The comprehensive and systematic collection of measured phenotypes (phenomics) will help to bridge the gap between genetic variability and phenotypes of the animals. Recent advances in “omics†technologies, could aid in the development of a more accurate molecular-profile...
The comprehensive and systematic collection of measured phenotypes (phenomics) will help to bridge the gap between genetic variability and phenotypes of the animals. Recent advances in “omics†technologies, could aid in the development of a more accurate molecular-profile by which to classify the biological outcomes. The use of high-throughput approaches such as proteomics and metabolomics have great potentiality in filling this gap. Indeed, the development of such strategies to characterise peptides and metabolites would provide valuable leads to better clarify the biological processes underlying many phenotypic and pathological traits.
The application and integration of these technologies in animal science will provide great opportunities to tackle biologically important questions (e.g. how to improve animal welfare) at a whole new level. Indeed, this information could be used to develop precision livestock farming (PLF) approaches with the ultimate aim to offer a real-time monitoring and management system, solving in part problems of animal productions in high density populated regions, like EU.
The objective of the project was to reveal new insights into the patterns, structure and determinants of phenotypic variation of the pigs at the molecular level using proteomics and metabolomics approaches for their use to describe the underlying molecular process linking genotypes and phenotypes of the animals.
The overall aims of the project were achieved by addressing the following six main objectives:
Firstly, the identification of the end phenotypes was achieved contributing in the analysis and construction of datasets of a large population of performance tested pigs from different breeds from which biological specimens were also collected to link external and internal phenotypes.
Secondly, the ER applied mass spectrometry (MS) based proteomics technologies, for the identification, detection and high throughput quantification of new protein/peptide markers in different biological substrates collected from the performance tested pigs. The ER settled the facilities and the protocols for the protein extraction and digestion. Following optimisation of the protocol the ER applied label-free LC-MS to investigate the difference in the liver proteome between two pig breeds, Italian Duroc (ID) and Italian Large White (ILW). Twenty-five proteins were identified to be differentially expressed between these breeds. Moreover, Western blotting was used to identify the presence of kynurenine 3-monooxygenasn (KMO) in liver samples from eight pigs from two different KMO genotypes. Kidney samples were also tested and used as positive control. No difference was observed between the two different phenotypes. These data were compared with genotyping results that the group reported for this gene. The results confirmed that there is no association between mutations that changes the 3D inferred protein structure and the protein level. Changes in the effect on the metabolomic pathway of the encoded enzyme might be due to different enzyme activities due to the identified mutations.
Thirdly, metabolomics analysis was performed using nuclear magnetic resonance (NMR) and MS to characterise and compare the metabolites of ID and ILW. About 250 samples between urine, plasma, serum and liver from the two breeds were processed using the facilities of Teagasc. Data analysis of the metabolomic dataset using Partial Least Squared Discriminant Analysis (PLS-DA) showed some patterns in the samples related to the two breeds.
Fourthly, the dataset developed over the project from the proteomics and metabolomics studies were processed using different approaches. For example, ANOVA analysis, PCA, PLS-DA were applied for the proteomics and metabolomics analysis. Different proteins and metabolites were identified to change significantly between breeds (see above). A new statistical pipeline to statistically validate the results was applied.
Cytoscape was used to obtain a functional interpretation of the 25 proteins differentially abundant between breeds. STRING database was used to investigate the protein-protein interaction of the proteins differentially abundant.
Moreover, the Pig Quantitative Trait Locus Database was used to explore possible links between up or down-regulated proteins and genomic QTLs for economically relevant traits and parameters that could be affected by genes encoding these proteins.
The multilayer data produced using these multi “omics†approaches were stored in the database with the genotype information already collected by Fontanesi’s group and will be an important aid in further studies.
Fifthly, several activities were undertaken, by the ER to communicate the output of the research to a wider public, nine between conferences and workshops, about ten between seminar and classes, one article is currently under review in PLoS One journal. This article is already available in a repository as preprints papers. At least other three papers will be published from the work done and will be freely accessible. Many other activities were undertaken to introduce among students and general public the research work performed in the MSCA and its implications for citizens. Moreover, the ER to better integrate his activities with the daily life in Bologna, involved in these initiatives several small local enterprises and two associations that are dealing wi
A sustainable livestock production sector should deal with the increasing worldwide demand of animal products by limiting the negative impacts on the environment, reducing production costs and on the same time taking care of animal health and welfare. Proteins and metabolites that were identified as differentially expressed between breeds in the project are a step forward in this direction. Indeed, thanks to the improvement of high throughput technologies to investigate molecular phenotypes only now can be produced the data needed to understand the fine biological processes underlining animal production. The work of the ER demonstrated that breed differences at proteome and metabolome level could be useful to describe breed specific metabolic characteristics. In livestock science, a better understanding of the link between phenotypes and genotypes will eventually allow researchers to develop tools that can guide animal breeding, selection and management decisions for a more sustainable animal-production sector, the data obtained over the project will contribute to this goal. Moreover, the long term benefits for the society and economy will be the reduced negative impacts of the pig production sector as more robust and more productive animals can be selected. Such a programme will also benefit the consumers in that they are consistently guaranteed a product of the required quality and are ensured value for money in purchasing decisions. The project contributed also to the strengthening of the pig as a biomedical model, which may have indirect benefit for human health.
More info: http://markthepig.eu/.