Trichinella spiralis: skeletal muscle membrane potentials in infected and uninfected mice

Male albino mice were infected orally with 400 ± 10 excysted Trichinella spiralis larvae. Skeletal muscle resting membrane potentials were recorded from the tibialis anterior muscles of infected and uninfected mice on the following days postinfection (PI): 1–15, 18, 20, 24, 28, 30–60 (at 5-day intervals), 90, 120, 150, and 180. The membrane potentials were significantly (P < 0.05) lower in infected muscle (82 vs 85 mV) on Day 30 PI. On Days 60, 90, 120, 150, and 180 PI the mean membrane potential in infected muscle (62 mV) was about 23 mV lower than the mean for uninfected muscle (85 mV) and this difference was highly significant (P < 0.001). These findings are discussed in relationship to other physiological alterations known to occur in skeletal muscles infected with T. spiralis larvae.     

Trichinella spiralis: comparison of stages in host intestine with those of an Arctic Trichinella sp

The intestinal phase of Trichinella spiralis and of Trichinella sp. isolated in the Arctic were compared in experimental animals. Reproductive capacity, pathogenicity, distribution, and persistence of adults in the small intestine, morphological measurements, and release of newborn larvae in vitro were examined. Numerous passages of 40 days each for T. spiralis and the Trichinella sp. isolate in mice did not affect reproductive capacity, distribution of adults in the small intestine, and size of worms. Reproductive capacity index for T. spiralis, I = 151.27 ± 27.30 was significantly higher compared to the Trichinella sp. isolate index, I = 63.46 ± 19.34. The Trichinella sp. isolate was more pathogenic to mice and wild rodents compared to T. spiralis during the intestinal phase. Both parasites were located in the anterior part of the small intestine but the position of T. spiralis adults (P = 17.08) differed from position of the Trichinella sp. isolate adults (P = 23.46) in the small intestine. Intestinal phase of T. spiralis was longer (20 days) compared to the Trichinella sp. isolate (15 days) but sex ratios (:♂) were similar for both parasites. T. spiralis females released significantly higher numbers of larvae in vitro/24 hr compared to the Trichinella sp. isolate. Release of larvae was continuous during the intestinal phase and the average fecundity for T. spiralis was 335 larvae/female and for the Trichinella sp. isolate 114 larvae/female. Adults of T. spiralis and the Trichinella sp. isolate were morphologically indistinguishable and did not differ in size. A comparative index for the intestinal phase is proposed for comparison of any Trichinella spp. isolates and standard T. spiralis.     

Immunocytolocalization of two protection-inducing antigens of Trichinella spiralis during its enteral phase in immune and non-immune mice

Monoclonal antibodies (mAb) recognizing epitopes on the 48K (beta stichocyte specific) and the 50/55K antigen (alpha stichocyte specific) were used as first ligands for immunocytolocalization on de-paraffinized sections of infected gut tissue of non-immune and immune CFW strain mice. The enteral phase was studied at 6, 14, 23, 30 hr and 7 days after initiation of infection via the oral route, times corresponding in worm development to the first (L1), second (L2), and third (L3) stage larva and adult. No change in the intensity of the immune reaction with either mAb was noted in parasites developing within immune or non-immune mice for any of the time-points studied. The 48K and the 50/55K antigens were present within the stichocytes at 6 hr. Enterocytes adjacent to some worms also stained positive for both epitopes at this time. Throughout worm development, the amount of each antigen within the worm diminished, until almost none was left at 30 hr. At day 7, the 48K antigen was present within a few stichocyte cells, the canalicular tree, and within the lumen of the midgut. The 50/55K antigen at this time point was localized within only a few stichocyte granules and on the lining of the worm's gut. Embryo stages did not possess either the 48K or 50/55K epitopes. A marked increase in cells bearing IgG in the lamina propria was noted in immune mice when compared with their non-immune counterparts.     

Effect of the expulsion phase of Trichinella spiralis on Hymenolepis diminuta infection in mice

The rapid elimination of the intestinal phase of Trichinella spiralis in NIH mice is associated with progressive inflammation of the intestinal tract. The non-specific effects of this inflammation were studied in mice concurrently infected with an unrelated parasite, Hymenolepis diminuta, which does not stimulate a visible inflammatory response but is also immunologically rejected by this strain of mice. It was demonstrated that the rejection phase of T. spiralis infection had a marked effect upon the growth and survival of H. diminuta. The cestode either failed to establish or to grow; if the worms were already strobilate when inflammation developed then destrobilation occurred. There was no cross-immunity between the parasites, nor was the interaction a direct consequence of inter-specific competition.     

Novel albendazole formulations given during the intestinal phase of Trichinella spiralis infection reduce effectively parasitic muscle burden in mice

Trichinellosis is a zoonotic disease affecting people all over the world, for which there is no speedy and reliable treatment. Albendazole (ABZ), an inexpensive benzimidazole used in oral chemotherapy against helminthic diseases, has a broad spectrum activity and is well tolerated. However, the low absorption and variable bioavailability of the drug due to its low aqueous solubility are serious disadvantages for a successful therapy. In this study, we evaluated the in vivo antiparasitic activity of three novel solid microencapsulated formulations, designed to improve ABZ dissolution rate, in a murine model of trichinellosis. Both ABZ and the microparticulate formulations were administered during the intestinal phase of the parasite cycle, on days 5 and 6 post-infection. This protocol significantly decreased muscle larval burden measured in the parenteral phase, on day 30 post-infection, when compared with the untreated control. Moreover, two of the three microencapsulated formulations both strongly and consistently reduced worm burden.     

Trichinella spiralis: recognition of muscle larva antigens during experimental infection of swine and its potential use in diagnosis

Longitudinal studies with Trichinella spiralis experimentally infected pigs were carried out to identify muscle larva antigens recognized during infection. This was approached using Western blot analysis and ELISA assays. Immunoblots of sera from experimentally infected pigs using total parasite extracts revealed five principal parasite antigens throughout infection. A similar pattern of antigen recognition was given by sera from backyard pigs in areas of Mexico, some of them endemic for Trichinella. Four of the five antigens recognized (MW 47, 52, 67, and 72 kDa) corresponded to surface/stichosomal antigens purified by monoclonal antibody NIM-M1. In addition, Western blots of excretions-secretions of muscle larva contained three (MW 52, 67, and 72 kDa) of the four surface/stichosomal components recognized by NIM-M1. Affinity-purified surface/stichosomal components, total soluble extracts, and excretory-secretory antigens of muscle larva were then evaluated in ELISA for detection of T. spiralis infections in experimentally infected, noninfected control, and 295 backyard pigs. These assays showed that purified surface/stichosomal components and excretory-secretory antigens increased the specificity of ELISA. These results suggest that muscle larva components purified by monoclonal antibody NIM-M1 are the major antigens recognized during infection of pigs with T. spiralis and therefore potentially useful for diagnosis of swine trichinellosis.     

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.     

Trichinella spiralis: expression of rapid expulsion in rats exposed to an abbreviated enteral infection.

Rats infected with Trichinella spiralis for the first week of the enteral infectious cycle displayed a strong rapid expulsion reaction during a challenge infection. The response was induced with equal facility in animals given low or high immunizing doses of infectious larvae (500 to 5000 larvae). Large challenge infections resulted in a 10–15% reduction in the efficiency of rejection as assessed 24 hr after challenge. Rats became primed to express rapid expulsion within the first week of primary infection whether the infection remained patent or not. However, maximum effectiveness was not realized until the second week after the initial infection. Once induced, the capacity to express rapid expulsion persisted for 6 weeks after the primary infection. Immunized hosts were capable of resisting two challenge infections spaced by periods of from 12 to 72 hr. This finding suggests that a mediator is not consumed by the initial response.     

Trichinella spiralis: correlates in vitro of altered immune responsiveness in mice.

Mixed lymphocyte reactions and in vitro antibody responses to dinitrophenol (DNP) after immunization with DNP-Ficoll were measured in spleen cells from mice following infection with 200 Trichinella spiralis larvae. A depression of the mixed lymphocyte reaction was observed at 14 through 84 days after infection. A reduced response to concanavalin A stimulation was demonstrated over a similar time period, 7 through 63 days of infection. The addition of mitomycin C-treated spleen cells from mice infected with T. spiralis to cultures of normal splenocytes suppressed the mixed lymphocyte reaction by 28% to 65%. The antibody response to DNP-Ficoll immunization was enhanced 20 days after infection, a time when the T-dependent antibody response to sheep erythrocytes was depressed.     

Trichinella spiralis: anaphylactic antibody formation and susceptibility in strains of inbred mice.

The anaphylactic antibody response of various strains of inbred mice of different H-2 specificities was investigated using the passive cutaneous anaphylactic technique (PCA) for the detection of the antibody response. Neither IgC₁ nor reaginic antibody were detected in serum samples obtained at the end of the first week of infection with Trichinella spiralis. Subsequently, all animals had detectable IgG₁ antibodies, although in some strains the titers were very low. Reaginic antibody was detected in relatively high titers in C57L, A, and DBA/1 mice. Two other strains were very poor responders (SJL and AKR). In most strains, reagin and IgG₁ remained detectable for 14 wk or longer. The pattern of response of all strains was very reproducible, indicating genetic control of the anaphylactic antibody production to the infection. In F₁ hybrids obtained from crosses between good and poor anaphylactic antibody responders, intermediate levels of both antibody classes were detected.Adult worm recovery rates were established at various points during the intestinal phase of infection, and no correlation between worm numbers and reaginic antibody titers in the various strains of mice could be demonstrated. There were noticeable differences in larval yields obtained after muscle digestion of mice belonging to the different inbred strains. In fact, we generally observed an inverse relationship between the number of larvae recovered from a given strain and their reaginic antibody titer.The intravenous injection of newborn larvae (NBL), obtained upon in vitro incubation of adult worms, produced detectable antibodies only in mice of the DBA/1 strain. These antibodies were consistently of low titer and became detectable only after the administration of two additional injections of NBL. This contrasted with the results observed after “per os” infection of DBA/1 mice, where high titers of these antibodies were always obtained, in spite of comparable ratios of muscle larval yield.     

Trichinella spiralis: role of non-H-2 genes in resistance to primary infection in mice

Two strains of mice which share identical H-2 genes but differ in their genetic backgrounds were compared for their ability to resist infection with Trichinella spiralis. The two strains of mice, C3HeB/FeJ and AKR/J, share the H-2k haplotype which is associated with susceptibility to primary infection with T. spiralis in H-2 congenic strains of mice. AKR/J mice, infected with 150 infective muscle larvae, harbored significantly fewer muscle larvae 30 days postinfection than did mice of the strain C3HeB/FeJ. Approximately equal numbers of worms establish in the small intestine of AKR and C3H mice, but the AKR mice expelled adult worms from the gut more rapidly than did mice of the C3H strain. By Day 9 postinfection, 50% of the worms had been expelled by the AKR mice whereas expulsion of worms from C3H mice was delayed beyond Day 9 and occurred primarily between Days 10 and 12. Over this same experimental period (Days 6-12), fecundity of female worms from AKR mice, measured as the mean newborn larvae/female/hour, was approximately one-half that of worms taken from C3H mice. These results support the conclusion that genes outside of the mouse H-2 complex regulate expulsion of adult worms from the gut. These background genes also markedly influence the fecundity of female worms.     

Heligmosomoides polygyrus: inoculum size and glucose, ion, and gas fluxes in the small intestine of mice

Female CDI mice were inoculated with 10, 50, 100, 250, or 500 larvae of Heligmosomoides polygyrus. At Days 7, 9, and 12 after infection, the anterior third of the small intestine was perfused using an in vivo technique. The distribution of worms in the mouse intestine was determined after 7, 9, and 12 days. All worms that were recovered were from the proximal half of the small intestine. When compared to uninfected controls, there was a significant increase (+56%) in glucose absorption of the small intestine at Day 7 after infection with inocula of 50 and 100 larvae; at Day 9, glucose absorption was significantly increased with a 10-larvae inoculum. A decrease in glucose absorption occurred at Days 7 and 9 after infection with a 500-larvae inoculum. Net water absorption was significantly increased (+183%) with the 50- and 100-larvae inocula at Day 7, but was significantly reduced at Day 9 after infection with the 50-, 100-, 250-, and 500-larvae inocula. Both Cl- and Na+ absorption were significantly increased with the 50-, 100-, and 250-larvae inocula at Day 7 after infection; at 9 and 12 days, there was significant net secretion of both ions. In control mice, there was net secretion of K+, while with the 50-, 100-, and 250-larvae inocula on Day 7 there was significant net absorption of K+ ions.(ABSTRACT TRUNCATED AT 250 WORDS)     

Adoptive transfer of immunity to Trichinella spiralis in mice: generation of effective cells by different life cycle stages

Adoptive transfer of immunity with day 8 mesenteric lymph node cells (MLNC) taken from NIH mice after a chemically abbreviated infection of 3 days duration was as effective as transfer with cells taken from mice which had received an uninterrupted infection. Using a surgical transplantation technique it was demonstrated that adult T. spiralis were not capable of stimulating cells effective upon adoptive transfer. The potent immunogenicity of the early stages of infection was emphasized by data showing that very low numbers of muscle larvae were efficient in stimulating effective mediator cells. Neither the time at which MLNC were taken for transfer after transplantation of adult worms nor the age of adult worms transplanted affected the failure of this life cycle stage to stimulate cells capable of mediating worm expulsion. It is proposed that expulsion of T. spiralis from the gut may be achieved by more than one effector mechanism, and that early and late intestinal stages stimulate these mechanisms differentially.     

Alterations in intercellular junctions of the uterine epithelium during the preimplantation phase in the rabbit

Summary In the rabbit, the pseudopregnant uterus has been used as a model for studying alterations characteristic of the preimplantation phase. Alterations in intercellular junctions of the uterine epithelium were investigated during early pseudopregnancy (day 0 to day 6) by means of the freeze-fracture technique.In the uterine epithelium of oestrous females the zonula occludens belongs to the tight type of tight junctions. During pseudopregnancy an impressive proliferation of tight junctional belts can be observed. The basal strands proliferate, forming loops perpendicular to the luminal surface, whereas the more or less parallel arrangement of the luminal strands is maintained. At day 4 of pseudopregnancy macular tight junctions begin to develop on the lower portions of the lateral plasmalemma and are extensive by day 6 post hCG.Small gap junctions are infrequent between cells of the uterine epithelium and show no significant changes during the preimplantation phase.The physiological significance of the present morphological observations is discussed in the light of changes occurring during the preimplantation period.Supported by grant Kü 210/9 from the Deutsche Forschungsgemeinschaft     

Trichinella spiralis: activity of the cerebral pyruvate recycling pathway of the host (mouse) in hypoglycemia induced by the infection

The activity of the cerebral pyruvate recycling pathway and energy metabolism in mice infected with Trichinella spiralis were investigated using (13)C-NMR and in vivo (31)P-NMR spectroscopy, respectively. The (13)C-NMR analysis, using [1,2-(13)C(2)] acetate as a substrate, of whole-brain extracts demonstrated that activity of the pathway increased when T. spiralis infection induced hypoglycemia in the host. The in vivo (31)P-NMR observation showed that the cerebral ATP in normal level sustained throughout this experiment. These findings indicate that the pyruvate recycling pathway plays a role in the energy supply to the host in hypoglycemia induced by T. spiralis infection.     

Restoration of the acute phase response after infection in cyclophosphamide-treated mice by granulocyte colony-stimulating factor

The therapeutic effect of granulocyte colony-stimulating factor (G-CSF) against intramuscular infection withPseudomonas aeruginosa in cyclophosphamide (CY)-treated mice was analyzed by measuring plasma levels of amyloid P-component (APC) and proinflammatory cytokine levels. CY (100mg/kg) treatment of mice significantly suppressed plasma concentrations of APC and tumor-necrosis factor- (TNF-) following infection withP. aeruginosa, in associated with enhanced susceptibility of the treated mice to this bacterium. A 4-day treatment of CY-treated mice with recombinant human G-CSF (rhG-CSF) increased resistance of CY-treated mice, together with the marked restoration of APC and TNF- productions. The capacity to produce interleukin 1- and TNF- of peritoneal macrophages and also that to produce IL-6 of spleen cells were significantly enhanced by thein vivo administration of rhG-CSF in CY-treated mice. These results indicate that G-CSF may increase the functions of monocytes/macrophages directly or indirectlyin vivo. Therefore, the therapeutic effect of rhG-CSF seems to consist of not only increases in the number and functions of neutrophills but also enhancement of monocyte/macrophage functions.Abbreviations rhG-CSF recombinant human granulocyte-colony stimulating factor - PMNs polymorphonuclear leukocytes - CY cyclophosphamide - HBSS Hanks' balanced salt solution - APC amyloid P-component - IEP immunoelectrophoresis - CFU colony-forming units - TNF- tumor-necrosis factor- - d IL interleukin     

Viral load in tissues during the early and chronic phase of non-pathogenic SIVagm infection

African green monkeys (AGMs) persistently infected with SIVagm do not develop AIDS, although their plasma viremia levels can reach those reported for pathogenic HIV-1 and SIVmac infections. In contrast, the viral burden in lymph nodes in SIVagm-infected AGMs is generally lower in comparison with HIV/SIVmac pathogenic infections, at least during the chronic phase of SIVagm infection. We searched for the primary targets of viral replication, which might account for the high viremias in SIVagm-infected AGMs. We evaluated for the first time during primary infection SIVagm dissemination in various lymphoid and non-lymphoid tissues. Sixteen distinct organs at a time point corresponding to maximal virus production were analyzed for viral RNA and DNA load. At days 8 and 9 p.i., viral RNA could be detected in a wide range of tissues, such as jejunum, spleen, mesenteric lymph nodes, thymus and lung. Quantification of viral DNA and RNA as well as of productively infected cells revealed that viral replication during this early phase takes place mainly in secondary lymphoid organs and in the gut (5 x 10(4)-5 x 10(8) RNA copies/10(6) cells). By 4 years p.i., RNA copy numbers were below detection level in thymus and lung. Secondary lymphoid organs displayed 6 x 10(2)-2 x 10(6) RNA copies/10(6) cells, while some tissue fragments of ileum and jejunum still showed high viral loads (up to 10(9) copies/10(6) cells). Altogether, these results indicate a rapid dissemination of SIVagm into lymphoid tissues, including the small intestine. The latter, despite showing marked regional variations, most likely contributes significantly to the high levels of viremia observed during SIVagm infection.     

Identification of G2/M phase transition by sequential nuclear and cytoplasmic changes and molecular markers in mice intestinal epithelial cells

Although the regulatory network of G2/M phase transition has been intensively studied in mammalian cell lines, the identification of morphological and molecular markers to identify G2/M phase transition in vivo remains elusive. In this study, we found no obvious morphological changes between the S phase and G2 phase in mice intestinal epithelial cells. The G2 phase could be identified by Brdu incorporation resistance, marginal and scattered foci of histone H3 phosphorylated at Ser10 (pHH3), and relatively intact Golgi ribbon. Prophase starts with nuclear transformation in situ, which was identified by a series of prophase markers including nuclear translocation of cyclinB1, fragmentation of the Golgi complex, and a significant increase in pHH3. The nucleus started to move upwards in the late prophase and finally rounded up at the apical surface. Then, metaphase was initiated as the level of pHH3 peaked. During anaphase and telophase, pHH3 sharply decreased, while Ki67 was obviously bound to chromosomes, and PCNA was distributed throughout the whole cell. Based on the aforementioned markers and Brdu pulse labeling, it was estimated to take about one hour for most crypt cells to go through the G2 phase and about two hours to go through the G2-M phase. It took much longer for crypt base columnar (CBC) stem cells to undergo G2-prophase than rapid transit amplifying cells. In summary, a series of sequentially presenting markers could be used to indicate the progress of G2/M events in intestinal epithelial cells and other epithelial systems in vivo.