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The relationship between worm population density, host survival and the growth of the third-stage larva of Amplicaecum robertsi Sprent & Mines, 1960, in the mouse

Published online by Cambridge University Press:  06 April 2009

Colin Dobson
Colin Dobson
Affiliation:
Department of Parasitology, University of Queensland, St Lucia, Brisbane, Queensland, Australia
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Extract

Female mice survived longer than male mice when infected with 400 eggs but not when infected with 100 eggs of Amplicaecum robertsi.

The larvae grew to greater lengths in young than in older mice; smaller worm burdens were also found in the older animals.

The growth of the larva was associated with the total worm burden of the host. As the worm burdens, of 40-day-old female mice, increased up to 281 individuals the length of the larvae attained after 14 days decreased; when the larval population increased above this number the lengths of the worms also increased.

These crowding effects are discussed in relation to competition for nutrients, immunological suppression of larval growth and to the ability of large larval populations to swamp the resistance mechanisms of the host. It is suggested that the increased growth of the larvae in large populations is due to their ability to break down the liver of the infected host more efficiently than small populations. However, this eventually leads to the deaths of the host through total liver breakdown.

This work was done during the tenure of a Senior Research Fellowship from the Wool Research Board of Australia. My best thanks are due to Mr J. James for his assistance with the statistics, to Professor J. F. A. Sprent for his help and advice and to Mr C. Wilkinson for his assistance.

Type
Research Article
Information
Parasitology , Volume 55 , Issue 1 , February 1965 , pp. 183 - 193
Copyright
Copyright © Cambridge University Press 1965

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References

Andrews, J. S. (1936). Note on the egg producing capacity of Cooperia curticei, a nematode parasite of cattle. J. Parasit. 22, 222–3.CrossRefGoogle Scholar
Dobson, C. (1960). An investigation of the host-parasite relations and host specificity of Nematospiroides dubius, Baylis, 1926, Heligmosomidae, a mouse nematode in its normal and an abnormal host. Thesis, University Library, Sheffield.Google Scholar
Dobson, C. (1961). Certain aspects of the host-parasite relationship of Nematospiroides dubius (Baylis). I. Resistance of male and female mice to experimental infections. Parasitology, 51, 173–9.CrossRefGoogle ScholarPubMed
Dunsmore, J. D. (1960). Retarded development of Ostertagia in sheep. Nature, Lond., 186, 986.CrossRefGoogle ScholarPubMed
Haley, A. J. & Parker, J. C. (1961). Size of adult Nippostrongylus brasiliensis from light and heavy infections of laboratory rats. J. Parasit. 47, 461.CrossRefGoogle Scholar
Kao, K. Y. T. & McGavack, T. H. (1959). Connective tissue. I. Age and sex influence on protein composition of rat tissues. Proc. Soc. exp. Biol., N.Y., 101, 153–7.CrossRefGoogle Scholar
Krupp, I. M. (1961). Effect of crowding and of superinfection on habitat selection and egg production in Ancylostoma caninum. J. Parasit. 47, 957–61.CrossRefGoogle ScholarPubMed
Lewert, R. M. (1958). Invasiveness of helminth larvae. Rice Inst. Pamph. 45, 97113.Google Scholar
Mackerras, L. M. (1936). The sheep blowfly problem in Australia. Results of some recent investigations. Bull. Coun. Sci. industr. Res. Aust. Pamphlet, no. 66.Google Scholar
Read, C. P. (1951). The ‘crowding effect’ in tapeworm infections. J. Parasit. 37, 174–8.CrossRefGoogle ScholarPubMed
Read, C. P. (1958). Status of behavioural and physiological ‘resistance’. Rice Inst. Pamph. 45 654.Google Scholar
Read, C. P. & Simmons, J. E. Jr (1963). Biochemistry and physiology of tapeworms. Physiol. Rev. 43, 263305.CrossRefGoogle ScholarPubMed
Roberts, L. S. (1961). The influence of population density on patterns and physiology of growth in Hymenolepis diminuta (Cestoda: Cyclophyllidae) in the definitive host. Expl Parasit. 11, 332–71.CrossRefGoogle Scholar
Sarles, M. P. (1929). The effect of age and size of infestation of the egg production of the dog hookworm, Ancylostoma caninum. Am. J. Hyg. 10, 658–66.Google Scholar
Sprent, J. F. A. (1963 a). The life history and development of Amplicaecum robertsi, an ascaridoid nematode of the carpet python (Morelia spilotes variegatus). I. Morphology and functional significance of larval stages. Parasitology, 53, 738.CrossRefGoogle Scholar
Sprent, J. F. A. (1963 b). The life history and development of Amplicaecum robertsi, an ascaridoid nematode of the carpet python (Morelia spilotes variegatus). II. Growth and host specificity of larval stages in relation to the food chain. Parasitology, 53, 321–37.CrossRefGoogle Scholar
Sprent, J. F. A. & Mines, J. J. (1960). A new species of Amplicaecum (Nematoda) from the carpet snake (Morelia argus variegatus): with a re-definition and a key for the genus. Parasitology, 50, 183–98.CrossRefGoogle Scholar
Todd, A. C. & Hansen, W. F. (1951). The economic import of host resistance to helminth infection. Am. J. vet. Res. 12, 5864.Google ScholarPubMed