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      A simulation model to investigate interactions between first season grazing calves and Ostertagia ostertagi

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          Highlights

          • A deterministic model to address calf —O. ostertagi interactions was developed.

          • The model predicts performance and FEC for different infection intensities.

          • It performs well when validated against published data.

          • It does not account for calf genotypic variation.

          • A future aim is to develop a stochastic model to account for between host variation.

          Abstract

          A dynamic, deterministic model was developed to investigate the consequences of parasitism with Ostertagia ostertagi, the most prevalent and economically important gastrointestinal parasite of cattle in temperate regions. Interactions between host and parasite were considered to predict the level of parasitism and performance of an infected calf. Key model inputs included calf intrinsic growth rate, feed quality and mode and level of infection. The effects of these varied inputs were simulated on a daily basis for key parasitological (worm burden, total egg output and faecal egg count) and performance outputs (feed intake and bodyweight) over a 6 month grazing period. Data from published literature were used to parameterise the model and its sensitivity was tested for uncertain parameters by a Latin hypercube sensitivity design. For the latter each parameter tested was subject to a 20% coefficient of variation. The model parasitological outputs were most sensitive to the immune rate parameters that affected overall worm burdens. The model predicted the expected larger worm burdens along with disproportionately greater body weight losses with increasing daily infection levels. The model was validated against published literature using graphical and statistical comparisons. Its predictions were quantitatively consistent with the parasitological outputs of published experiments in which calves were subjected to different infection levels. The consequences of model weaknesses are discussed and point towards model improvements. Future work should focus on developing a stochastic model to account for calf variation in performance and immune response; this will ultimately be used to test the effectiveness of different parasite control strategies in naturally infected calf populations.

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          Most cited references88

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          Optimal immune responses: immunocompetence revisited.

          The function of the immune system of an animal is to provide defence against infection, in order to maximize fitness. Understanding this and, particularly, how limiting resources are traded off between costly immune responses and other physiological demands, is central to properly understanding life-history traits and their evolution. Here, we propose that functional (rather than immunological) measures of immune responses should be used when investigating this. We further suggest that optimal immune responses are context specific, rather than generic; that is, a maximum immune response is not necessarily optimal. The nature of an optimal immune response will depend on the specific circumstances and infection status of the animal. Identifying and understanding such optimality requires that the effects of different immune strategies on fitness be considered.
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            Towards a functional explanation for the occurrence of anorexia during parasitic infections.

            The development and occurrence of anorexia, the voluntary reduction in food intake during parasitic infections in animals, is somewhat paradoxical and contrary to conventional wisdom and expectation. We take the view that its occurrence is an evolved, costly behavioural adaptation which serves a function. Five such functional and general hypotheses to account for it are developed: (1) anorexia is induced by the parasite for its own benefit; (2) food intake decreases to starve parasites; (3) the negative effect on the host's energetic efficiency during parasitic diseases has a direct effect on food consumption; (4) food intake decreases for the purpose of promoting an effective immune response in the host; and (5) anorexia allows the host to become more selective in its diet, and thus select foods that either minimize the risk of infection or are high in antiparasitic compounds. Only hypotheses (4) and (5) survive the comparison for consistency with the physiological, metabolic and behavioural alterations that occur during the development of parasitic infections, and with the rule of generality (i.e. account for its occurrence in both protozoan and helminth infections). Both surviving hypotheses will need further experimental testing for their support or rejection, and such experiments are proposed. Also, the advantages and consequences of viewing anorexia during parasitic infections within a functional framework are discussed. These arise from the recognition that anorexia is a disease-coping strategy, part of the mechanism of recognition of parasite invasion by the immune system, which leads to a modification of the host's feeding behaviour. Copyright 1998 The Association for the Study of Animal Behaviour
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              Regulation of egg production, worm burden, worm length and worm fecundity by host responses in sheep infected with Ostertagia circumcincta.

              Following infection with Ostertagia circumcincta there was considerable variation in worm burdens, worm size and number of inhibited larvae even among sheep matched for age, sex, breed, farm of origin and history of parasite exposure. There was also substantial variation among sheep in the concentration of mast cells, globule leucocytes, eosinophils, IgA-positive plasma cells and parasite-specific IgA in the abomasal mucosa. With the exception of faecal egg counts over time, the parasitological and immunological traits were all continually distributed among animals and sheep did not fall into discrete high and low-responder categories. The responses were correlated. Sheep with more mast cells also had more globule leucocytes, more eosinophils, more IgA plasma cells and greater amounts of parasite-specific IgA in the abomasal mucosa. Female worm length was strongly and positively correlated with the number of eggs in utero. Faecal egg counts were associated with variation in worm number and with variation in the number of eggs in utero. The worm burden was negatively correlated with the number of globule leucocytes in the abomasal mucosa, suggesting that worm numbers are regulated by immediate hypersensitivity reactions. Decreased female worm length was associated with an increased local IgA response to fourth stage larvae. The number of inhibited larvae was positively associated with the size of the local IgA response and positively associated with the size of the worm burden. The results suggest that variation among mature sheep in faecal egg counts is due, at least in part, to variation in local IgA responses which regulate worm fecundity and to variation in local immediate hypersensitivity reactions which regulate worm burdens.
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                Author and article information

                Contributors
                Journal
                Vet Parasitol
                Vet. Parasitol
                Veterinary Parasitology
                Elsevier
                0304-4017
                1873-2550
                15 August 2016
                15 August 2016
                : 226
                : 198-209
                Affiliations
                [a ]School of Agriculture Food and Rural Development, Newcastle University, Newcastle upon Tyne, NE1 7RU, UK
                [b ]The Roslin Institute and Royal (Dick) School of Veterinary Studies, University of Edinburgh, Midlothian, EH25 9RG, Scotland, UK
                [c ]Scottish Centre for Production Animal Health and Food Safety, School of Veterinary Medicine, University of Glasgow, G61 1QH, Scotland, UK
                Author notes
                [* ]Corresponding author. z.berk@ 123456newcastle.ac.uk
                Article
                S0304-4017(16)30155-8
                10.1016/j.vetpar.2016.05.001
                4990062
                27514906
                5902aef9-7e44-4e8c-b0bf-bed2d9083d7c
                © 2016 The Authors

                This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/).

                History
                : 28 October 2015
                : 25 April 2016
                : 1 May 2016
                Categories
                Research Paper

                Parasitology
                calves,gastrointestinal parasites,immunity,modelling,ostertagia ostertagi,parasite-induced anorexia

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