What You Can Do About Cattle Ailments and Diseases

Pistor, W. J.

08 1900

This item was digitized as part of the Million Books Project led by Carnegie Mellon University and supported by grants from the National Science Foundation (NSF). Cornell University coordinated the participation of land-grant and agricultural libraries in providing historical agricultural information for the digitization project; the University of Arizona Libraries, the College of Agriculture and Life Sciences, and the Office of Arid Lands Studies collaborated in the selection and provision of material for the digitization project.

Cattle -- Diseases.

Cattle -- Parasites.

Cattle -- Diseases -- Prevention.

Cattle -- Diseases -- Treatment.

What You Can Do About Cattle Ailments and Diseases

Pistor, W. J.

03 1900

This item was digitized as part of the Million Books Project led by Carnegie Mellon University and supported by grants from the National Science Foundation (NSF). Cornell University coordinated the participation of land-grant and agricultural libraries in providing historical agricultural information for the digitization project; the University of Arizona Libraries, the College of Agriculture and Life Sciences, and the Office of Arid Lands Studies collaborated in the selection and provision of material for the digitization project.

Cattle -- Diseases.

Cattle -- Parasites.

Cattle -- Diseases -- Prevention.

Cattle -- Diseases -- Treatment.

Mechanisms of anthelmintic resistance in Cooperia oncophora, a nematode parasite of cattle

Njue, Annette Igandu

January 2003

Anthelmintic resistance is a major problem in livestock, and while it has been slower to emerge in cattle, there are reports of its occurrence. Three broad-spectrum anthelmintics are available for use, and one mechanism of resistance that is common to all is target site alteration. Glutamate-gated chloride channels (GluCls) are an important target for macrocyclic lactone anthelmintics (MLs), while beta-tubulin represents the benzimidazole (BZ) target. The objectives of this thesis were to determine whether GluCls are involved in ML resistance in the cattle parasite Cooperia oncophora , and whether beta-tubulin is involved in BZ and ML resistance. Two isolates of C. oncophora were used. In a fecal egg-count reduction test, ivermectin was found to be 100% effective against one isolate (IVS), and only 77.8% effective against the second isolate (IVR). Two full-length GluCl cDNAs, encoding GluClalpha3 and beta subunits, were cloned. These subunits share high sequence identity with similar GluCl subunits from Haemonchus contortus and Caenorhabditis elegans. Genetic variability analysis of the two genes showed significant differences in allele frequencies between IVS and IVR worms at the GluClalpha3 gene, but not the GluClbeta gene, suggesting that the GluClalpha3 gene is involved in ivermectin resistance. Sequencing of full-length GluCl subunit cDNAs from IVS and IVR worms revealed the presence of mutations in the N-terminal domains. Mutations in the GluClalpha3 caused modest but significant reductions in glutamate, ivermectin and moxidectin sensitivity, while mutations in the GluClbeta abolished glutamate sensitivity. Of the three mutations identified in the IVR GluClalpha3, the L256F mutation accounted for the difference in glutamate and ivermectin response between IVS and IVR GluClalpha3 channels. Two beta-tubulin isotypes cloned from C. oncophora were found to share a high homology with beta-tubulin isotypes from other trichostrongylids. Gen

Cooperia.

Drug resistance.

Anthelmintics.

Ivermectin.

Chloride channels.

Cattle -- Parasites.

Pharmacokinetics of propylthio-benzimidazole anthelmintics : modulation of liver biotransformation in sheep and cattle

Lanusse, Carlos Edmundo

January 1991

The aim of this research was to determine the influence of route of administration, drug formulation and modified-liver metabolism on the pharmacokinetic and metabolic patterns of benzimidazole anthelmintics in ruminants. Both route of administration and formulation dramatically affected the bioconversion of netobimin (NTB) pro-drug, N-methoxycarbonyl-N$ sp prime$-(2-nitro-5-propylphenylthio)-${ rm N} sp{ prime prime}$-(2-ethyl sulphonic acid) guanidine, and the bioavailability and disposition kinetics of its active albendazole (ABZ) metabolites in both sheep and cattle. The efficacy of NTB conversion by the gastrointestinal (GI) microflora, was markedly lower after subcutaneous (SC) administration of NTB pro-drug compared with enteral administrations in both species. Although trisamine and zwitterion formulations of NTB were bioequivalent after SC treatment, the zwitterion suspension was two-fold more bioavailable in terms of ABZ metabolites, after oral administration to cattle. ABZ sulphoxide (ABZSO) and ABZ sulphone (ABZSO$ sb2$), the main metabolites found in plasma, were reversibly exchanged between plasma and GI compartments and concentrated in the abomasum. ABZ, ABZSO and ABZSO$ sb2$ were detected in the GI tract for 72 h post-NTB administration to cattle. In vitro, ABZ was oxidized into ABZSO and ABZSO$ sb2$ by liver microsomes and ruminal and ileal fluids. However, only ABZSO was reduced (back to ABZ) by these GI fluids. The rate of ABZ sulphoxidation by liver microsomes was significantly lower in cattle compared to sheep. However, while the oxidizing activity was greater in GI fluids of cattle, the reducing activity was prevalent in those of sheep. This was consistent with the higher ABZSO$ sb2$/ABZSO ratio and the markedly faster disposition of both metabolites in cattle compared to sheep. The co-administration of NTB with different oxidation-impairing compounds, largely methimazole (MTZ), in both species, resulted in an increased bioavailability and/o

Benzimidazoles -- Pharmacokinetics.

Anthelmintics -- Pharmacokinetics.

Sheep -- Parasites -- Control.

Cattle -- Parasites -- Control.

Mechanisms of anthelmintic resistance in Cooperia oncophora, a nematode parasite of cattle

Njue, Annette Igandu

January 2003

No description available.

Chloride channels.

Ivermectin.

Drug resistance.

Cattle -- Parasites.

Anthelmintics.

Cooperia.

Pharmacokinetics of propylthio-benzimidazole anthelmintics : modulation of liver biotransformation in sheep and cattle

Lanusse, Carlos Edmundo

January 1991

No description available.

Anthelmintics -- Pharmacokinetics.

Sheep -- Parasites -- Control.

Benzimidazoles -- Pharmacokinetics.

Cattle -- Parasites -- Control.

Studies of Hypoderma lineatum and Hypoderma bovis with especial reference to economic importance and control

Case, Leland Irving

January 1929

1. Hypoderma lineatum and Hypoderma bovis are prevalent in Burkes Garden and Southwestern Virginia generally. 2. Young cattle, calves and yearlings particularly, are generally more heavily infested than older cattle. 3. Adults appear in Burkes Garden the first warm days in April though they are at their worst in June and July, a normal season. 4. Larvae ordinarily make their first appearance in the subcutaneous tissues of the back about the first of December. The first ones emerge and pupate about the middle of January. 5. At the time control was started H. lineatum exceeded H. bovis in the ratio of 65 to 35 percent. The ratio now is 55 to 45 percent. 6. Salt, wet or dry, is an ineffective dressing for killing Hypoderma larvae in the subcutaneous tissues of the host. 7. Benzol, 90 or 100 percent, injected into larval cysts effects a high percentage of kill. 8. Hand extraction at intervals of 30 days repeated five times is a practical and effective means of control. 9. Hand extraction performed by the average farm worker caused an occasional case of anaphylaxis, .037 percent 10. Cooperative control measures, to be effective, should be supervised closely. 11. Extraction of Hypoderma larvae from the subcutaneous tissues of the host effects gains in weight and milk flow advantageously. 12. Control measures as practiced in Burkes Garden has reduced Hypoderma infestation by approximately 50 percent. / M.S.

LD5655.V855 1929.C373a

Cattle -- Parasites

Warble flies

Salivary gland transcriptome of Rhipicephalus (Boophilus) microplus

Genu, Siyamcela

11 1900

The cattle tick, Rhipicephalus (Boophilus) microplus is a tick of veterinary and health importance globally, transmitting Babesia bovis and B. bigemina. Tick control is important and needed to prevent livestock diseases caused by tick-transmitted pathogens. Traditionally, tick control methods have resulted in development of acaricide-resistant ticks, environmental pollution and meat and milk contamination. Therefore, there is a need for alternative method and vaccines directed against tick feeding. The aim of this study was to identify proteins involved in tick feeding, tickhost-pathogen interactions and tick reproduction. Consequently, these will help in identification of antigens with the ultimate goal of developing anti-tick vaccines. R. (B.) microplus female ticks were collected at five different feeding stages. RNA was isolated from the salivary gland extracts (SGEs). The cDNA libraries were synthesized and sequenced with the Illumina MiSeq technology. Transcriptome data was analyzed with CLC Genomics Workbench, Trinity and Minia. The SGEs were also used to isolate the fractions: membrane, soluble and pellet protein for proteomic analysis. The proteomics data was analysed with Mascot, X!Tandem and Scaffold. Both the transcriptome and proteome analysis revealed the presence of major secretory protein families such as Kunitz, lipocalins, serpins, cement proteins and metalloproteases, while the majority of transcripts coded for housekeeping genes. / National Research Foundation (South Africa) / Life and Consumer Science / M. Sc. (Life Science)

636.0894433

Cattle tick -- Control

Ticks as carriers of disease

Cattle -- Parasites

Tick-borne diseases in animals

Neospora caninum : studies toward isolation in New Zealand : a thesis presented in partial fulfilment of the requirements for the degree of Master of Veterinary Studies at Massey University, Palmerston North, New Zealand

Walton, Julie K

January 2008

Background: Neospora caninum is a parasite that causes disease, largely in cattle and dogs. It is a disease of significant interest within New Zealand due to its association with bovine abortion. The economic impact of bovine abortion justifies the development of a bovine vaccine against N. caninum. Aim: To develop and optimise diagnostic procedures for the detection of Neospora from a variety of blood and tissue samples and to isolate a New Zealand strain of Neospora caninum. Methods: A local strain of Toxoplasma gondii and an imported Neospora caninum strain, Nc-Liverpool, were used to optimise tachyzoite growing conditions in bovine endothelial (BE) cells and Vero host cell cultures. A serum study using 112 tissue culture flasks was performed to determine whether foetal bovine serum or horse serum supplemented media provided the optimal growing conditions for Nc-Liverpool tachyzoites. Nc-Liverpool tachyzoites were also used to determine the optimal growth period between passage, and harvest for cryopreservation and cryopreservation conditions. Percoll gradients were also tested using Nc-Liverpool tachyzoites. A known Neospora positive canine sample and murine tissues infected with Toxoplasma, were used during the development of the immunohistochemical diagnostic technique. Antibody concentrations and incubation temperatures were tested to reduce cross-reactivity and increase specific stain intensity. Immunohistochemistry was performed on sections of all tissue samples used for N. caninum isolation and experimentally infected murine tissue. Several PCR techniques were developed, the final PCR used being a combination of the different techniques, which produced a 250kb band. PCR-3 used the NF6/GA1 primer combination for Neospora detection and TF6/GA1 for Toxoplasma detection, additional Mg2+ and an annealing temperature of 55°C were required. Whole tissue was processed via DNA elution whereas cell culture and Percoll purified tachyzoites were used following crude lysis techniques. All bovine and canine tissues used for parasite isolation as well as all experimentally infected mouse tissues were tested for N. caninum using PCR. An immunoblot technique was developed for the detection of N. caninum antibodies in murine blood samples. Lysed Nc-Liverpool tachyzoites were used as antigen with varied results. The primary and secondary antibodies were commercially available and used at concentrations of 1:1,000 and 1:25,000 respectively. BALB/c and CF1 mice were experimentally infected with Toxoplasma gondii and Nc-Liverpool. Forty female BALB/c and 40 female CF1 mice were used in 2 studies to determine the optimal Nc-Liverpool inoculation dose and immunosuppression requirements. Mice were immunosuppressed with 2.5mg of methylprednisolone acetate (MPA) and Nc-Liverpool inoculation ranged from 1.3x106 to 5x103 tachyzoites. Upon death, the brain and blood was harvested from the mouse carcases. Attempts were made to isolate a New Zealand strain of N. caninum from bovine and canine central nervous system (CNS) tissue, and to maintain the parasites in cell culture and by small animal passage, in order to attenuate the parasite strain for use as a live large animal vaccine. Twenty one bovine tissue samples were used for N. caninum isolation attempts, 18 of which were positive for Neospora antibodies using a commercial IFAT. Isolation tissues were purified using a 30% Percoll gradient and inoculated onto 8 cell culture flasks and into 8 immunosuppressed mice (BALB/c and CF1). Results: Nc-Liverpool tachyzoites were found to be viable when grown at 37°C in antibiotic-MEM supplemented with either FBS or ES and grew optimally in FBS despite Neospora antibodies being detected using an IFAT. Passaging cultures at approx. 4 day intervals resulted in the greatest parasite growth. However, cryopreserved parasites should be harvested 2 days post inoculation (PI) for optimal viability. Viable parasites could be isolated using a 30% Percoll gradient and centrifuged at 2,700 x g (3,400 rpm) in a bucket centrifuge for 10 minutes. Tissue cysts could be detected using immunohistochemistry but some degree of cross reaction remained despite optimisation. Cysts were not found in tissues used for isolation attempts or in mouse brains following inoculation with Nc-Liverpool, however cysts were commonly found in mice experimentally infected with T. gondii tachyzoites. PCR-3 was successfully used to detect N. caninum and T. gondii infected tissue and tachyzoites from tissue culture. PCR-3 could detect N. caninum DNA in the brain tissue of 9/24 mice experimentally infected with Nc-Liverpool, even though most mice were culled within 1 week. Although production of N. caninum antigen was only moderately successful, N. caninum antibody detection in mouse blood using one specific antigen batch was reliable and specific. The immunoblot could only detect N. caninum antibody approximately 14 days PI, but was sensitive enough to detect 100% of mice experimentally infected with Nc-Liverpool tachyzoites. PCR-3 strongly correlated with the immunoblot results from 14 days PI. BALB/c mice were found to be far more sensitive to Nc-Liverpool than CF1 mice and developed severe disease at concentrations of approximately 1x106 Nc-Liverpool tachyzoites. Neither BALB/c nor CF1 mice developed peritoneal exudate, irrespective of the parasite inoculation concentration. Despite Neospora DNA being present in the brains of experimentally infected mice, re-isolation and continuous parasite passage from the brains could not be achieved. No mice experimentally infected with either Nc-Liverpool or isolation attempts were found to have brain cysts when tested using immunohistochemistry. Only 1 mouse inoculated with bovine isolation material was found to have a Neospora positive PCR. Through the detection of DNA, antigens and antibodies, parasites were determined to have been present in 10 of the 18 IFAT positive bovine isolation samples, indicating that 55% of calves born to seropositive dams were infected with N. caninum. However, despite numerous attempts to isolate Neospora parasites from naturally infected canine and bovine tissue and culturing using the optimised Nc-Liverpool technique, maintenance of a live culture of a New Zealand strain of N. caninum could not be established. Conclusions: Findings from this study could be used to assist in the maintenance of Neospora caninum and Toxoplasma gondii parasite strains and for detection or diagnosis of these parasites in host tissues.

Neospora caninum

pathogenic protozoa

Toxoplasma gondii

cattle parasites

cattle diseases

veterinary parasitology

New Zealand

Neospora caninum : studies toward isolation in New Zealand : a thesis presented in partial fulfilment of the requirements for the degree of Master of Veterinary Studies at Massey University, Palmerston North, New Zealand

Walton, Julie K

January 2008

Background: Neospora caninum is a parasite that causes disease, largely in cattle and dogs. It is a disease of significant interest within New Zealand due to its association with bovine abortion. The economic impact of bovine abortion justifies the development of a bovine vaccine against N. caninum. Aim: To develop and optimise diagnostic procedures for the detection of Neospora from a variety of blood and tissue samples and to isolate a New Zealand strain of Neospora caninum. Methods: A local strain of Toxoplasma gondii and an imported Neospora caninum strain, Nc-Liverpool, were used to optimise tachyzoite growing conditions in bovine endothelial (BE) cells and Vero host cell cultures. A serum study using 112 tissue culture flasks was performed to determine whether foetal bovine serum or horse serum supplemented media provided the optimal growing conditions for Nc-Liverpool tachyzoites. Nc-Liverpool tachyzoites were also used to determine the optimal growth period between passage, and harvest for cryopreservation and cryopreservation conditions. Percoll gradients were also tested using Nc-Liverpool tachyzoites. A known Neospora positive canine sample and murine tissues infected with Toxoplasma, were used during the development of the immunohistochemical diagnostic technique. Antibody concentrations and incubation temperatures were tested to reduce cross-reactivity and increase specific stain intensity. Immunohistochemistry was performed on sections of all tissue samples used for N. caninum isolation and experimentally infected murine tissue. Several PCR techniques were developed, the final PCR used being a combination of the different techniques, which produced a 250kb band. PCR-3 used the NF6/GA1 primer combination for Neospora detection and TF6/GA1 for Toxoplasma detection, additional Mg2+ and an annealing temperature of 55°C were required. Whole tissue was processed via DNA elution whereas cell culture and Percoll purified tachyzoites were used following crude lysis techniques. All bovine and canine tissues used for parasite isolation as well as all experimentally infected mouse tissues were tested for N. caninum using PCR. An immunoblot technique was developed for the detection of N. caninum antibodies in murine blood samples. Lysed Nc-Liverpool tachyzoites were used as antigen with varied results. The primary and secondary antibodies were commercially available and used at concentrations of 1:1,000 and 1:25,000 respectively. BALB/c and CF1 mice were experimentally infected with Toxoplasma gondii and Nc-Liverpool. Forty female BALB/c and 40 female CF1 mice were used in 2 studies to determine the optimal Nc-Liverpool inoculation dose and immunosuppression requirements. Mice were immunosuppressed with 2.5mg of methylprednisolone acetate (MPA) and Nc-Liverpool inoculation ranged from 1.3x106 to 5x103 tachyzoites. Upon death, the brain and blood was harvested from the mouse carcases. Attempts were made to isolate a New Zealand strain of N. caninum from bovine and canine central nervous system (CNS) tissue, and to maintain the parasites in cell culture and by small animal passage, in order to attenuate the parasite strain for use as a live large animal vaccine. Twenty one bovine tissue samples were used for N. caninum isolation attempts, 18 of which were positive for Neospora antibodies using a commercial IFAT. Isolation tissues were purified using a 30% Percoll gradient and inoculated onto 8 cell culture flasks and into 8 immunosuppressed mice (BALB/c and CF1). Results: Nc-Liverpool tachyzoites were found to be viable when grown at 37°C in antibiotic-MEM supplemented with either FBS or ES and grew optimally in FBS despite Neospora antibodies being detected using an IFAT. Passaging cultures at approx. 4 day intervals resulted in the greatest parasite growth. However, cryopreserved parasites should be harvested 2 days post inoculation (PI) for optimal viability. Viable parasites could be isolated using a 30% Percoll gradient and centrifuged at 2,700 x g (3,400 rpm) in a bucket centrifuge for 10 minutes. Tissue cysts could be detected using immunohistochemistry but some degree of cross reaction remained despite optimisation. Cysts were not found in tissues used for isolation attempts or in mouse brains following inoculation with Nc-Liverpool, however cysts were commonly found in mice experimentally infected with T. gondii tachyzoites. PCR-3 was successfully used to detect N. caninum and T. gondii infected tissue and tachyzoites from tissue culture. PCR-3 could detect N. caninum DNA in the brain tissue of 9/24 mice experimentally infected with Nc-Liverpool, even though most mice were culled within 1 week. Although production of N. caninum antigen was only moderately successful, N. caninum antibody detection in mouse blood using one specific antigen batch was reliable and specific. The immunoblot could only detect N. caninum antibody approximately 14 days PI, but was sensitive enough to detect 100% of mice experimentally infected with Nc-Liverpool tachyzoites. PCR-3 strongly correlated with the immunoblot results from 14 days PI. BALB/c mice were found to be far more sensitive to Nc-Liverpool than CF1 mice and developed severe disease at concentrations of approximately 1x106 Nc-Liverpool tachyzoites. Neither BALB/c nor CF1 mice developed peritoneal exudate, irrespective of the parasite inoculation concentration. Despite Neospora DNA being present in the brains of experimentally infected mice, re-isolation and continuous parasite passage from the brains could not be achieved. No mice experimentally infected with either Nc-Liverpool or isolation attempts were found to have brain cysts when tested using immunohistochemistry. Only 1 mouse inoculated with bovine isolation material was found to have a Neospora positive PCR. Through the detection of DNA, antigens and antibodies, parasites were determined to have been present in 10 of the 18 IFAT positive bovine isolation samples, indicating that 55% of calves born to seropositive dams were infected with N. caninum. However, despite numerous attempts to isolate Neospora parasites from naturally infected canine and bovine tissue and culturing using the optimised Nc-Liverpool technique, maintenance of a live culture of a New Zealand strain of N. caninum could not be established. Conclusions: Findings from this study could be used to assist in the maintenance of Neospora caninum and Toxoplasma gondii parasite strains and for detection or diagnosis of these parasites in host tissues.

Neospora caninum

pathogenic protozoa

Toxoplasma gondii

cattle parasites

cattle diseases

veterinary parasitology

New Zealand