ABSTRACT
A genome linkage scan was carried out using a resource flock of 1029 sheep in six half-sib families. The families were offspring of sires derived by crossing divergent lines of sheep selected for response to challenge with the intestinal parasitic nematode Trichostrongylus colubriformis. All animals in the resource flock were phenotypically assessed for worm resistance soon after weaning using a vaccination/challenge regime. After correcting for fixed effects using a least squares linear model the faecal egg count data obtained following the first challenge and the faecal egg count data obtained after the second challenge were designated Trait 1 and Trait 2, respectively. A total of 472 lambs drawn from the phenotypic extremes of the Trait 2 faecal egg count distribution were genotyped with a panel of 133 microsatellite markers covering all 26 sheep autosomes. Detection of quantitative trait loci (QTL) for each of the faecal egg count traits was determined using interval analysis with the Animap program with recombination rates between markers derived from an existing marker map. No chromosomal regions attained genome-wide significance for QTL influencing either of the traits. However, one region attained chromosome-wide significance and five other regions attained point-wise significance for the presence of QTL affecting parasite resistance.
Subject(s)
Quantitative Trait, Heritable , Sheep Diseases/genetics , Trichostrongylosis/veterinary , Analysis of Variance , Animals , Chromosome Mapping , Female , Genetic Markers , Immunity, Innate , Male , Sheep , Sheep Diseases/immunology , Sheep Diseases/parasitology , Trichostrongylosis/geneticsABSTRACT
The glyoxylate cycle, catalysed by two unique enzymes: isocitrate lyase (ICL; EC 4.1.3.1) and malate synthase (MS; EC 4.1.3.2), is necessary for the net conversion of acetate into glucose. This metabolic pathway operates in microorganisms, higher plants and nematodes. Two bacterial genes, encoding ICL and MS, were modified in order to introduce them into the mouse germ line. The ovine metallothionein-Ia (MT-Ia) promoter-ace B gene-ovine growth hormone (GH) gene (3' GH sequence) construct was fused to the ovine, MT-Ia promoter-ace A gene-ovine GH gene (3' GH sequence). Therefore, in this single DNA sequence, both ace A and ace B are under independent MT-Ia promoter control and can be induced by zinc. Transgenic mice were generated by pronuclear microinjection of the ace B-ace A gene construct. We now report the establishment of four mouse lines carying these two transgenes. Studies on the progeny of these lines indicate that one line (No. 91) is expressing both genes at the mRNA and enzyme levels in the liver and intestine, whereas another line (No. 66) has a much lower expression. Both enzyme activities were detected in the liver and intestine at levels up to 25% of those measured in fully derepressed Escherichia coli cells.
Subject(s)
Genes, Bacterial , Glyoxylates/metabolism , Isocitrate Lyase/genetics , Malate Synthase/genetics , Transgenes , Animals , Blotting, Northern , Female , Intestine, Small/enzymology , Isocitrate Lyase/metabolism , Liver/enzymology , Malate Synthase/metabolism , Mice , Mice, Inbred C57BL , Mice, Inbred CBA , Mice, Transgenic , Tissue DistributionABSTRACT
The coding sequences of the cysE and cysK genes from Escherichia coli, which encode the enzymes of the cysteine biosynthetic pathway, namely, serine acetyltransferase (EC 2.3.1.30) and O-acetylserine sulfhydrylase (or cysteine synthase [EC 4.2.99.8]), were modified for expression in eukaryotic cells and introduced into murine L cells. A number of fusion genes comprising the cysE or cysK coding sequences joined to the promoter of the ovine metallothionein-Ia (MT-Ia) gene and various portions of the ovine growth hormone (GH) gene were prepared. Significant differences in the level of transcription were observed, depending on the amount and arrangement of the GH gene sequences used, the highest levels being obtained with the constructs MTCE10 and MTCK7, which contained only the GH 3' untranslated gene sequences. These two constructs were fused to produce the gene MTCEK1. In this single DNA sequence, each bacterial gene is under independent MT-Ia promoter control. Expression of the cysK sequence in this construct (MT-Ia promoter-cysE-3' GH sequence-MT-Ia promoter-cysK-3' GH sequence) was elevated compared with expression of the cysK gene in MTCK7. However, expression of the cysE sequence in MTCEK1 was only 40% of that of the cysE gene cloned into MTCE10. The double-promoter configuration, which enhances the expression of the second gene in MTCEK1, is proposed as a model for the modification of bacterial genes in general.
Subject(s)
Acetyltransferases/genetics , Cysteine Synthase/genetics , Escherichia coli/genetics , Gene Expression Regulation, Enzymologic , Acetyltransferases/biosynthesis , Animals , Base Sequence , Blotting, Northern , Cloning, Molecular , Cysteine Synthase/biosynthesis , DNA, Bacterial/analysis , Escherichia coli/enzymology , Genes, Bacterial , L Cells , Mice , Molecular Sequence Data , Plasmids , RNA, Bacterial/analysis , Serine O-Acetyltransferase , Sheep/genetics , Transcription, Genetic , Transfection , Zinc/pharmacologyABSTRACT
The techniques involved in the transfer of foreign DNA to domestic animals have advanced to the stage where transgenic animals that express foreign genes can be reliably produced, albeit still at low efficiency. This paper reviews the current status of some of the more important areas in agriculture where this technology is being applied. Numerous attempts have been made to modify the growth performance characteristics of domestic animals by the introduction of metallothionein/growth hormone fusion genes. A summary of our work with transgenic sheep is presented. The results demonstrate that the unregulated production of growth hormone in transgenic sheep reduces carcass fat, elevates metabolic rate and heat production, causes skeletal abnormalities and impairs survival. The introduction of new metabolic pathways to domestic animals offers an attractive approach to improved animal productivity. This paper summarises recent results of research directed towards the introduction of a cysteine biosynthetic pathway and the glyoxylate cycle to transgenic sheep. So far, the genes encoding the enzymes have been isolated and expressed both in cells in culture and in transgenic mice. The results of work currently in progress demonstrate that some modification of the fusion genes is required to enhance their expression in transgenic animals.
Subject(s)
Agriculture/methods , Animals, Domestic/physiology , Animals, Genetically Modified/physiology , Animals , Animals, Domestic/genetics , Animals, Genetically Modified/genetics , Base Sequence , Cysteine/biosynthesis , DNA/chemistry , Growth Hormone/genetics , Lactation , Milk/metabolism , Molecular Sequence Data , Plasmids , Promoter Regions, Genetic , Wool/growth & developmentABSTRACT
Two groups of three Merino wethers were infused intravenously with either 0.12 mg mouse epidermal growth factor (mEGF)/kg fleece-free body weight or 0.9% (w/v) NaCl over 24 h. Sheep treated with mEGF rejected food during treatment but feed intake was kept equal for both groups. Wool growth and plasma concentrations of mEGF were measured during the experiment. Pieces of skin taken from the wool-growing regions of the body were incubated with radioactive thymidine in order to measure its rate of incorporation into DNA. The skin was then divided at about the level of the sebaceous glands into sections that contained the upper dermis and epidermis (E sections) and those containing the generative wool-follicle bulbs (D sections). No mEGF was detected in the controls whereas mean levels of about 35 micrograms mEGF/1 plasma were detected during the last 4 h of infusion in the protein-treated group. After infusion, wool growth was reduced by about 20% of the mean pretreatment level in the controls and no shedding of wool fibre was evident. In the mEGF-treated sheep, on the other hand, wool growth was depressed by 75-95% of the mean pretreatment level and the fleeces were almost completely cast in all three of the animals, leaving them nude on the wool-growing regions of the body. Wool growth was restored to its pretreatment level in this group about 1 month after infusion. The D sections of skin contributed 50-60% of skin wet weight in controls throughout the experiment.(ABSTRACT TRUNCATED AT 250 WORDS)
Subject(s)
DNA/biosynthesis , Epidermal Growth Factor/pharmacology , Skin/metabolism , Wool/growth & development , Animals , Depression, Chemical , Epidermal Growth Factor/blood , Hydrocortisone/blood , Male , Mice , Organ Size/drug effects , Sheep , Skin/drug effects , Thymidine/metabolism , Wool/drug effectsABSTRACT
The effects of 8-day intravenous infusions of dexamethasone on deoxyribonucleic and ribonucleic acid metabolism have been examined in the skin of the Merino sheep. In two separate experiments, depilatory doses of dexamethasone (8.4 mg kg-0.75 body weight) were shown to inhibit the [3H]thymidine incorporation into DNA in the skin by about 80%. In the presence of excess thymidine the amount of radioactivity in DNA at the end of infusion decreased to about 50% of the pretreatment values. The incorporation of [3H]uridine into RNA in the skin was not affected. Decreases in the wet weight, DNA and RNA contents of skin were observed at the end of the dexamethasone infusion. In two experiments, wool growth was reduced to 36 +/- 9% (s.e.m.) and 52 +/- 8% of the respective pretreatment values. The results suggest that the dexamethasone caused a reduction in the wool growth by inhibiting DNA biosynthesis of wool follicle cells.
Subject(s)
DNA/metabolism , Dexamethasone/pharmacology , Nucleic Acid Hybridization/drug effects , Skin/metabolism , Animals , DNA/analysis , Depression, Chemical , Dexamethasone/blood , Hair Removal , Male , Organ Size/drug effects , RNA/analysis , RNA/metabolism , Sheep , Skin/anatomy & histology , Thymidine/metabolism , Uridine/metabolism , Wool/growth & developmentABSTRACT
The effects of an 8-day intravenous infusion of dexamethasone (7.6 mg kg-0.75 body weight) on collagen biosynthesis and wool growth in skin were examined in four Merino wethers. Plasma dexamethasone concentrations reached their peaks during the first 24 h infusion, which were followed by relatively stable levels (c. 1 X 10(-7) M) for the next 4--5 days. Minor increases in plasma dexamethasone levels were recorded during the final 2 days of treatment. Dexamethasone concentrations quickly fell below the level of detection once infusion ceased. Marked decreases in the wet weight, thickness and protein content of skin were observed at the end of infusion. DNA content was reduced to 42.4 +/- 4.9% s.e.m. during the first 2 days of treatment, but in the next 4 days of infusion gradually increased to 85.0 +/0 12.5% of controls. The level of collagen (expressed as hydroxyproline content of its acid hydrolysate) was elevated throughout the infusion and then gradually declined in 3 weeks to about 60% of controls. The biosynthesis of collagen measured by the rate of [14C]hydroxyproline formation and the activity of proline, 2-oxoglutarate dioxygenase (EC 1.14.11.2. formerly prolyl hydroxylase) was reduced during the first half of treatment to a greater extent than the rate of [14C]proline incorporation into proteins. Wool growth was reduced by 80.4 +/- 11.6% in the post-infusion period which allowed three sheep out of four to be defleeced. Inhibition of collagen biosynthesis in sheep skin was due initially to a decrease in the activity of proline, 2-oxoglutarate dioxygenase and later to the reduced rate of proline incorporation into proteins. It was also evident that changes in biosynthetic rate of collagen were not reflected in the total level of skin collagen. The extent of wool growth depression in individual animals paralleled the changes in DNA content and the extent of collagen biosynthesis inhibition.
