Infectivity, growth, distribution and fecundity of a six versus twenty-five metacercarial cyst inoculum of Echinostoma caproni in ICR mice

Effects of a protein-free diet on worm recovery, growth, and distribution of Echinostoma caproni in ICR mice

The effects of a protein-free diet on the host–parasite relationship of Echinostoma caproni in ICR mice were studied. The experimental diet was a customized protein-free diet (PFD) in pellet form containing 0% protein. The control diet consisted of a standard laboratory diet containing 23% casein as a source of protein. A total of 24 mice were each infected with 15 metacercarial cysts of E. caproni. Twelve mice were placed on the experimental diet (experimentals) and the remaining mice (controls) were placed on the control diet. Experimental and control mice were necropsied at 2, 3, and 4 weeks postinfection (p.i.). The weight of mice on the PFD was markedly lower than that of mice on the control diet. The length and circumference of the small intestine of infected mice on the PFD were significantly lower than those of the controls at 3 weeks p.i. (Student's t-test; P < 0.05). Worm recoveries from mice on the PFD were significantly lower than those of the controls at 3 weeks p.i. There was a significant decline in worm body area in worms from the mice on the PFD compared with those on the control diet at 2, 3, and 4 weeks p.i. Worm dry weights from mice on the PFD were significantly lower than those on the control diet at 2 weeks p.i. Worms from hosts on the PFD were located more posteriad in the gut than those recovered from mice on the control diet. The findings suggest that the PFD contributes to growth retardation of E. caproni in ICR mice.

Biological variation between two Brazilian geographical isolates of Echinostoma paraensei

The biological behaviour and morphometric data from two allopatric isolates of Echinostoma paraensei (Rio Bonito - RB and Sumidouro - SU) collected from naturally infected Nectomys squamipes from two secluded Atlantic Forest fragments were studied. Mice that had been experimentally infected with ten encysted metacercariae of each isolate were monitored weekly in two trials to analyse worm burden and the kinetics of worm distribution along the intestine. The total number of uterine eggs, wet weights and measurements of the worms and body, acetabulum, testes and ovaries were also analysed. The RB isolate showed a higher worm burden, 7.7+/-0.8, and a longer life span, 16 weeks, compared to a worm burden of 5.8+/-1.1 and life span of 9 weeks for the SU isolate. Worms of the RB isolate were clustered in the duodenum and in the bile duct while the SU isolate worms were dispersed along the small intestine of infected mice. Both isolates developed similarly as regards morphometric data and wet weight, although the total number of uterine eggs was greater in RB. The degree of intraspecific variation observed in the worm distribution along the intestine, worm burden and life span raises questions regarding the use of these criteria for species differentiation. These findings suggest that variation in biological parameters found between the E. paraensei isolates could result from geographical isolation and, in particular, the environmental conditions of transmission. Further studies on E. paraensei polulations from different forest fragments will contribute towards an understanding of the speciation of this parasite.

Changes on Schistosoma mansoni (Digenea: Schistosomatidae) worm load in Nectomys squamipes (Rodentia: Sigmodontinae) concurrently infected with Echinostoma paraensei (Digenea: Echinostomatidae)

The water rat, Nectomys squamipes, closely involved in schistosomiasis transmission in Brazil, has been found naturally infected simultaneously by Schistosoma mansoni and Echinostoma paraensei. Laboratory experiments were conducted to verify parasitic interaction in concurrent infection. It was replicated four times with a total of 42 water rats and essayed two times with 90 mice pre-infected with E. paraensei. Rodents were divided into three groups in each replication. A wild strain recently isolated from Sumidouro, RJ, and a laboratory strain of S. mansoni from Belo Horizonte (BH) was used. Rats infected with E. paraensei were challenged 4 weeks later with S. mansoni and mice 2 or 6 weeks after the infection with S. mansoni. Necropsy took place 8 weeks following S. mansoni infection. The N. squamipes treatment groups challenged with S. mansoni RJ strain showed a significant decrease (80 and 65%) in the S. mansoni parasite load when compared with their respective control groups. There was a significant change or no change in the hosts challenged with the BH strain. The persistence time of E. paraensei within host was extended in relation to control groups, with a consequent enhancement of the number of recovered worm. An E. paraensei strain-specific influence on S. mansoni parasitism is reported. This paper presents some experimental data about this interaction in N. squamipes and Mus musculus.

Effect of a high protein diet on worm recovery, growth and distribution of Echinostoma caproni in ICR mice

The effects of a high protein diet on the host-parasite relationship of Echinostoma caproni in ICR mice were studied. The customized high protein diet (CHPD) contained 64% casein as a source of protein. The control diet consisted of a standard laboratory diet containing 23% casein as a source of protein. Mice were each fed 25 cysts of E. caproni by stomach tube and necropsied 2, 3, 4 and 5 weeks postinfection. The weight of mice on the CHPD did not differ significantly from mice on the control diet. Worm recoveries were also unaffected by the high protein diet. There was a significant decline in worm dry weight, body area and uterine egg counts in worms from mice on the CHPD compared with those on the control diet. Worms from hosts on the CHPD were located more posteriad in the gut than those recovered from mice on the control diet. Changes in the mouse diet adversely affected E. caproni maturation and growth, possibly by altering the immediate host mucosal environment and making it less conducive to worm development.

Effects of high fat diets on worm recovery, growth and distribution of Echinostoma caproni in ICR mice

The effects of high fat diets (HFDs) on the host-parasite relationship of Echinostoma caproni in ICR mice were studied. Two HFDs were used, one consisting of a customized high fat diet (CHFD) with 45% lipid in the form of cottonseed oil, and the second consisting of an egg yolk diet (EYD) from domestic hens' eggs, with 31% lipid. Controls for both diets consisted of mice fed a standard laboratory diet with 5% lipid. Mice were each fed 25 cysts of E. caproni by stomach tube and necropsied 2, 3 and 4 weeks postinfection (PI). The weight of mice on the CHFD declined significantly compared to mice on the control diet, but there was no significant decline in weight of mice fed EYD compared to the controls. Worm recoveries from mice on both HFDs were significantly less than those from control hosts. There was a significant decline in worm dry weight, body area and uterine egg counts in worms on HFD compared to those on the control diet. Worms from hosts on HFD were located more anteriad in the gut than those recovered from mice on the control diet.

A comparison of the adult and miracidial stages of Echinostoma paraensei and E. caproni

Adult Echinostoma paraensei and Echinostoma caproni were grown in outbred mice and golden hamsters to compare size, growth rates, infectivity, and habitat selection. Antagonistic responses between the 2 species were investigated by concurrent infections in mice. Miracidial stages were compared for developmental stages, hatching responses, and behaviour to light and gravity. Size differences and growth rates were significantly different in both mice and hamsters. Mice proved to be better hosts for E. caproni and hamsters for E. paraensei. In mature infections, E. paraensei adults localized in the duodenum and E. caproni in the ileum of both mice and hamsters. In concurrent infections of mice, E. paraensei adults were significantly smaller than in single species infections beyond 14 days post-infection, while E. caproni adults were either equal to or larger than those in single species infections. On the other hand, E. paraensei were recovered in larger numbers in concurrent infections than in single species infections, while the reverse was found for infectivity of E. caproni adults. Miracidia of E. paraensei developed at the same rate as those of E. caproni in both light and dark cultures, but E. paraensei hatched much sooner when exposed to light. No miracidia hatched from cultures kept in the dark, indicating light is needed to stimulate the hatching process. All light-stimulated cultures exhibited a circadian hatching pattern from 1100 to 1600 hours. Cultures maintained in the dark past 11 days did not hatch when exposed to light. Miracidia of E. paraensei showed a positive phototaxis but no response to gravity. This comparison of life cycle stages leads us to conclude that E. paraensei and E. caproni are distinct species.