident in the range 50-100 muscle larvae/mouse. Above this dose the time taken to rejection increases monotonically with dose for all mouse strains examined. Despite this, the relative strength of rejection (i.e., phenotype) of a given strain of mouse was not changed at higher doses. Based on an end point of 98% rejection of the infective dose, time to rejection was predictable to +/- 1 day for all mouse strains and doses tested over the range 100-1000 worms administered. The principal reason for the increased time to complete rejection with larger worm doses was a delay in the initiation of intestinal rejection. This delay was evident above a dose of 50-100 larvae per mouse and occurred in all strains. Once begun, rejection was faster and eliminated more worms in unit time at higher doses (400-800 more) than at lower doses of worms. This appeared to be due to a stronger immune response of the host at higher doses. However, the increase in the rate of rejection was still not as great as the increase in the dose. We postulate that the delay in rejection with increased dose is due to a requirement for a "critical mass" of effectors/worm required to cause rejection. As dose increases, more time is required to reach the level at which worm rejection commences. Deaths due to higher doses of worms also occurred in a strain-specific manner and were temporally biphasic. The intestinal phase of infection produced mortality from 1 to 5 days after infection and the strongest rejection phenotype (NFS) was also the most resistant to intestinal deaths. Deaths occurring after Day 5 were due to the parenterally migrating newborn larvae. The weakest rejection phenotype, that of the B10 congenics, was also the least resistant to intestinal deaths. An experimental formula describing 98% worm rejection time with different doses was derived from the data.(ABSTRACT TRUNCATED AT 400 WORDS)     

Trichinella spiralis and Strongyloides ratti: immune interaction in adult rats.

The consequences of prior and concurrent infection with two species of nematodes were studied in rats. Primary infection with Strongyloides ratti adversely affected the development of a secondary Trichinella spiralis infection. Both immediate and delayed challenge with T. spiralis, following the expulsion of the previous S. ratti infection, reduced the percentage of worm recovery of the former as well as their fecundities and lengths. It is suggested that nonspecific inflammation produced by one species, during the peak period of worm expulsion, was not responsible for the accelerated rate of expulsion of the other; instead a direct, specific cross-immunity was probably operative affecting the survival of the challenge species. The response elicited by previous experience of the intestinal phase was reciprocal, but there was evidence of an enhancing effect by the muscle larval stages of T. spiralis on S. ratti. Rats concurrently infected with both species expelled S. ratti more rapidly than T. spiralis. Possible mechanisms underlying the interaction between the two species are suggested and discussed.     

Trichinella spiralis: immunity and inflammation in the expulsion of transplanted adult worms from mice.

The technique of implanting adult Trichinella spiralis into the intestines of mice has been used to assess the contributions of direct, anti-worm immunity and of intestinal inflammation to worm expulsion. The survival after transfer of worms exposed to an effective adoptive immunity in donors was no different from that of worms taken from control donors. Worms taken from donors 8 days after infection, i.e., shortly before the onset of expulsion, showed no increased susceptibility to an immunity adoptively transferred to the recipient mice. When worms were implanted into mice responding to a prior, oral infection they were expelled rapidly. This expulsion was independent of the age of the worms transferred and took place at the same time as the expulsion of the existing infection.     

The immune protection induced by a serine protease from the Trichinella spiralis adult against Trichinella spiralis infection in pigs

Trichinellosis is a major foodborne parasitosis caused by Trichinella spiralis. In the present study, a serine protease gene from an adult T. spiralis (Ts-Adsp) cDNA library was cloned, expressed in Escherichia coli and purified by Ni-affinity chromatography. Previous studies of our laboratory have found that mice vaccinated with recombinant Ts-Adsp protein (rTs-Adsp) exhibited partial protection against T. spiralis infection. In this study, the protective effect of rTs-Adsp against T. spiralis infection in pigs was further explored. The cell-mediated and humoral immune responses induced by rTs-Adsp were measured, including the dynamic trends of specific antibody levels (IgG, IgG1, IgG2a and IgM), as well as the levels of cytokines (IFN-γ, IL-2, IL-4, and IL-10) in the serum. Moreover, the changes in T lymphocytes, B lymphocytes, and neutrophils were measured to evaluate cellular immune responses in pigs vaccinated with rTs-Adsp. The results indicated that a Th1-Th2 mixed immune response with Th1 predominant was induced by rTs-Adsp after vaccination. Flow cytometric analysis showed that the proportions of CD4⁺ T cells, B cells, and neutrophils in the immunized groups were significantly increased. Furthermore, pigs vaccinated with rTs-Adsp exhibited a 50.9% reduction in the muscle larvae burden, compare with pigs from the PBS group five weeks after challenged. Our results suggested that rTs-Adsp elicited partial protection and it could be a potential target molecule for preventing and controlling Trichinella transmission from pigs to human.     

Biological and immunological characteristics of Trichinella pseudospiralis

In 1972 three new species were proposed for the genus Trichinella, which for 137 years had contained a single species, Trichinella spiralis (Owen,1835). One of these proposed species, Trichinella pseudospiralis, was markedly different from the others in that it was smaller in size, the muscle-stage larvae were not surrounded by a capsule, and it was capable of parasitizing birds. Owing to a lack of information on the normal host range, geographic distribution, biochemistry, immunology and normal variation in biological characteristics of these organisms, several authors supported the more conservative position of designating them sibling species, subspecies or races of Trichinella. The summary statement following the session on Parasite Genetics and Speciation at the 7th International Conference on Trichinellosis recommended that pseudospiralis be accepted as a new species of Trichinella. In this article George Stewart reviews the available information on the biological and immunological characteristics of T. pseudospiralis.     

The role of malic enzyme in the carbohydrate metabolism of Trichinella spiralis spiralis and Trichinella spiralis pseudospiralis

The role of malic enzyme in the carbohydrate metabolism of Trichinella spiralis spiralis and Trichinella spiralis pseudospiralis. International Journal for Parasitology16: 435–440. The activities, intracellular localization and some regulatory properties of malic enzymes from homogenates of T.s. spiralis and T.s. pseudospiralis larvae have been studied. The malate saturation curves exhibit sigmoidicity. With increasing pH a ‘double sigmoidicity’ was observed in both NAD- and NADP-specific malic enzyme from T.s.spiralis and Trichinella malic enzymes resemble the Ascaris enzyme in their nondecarboxylation of oxaloacetate and in nucleotide and ammonium sulphate sensitivity, but the enzyme from T.s. pseudospiralis differs in its equal specificity for NAD and NADP. The cytoplasmic localizations and some properties of phosphoenolpyruvate carboxykinase in both Trichinella species are similar to the characteristics of the same enzyme in Ascaris.     

Identification of Trichinella spiralis early antigens at the pre-adult and adult stages

Three expression cDNA libraries from Trichinella spiralis worms 14 h, 20 h and 48 h post-infection (p.i.) were screened with serum from pigs experimentally infected with 20,000 T. spiralis muscle larvae. Twenty-nine positive clones were isolated from the 14 h p.i. cDNA library, corresponding to 8 different genes. A putative excretory-secretory protein similar to that of T. pseudospiralis was identified. Three clones corresponded to a T. spiralis serine proteinase inhibitor known to be involved in diverse functions such as blood coagulation and modulation of inflammation. Screening of the 20 h p.i. cDNA library selected 167 positive clones representing 12 different sequences. The clone with the highest redundancy encoded a small polypeptide having no sequence identity with any known proteins from Trichinella or other organisms. Fourteen clones displayed sequence identity with the heat shock protein (HSP) 70. HSPs are produced as an adaptive response of the parasite to the hostile environment encountered in the host intestine but their mechanism of action is not yet well defined. From the 48 h p.i. T. spiralis cDNA library, 91 positive clones were identified representing 7 distinct sequences. Most of the positive clones showed high similarity with a member of a putative T. spiralis serine protease family. This result is consistent with a possible major role for serine proteases during invasive stages of Trichinella infection and host-parasite interactions.     

Genetic analysis of the relationship between interleukin production and worm rejection in Trichinella spiralis-infected inbred mice

The production of interleukin 1 (IL-1), IL-2, and IL-3 by peritoneal macrophages, mesenteric lymph node (MLN), or spleen cells from inbred strains of mice infected with Trichinella spiralis was examined. The mice belonged to the worm rejection phenotypes previously characterized as strong (NFS), intermediate (C3H, BUB, DBA/1, SWR, CBA, etc.), or weak (B10.Q, B10.BR, etc.). Strong responder NFS mice produced approximately twice as much IL-1 as intermediate responder C3Heb/Fe or weak responder B10.BR mice. IL-3 production varied slightly among strains but did not show any relationship to the phenotype of rejection (highest: C3Heb/Fe, B10.BR; lowest: B10.Q). Of 16 strains of inbred mice and 6 F1 hybrid crosses assessed, marked variations occurred in IL-2 production from MLN cells in response to T. spiralis antigen challenge in vitro. When 16 mouse strains were compared IL-2 production ranged from 5.1 units/ml (A/J) to 29.8 (NFS). Variations in IL-2 production among mouse strains did not relate directly to MHC haplotype, and the capacity of an individual strain to release IL-2 or IL-3 did not correlate with adult worm rejection phenotype. Genetic linkage studies proved that the gene(s) regulating IL-2 production in T. spiralis infection were not linked to the gene(s) regulating adult worm rejection. Regression analysis showed a weak correlation of high IL-2 production with weak worm rejection suggesting that IL-2 production or an associated process is a negative factor in primary worm rejection.     

Soluble metabolic antigens of Trichinella spiralis: their isolation and characteristics]

Cultivation of Trichinella muscular larvae, purified by centrifugation in 20 ... 50% saccharose density gradient, in protein--free nutrient media at a dosage of 3.5-.10(3) lar./ml in the presence of insulin has made it possible to obtain a soluble antigen of Trichinella. It has been shown by means of electrophoresis in polyacrylamide gel that the soluble (secretory-excretory) antigen has three protein fractions while the somatic Trichinella antigen has 18 fractions. It has been shown that the soluble (secretory-excretory) antigen can be used for immobilization of erythrocytes on the surface that enables the sensitivity and specificity of serological methods for diagnosis of trichinellosis to be increased.     

Ultrastructure, antigenicity, and histochemistry of stichocyte granules of adult Trichinella spiralis.

The stichosome of adult Trichinella spiralis was studied to determine its ultrastructural, antigenic, and histochemical characteristics. Stichocytes of adult worms had 2 types of granules, type I and type II, the ultrastructure of which was different from those of muscle larvae. Both types of granules consisted of a membrane surrounding a homogeneous matrix, and type I granules were rounder than type II granules. Sera from C3H mice immunized against excretory-secretory products of muscle larvae produced positive immunostaining of type I but not type II granules. Differences in antigenicity were observed between larval and adult stichocyte granules; monoclonal antibodies against alpha-granules of muscle larvae failed to label the adult granules. Azan staining revealed a histochemical difference between larval and adult stichocytes; adult stichocytes stained yellow, whereas larval stichocytes are known to stain red or blue. Thus, the present contribution revealed the existence of 2 distinct types of stichocyte granules in adult T. spiralis and showed them to differ profoundly from those characterized previously in muscle larvae.     

Chemical composition of newborn larvae, muscle larvae and adult Trichinella spiralis

Chemical composition of newborn larvae, muscle larvae and adult Trichinella spiralis. International Journal for Parasitology16: 455–460. The chemical composition of newborn larvae (NBL), muscle larvae (ML) and 4-day-old and 7-day-old adult Trichinella spiralis were compared. Total protein constituted 44.1% of the dry wt of ML, 36.9% of NBL and 30.3% of 7-day-old adult worms. Glycogen content was 16.1% of worm dry wt in ML and 7.8% in NBL and 7.2% of worm dry wt in adults. Trehalose content was 5.2% in NBL, 8.3% in ML and 8.7% in 7-day-old adult worms. Significantly lower levels of trehalose and glycogen were found in 4-day-old worms than were present in 7-day-old worms. Free glucose amounted to 0.1% of dry wt in ML, 0.37% in NBL and 0.87% in 7-day-old adults. RNA accounted for 3.5% of the dry wt of ML, 3.2% of the dry wt of 7-day-old adults and 1.1% of the dry wt of NBL. The DNA content of NBL was 0.23% of worm dry wt, in ML 0.48% of worm dry wt and 0.51% of worm dry wt in 7-day-old adults. The three parasite stages examined agreed closely with regard to types of amino acids in the free pool. Exceptions were as follows: NBL lacked taurine which both adults and ML contained; adults lacked methionine which both ML and NBL contained; and, trace amounts of cysteine were present in ML but absent from the other two stages.