Eosinophilia in chimeric mice infected with Toxocara canis

A marked strain variation in eosinophilia following oral infection with Toxocara canis eggs was observed in mice. Mutual radiation chimeras between high and low responder mice in terms of eosinophilia were made and compared with the respective donor and recipient for eosinophilia after the infection. As a result, the degree and time course of eosinophilia in chimeric mice were similar to those in donors. The result suggested that genes which regulate inheritance of the trait, marked eosinophilia in T. canis-infected mice, might be expressed in bone marrow derived cells.     

Ascaris suum: immunoglobulin responses in mice

The immune response in mice to infection with Ascaris suum was characterized by determining (1) changes in serum immunoglobulin levels and (2) changes in the relative proportions of immunoglobulin-containing cells in major lymphoid tissues and sites of possible local immunoglobulin production.     

Ascaris: development of selected genotypes in mice

Using nucleotide variation in the first internal transcribed spacer of nuclear ribosomal DNA, five different genotypes (designated G1-G5) have been identified and the preponderance of genotype G1 in humans and of genotype G3 in pigs led to the proposal that parasites bearing the two genotypes have an affinity for a particular host species. A subsequent study using eggs of genotype G1 from humans and G3 from pigs to infect pigs and mice indicated that there is a significant difference in the ability to infect and establish as larvae in mice and as adults in pigs between the two genotypes. Extending previous investigations, the present study investigated whether there are differences in development as designated by egg hatching, larvae migration and distribution in the mice between the Ascaris strains with known genotypes. Ascaris eggs of genotypes G1 (predominating in human-derived worms) and G3 (predominating in pig-derived worms) were used to infect C57BL/6 mice orally. Eggs/larvae were examined from the small and large intestines, thoracic and abdominal cavities, peripheral blood, livers and lungs at intervals of 2h until 12h post-infection, then periodically until 34 days of infection. Results showed distinct differences in egg hatching (the timing and location of hatching, and the numbers hatched), and in larvae migration and distribution (the means and constituent ratios, the time of peak recovery, and larvae reappearing in intestines) between the two strains. The results can explain the findings of significantly higher larval recovery of genotype G1 than G3 in the mice, and may shed some enlightenment to understand the difference in host affiliation of Ascaris of different genotypes.     

Ascaris suum: homocytotropic antibody responses in mice.

Homocytotropic antibodies in the sera of CD-1 and DBA/1 mice infected with larval A. suum were titered by PCA reactions. IgG₁ and reaginic antibody responses were similar in both strains of mice. With a dose of 8000 to 10,000 embryonated eggs, reaginic antibody was detected during the second week and IgG₁ antibody during the third week of infection. Doses of 1500 to 5000 eggs gave delayed antibody responses or did not induce a detectable response, although an anamnestic response followed a challenge inoculation even when no detectable antibody was observed in initial infection. Larval A. suum infections in two strains of mice did not potentiate a reaginic response to ovalbumin.     

Mutagenicity of Ascaris chymotrypsin inhibitor in germ cells of mice

Chymotrypsin inhibitor isolated from Ascaris suum (ACHI) was tested for the induction of dominant lethal mutations in male mice. Dominant lethal effects of ACHI for the main stages of germ cell development were analyzed by mating at specific time points after dosing. Two groups of adult BALB/c males received 24 or 40 mg per kilogram body weight (BW) per day intraperitoneal (IP) injection of ACHI in sterile phosphate-buffered saline (PBS) for five consecutive days (subacute exposure). Males from a third group were administered single IP injections of ACHI—60 mg/kg BW (acute exposure). The control group received concurrent injections of PBS for five successive days. After the last dose, each male was mated with two untreated females. For fractionated examination with regard to successive germ cell stages (spermatozoa, spermatids, spermatocytes, spermatogonia), every second week, two other untreated virgin females were placed with each male for mating. The uteri of the females were inspected on the 15th day of gestation, and preimplantation loss and postimplantation loss determined from dominant lethal parameters. Exposure of mice germ cells to ACHI did not impair mating activity of males. Fertility index was reduced (P < 0.05) only for females mated at the third week with males exposed to the highest dose of ACHI. In the females bred to ACHI-treated males, significant (P < 0.05) increase in preimplantation loss was observed at postinjection weeks 1 (reflecting exposure to spermatozoa after single treatment and to spermatozoa or late spermatids after subacute dosing) and 3 (reflecting exposure to mid and early spermatids for acute dosing and to mid and early spermatids or late spermatocytes following acute treatment), regardless of dose and length of exposure to the inhibitor. At the 60-mg/kg-BW group, a significant increase of this parameter was also noted at week 5 (reflecting exposure to early spermatocytes). During mating days 15–21, a significant (P < 0.05) increase in postimplantation loss and dominant lethal effects were observed for all doses of ACHI. Acute ACHI exposure 5 weeks prior to mating resulted in dominant lethal effects in early spermatocytes. These preliminary data suggest that ACHI induces dominant lethal mutations at postmeiotic and meiotic stages of spermatogenesis, but spermatids are the most sensitive cell stage to the effect of ACHI. These results show that ACHI may be one of the factors causing disturbances in spermatogenesis leading to a reduction of host reproductive success.     

Effects of immunoactivity on Ascaris suum infection in mice]

The immune response to sheep red blood cell (sRBC) was monitored in the mice infected with Ascaris suum or Trichinella spiralis. The effects of the infection with T. spiralis or the injection with cyclophosphamide(CY) as an immunosuppression agent prior to challenge infection with the embryonated eggs of A. suum were monitored in mice by means of the level of infection with A. suum and cellular and humoral immune response to sRBC. Following the oral administration of 1,000 eggs of A. suum to mice, delayed-type hypersensitivity (DTH) and rosette-forming rate were gradually decreased and reached to the lowest levels at the 5th week and 6th week postinfection, respectively, and then returned to normal at the 10th week. The hemagglutinin(HA) and hemolysin(HE) titers were gradually elevated and reached to peak at the 3rd week postinfection, and then returned to normal level. The appearance ratios of the eosinophils and mast cells were in peak at the 4th week and the 2nd week postinfection, respectively. Meanwhile the harvest ratio of A. suum larvae from the liver and lungs was 21.97% at the 1st week postinfection. Following the oral administration of 300 T. spiralis infective larvae, DTH and rosette-forming rate were gradually decreased with the lapse of time and reached the lowest values in the 30th and 21st day of postinfection, and then slightly increased and transiently decreased in the 70th and 80th day of postinfection, respectively. HA and HE titers were the lowest in the 21st and 90th day, whereas the ratios of eosinophils and mast cells were the highest on the 40th and 14th day postinfection, respectively. Following the intraperitoneal injection of CY, the body weight, the spleen weight, DTH, rosette-forming ratio, HA and HE titers, the number of WBC and the ratio of the mast cell were predominantly decreased in the 5th day, and then returned to the same value of the 1st day postinjection. The ratio of eosinophils was gradually decreased following to advance of days. At the 1st, 5th and 10th days after intraperitoneal injection of CY of 400 mg/kg, a dose with 1,000 eggs of A. suum was administered orally to mice, and harvest rate of the larvae at the 7th day postadministration was 7.07% in the 1st day, 14.94% in the 5th day, 10.1% in the 10th day, 8.02% in control group. The effect of prior infection with infective larvae of T. spiralis upon immunological sequelae of a challenge infection of mice with embryonated eggs of A. suum in 30 or 70 days interval was checked.(ABSTRACT TRUNCATED AT 400 WORDS)     

Evidence for the control of Eosinophilia by the major histocompatibility complex in mice

The genetic control of eosinophilia has been studied in congenic strains of mice. Eosinophilia was induced with cyclophosphamide followed by keyhole limpet hemocyanin in complete Freund's adjuvant. After this treatment, BALB/c mice developed a high eosinophil response, whereas CBA, C57BL and A/J mice developed a low one. The major histocompatibility complex (M-HQ was found to exert a control on eosinophilia, as B 10.D2 mice developed a higher eosinophil response than B10, B10.A, or B10.BR. BALB/c-H-2 ^k mice had a lower response than BALB/c, and A.TL mice had a higher response than A/J or A.TH. If a single gene within the MHC is responsible for these effects, the most likely position for it is in the vicinity of the Tla locus. Splenectomy reduced eosinophilia in BALB/c and A.TL mice, but not in A/J mice,indicating that the spleen is a significant site of eosinophil production in high responder strains.     

Effect of dietary magnesium on Ascaris suum infections of mice

Low amounts of dietary magnesium affected the inflammatory tissue response in nonimmunized mice differently than in immunized mice. Eosinophil numbers and LPL activity in lung tissue following infection with A. suum larvae were altered by the level of magnesium in the diets of mice. Average or higher dietary levels of magnesium resulted in decreased numbers of lung larvae indicating an overall protective effect. Increases in eosinophil numbers or LPL activity were not directly related to the numbers of larvae/lungs. Larvae/livers, eosinophil numbers, and LPL activity were affected by the types of magnesium diets that mice received. Nonimmunized mice had differences in larvae/liver (at 2 days and 7 days pi) and LPL activity (at 2 days pi). Immunized mice had varying findings at 2 days pi but a direct relationship between dietary magnesium and numbers of larvae, numbers of eosinophils, and liver LPL activity at 7 days pi.     

Eosinophilia in murine trichinellosis

In both primary and secondary infections using 3 different strains of mice (DBA/1, B10 X D2, and C3H/HeJ), 2 peaks of peripheral blood eosinophilia were noted. Depending upon the strain, the first of the biphasic peaks in primary infections occurred between days 5 and 9, and the second peak occurred between days 16 and 22. The relative heights of the peak varied with the strain. In secondary infections, the initial peak was lower and the larger second peak occurred earlier. Methyridine treatment to eliminate adults prior to release of newborn larvae altered neither the course of eosinophilia in primary infection nor the biphasic distribution of eosinophilia. These studies demonstrate that the adult worm is responsible for inducing eosinophilia in murine infections, that 2 peaks of eosinophilia exist in primary and secondary infections, and that eosinophilia in secondary infections is an anamnestic response.     

Eosinophilia in murine ancylostomiasis.

Eosinophil changes in the peripheral blood of singly and repeated infected mice were studied during murine ancylostomiasis. In singly infected animals, eosinophils began to rise on 1st day, reached a peak on 4th day and progressively declined from 9th to 30th day. In repeatedly infected animals, peak eosinophilia was observed during 3rd week of post infection and sustained upto 30th day with a slight decrease. These studies demonstrate that eosinophilia is induced due to antigen-antibody reactions in the host system and eosinophilia in helminthic infections is amnestic response.