Raffaele Mazza

Discovery, characterization and validation of single nucleotide polymorphisms within 206 bovine genes that may be considered as candidate genes for beef production and quality

A large number of putative single nucleotide polymorphisms (SNPs) have been identified from the bovine genome-sequencing project. However, few of these have been validated and many will turn out to be sequencing artefacts or have low minor allele frequencies. In addition, there is little information available on SNPs within coding regions, which are likely to be responsible for phenotypic variation. Therefore, additional SNP discovery is necessary to identify and validate polymorphisms both in specific genes and genome-wide. Sequence-tagged sites within 286 genes were resequenced from a panel of animals representing a wide range of European cattle breeds. For 80 genes, no polymorphisms were identified, and 672 putative SNPs were identified within 206 genes. Fifteen European cattle breeds (436 individuals plus available parents) were genotyped with these putative SNPs, and 389 SNPs were confirmed to have minor allele frequencies above 10%. The genes containing SNPs were localized on chromosomes by radiation hybrid mapping and on the bovine genome sequence by Blast. Flanking microsatellite loci were identified, to facilitate the alignment of the genes containing the SNPs in relation to mapped quantitative trait loci. Of the 672 putative SNPs discovered in this work, only 11 were found among the validated SNPs and 100 were found among the approximately 2.3 million putative SNPs currently in dbSNP. The genes studied in this work could be considered as candidates for traits associated with beef production and the SNPs reported will help to assess the role of the genes in the genetic control of muscle development and meat quality. The allele frequency data presented allows the general utility of the SNPs to be assessed.

Annotation of 390 bovine miRNA genes by sequence similarity with other species

Source/description: MicroRNAs (miRNAs) are small noncoding RNA molecules that negatively regulate the expression of many protein-coding genes by affecting the degradation rate of the mRNAs or the correct translation of the gene products. miRNAs are normally encoded in pre-miRNA sequences with lengths of approximately 70 nt; these in turn are processed into mature sequences of about 22 nt. In the latest ENSEMBL release of the cow genome (http://www.ensembl.org/Bos_taurus), there are 524 identified miRNA genes, but only 117 are annotated in MIRBASE (http://microrna.sanger.ac.uk/) with unique identifiers. The remaining 407 miRNA genes are annotated as novel genes by the ENSEMBL annotation pipeline. We investigated this last group of sequences, which are predicted pre-miRNA-encoding genes for which corresponding bovine miRNAs have not yet been identified. A similarity search approach was used to identify homologous sequences among the miRNAs annotated in other species.

Recent Advance in DNA-based Traceability and Authentication of Livestock Meat PDO and PGI Products

This review updates the available molecular techniques and technologies and discusses how they can be used for traceability, food control and enforcement activities. The review also provides examples on how molecular techniques succeeded to trace back unknowns to their breeds of origin, to fingerprint single individuals and to generate evidence in court cases. The examples demonstrate the potential of the DNA based traceability techniques and explore possibilities for translating the next generation genomics tools into a food and feed control and enforcement framework.

Detection of QTL for milk protein percentage in Italian Friesian cattle by AFLP markers and selective genotyping

We targeted quantitative trait loci (QTL) for milk protein percentage (P%) in two Italian Holstein granddaughter design families using selective genotyping in combination with high throughput amplified fragment length polymorphism (AFLP) markers. A total of 64 extreme high and low sires in respect to estimated breeding value (EBV) for P% (EBVP%) were genotyped with 25 AFLP primer combinations that revealed 305 and 291 polymorphisms in the two families. Association between markers and EBVP% was investigated by a linear model only on bands having paternal origin (105 and 96 AFLP bands in family D and S, respectively). Although no marker was significantly associated with the target trait after correction for multiple comparisons, 17 AFLP markers, significant without correction for multiple tests, were considered suggestive of the presence of a QTL. Eleven of these were successfully located on six Bos taurus (BTA) chromosomes by radiation hybrid or in-silico mapping. Ten of these mapped in the immediate neighbourhood (less than 10 cM) of already described QTL for P%. Suggestive association was verified in four regions by microsatellites analysis: one on BTA 10; one on BTA 28; and two on BTA 18. Microsatellites identified significant effects by single marker and interval mapping analyses on BTA 10 and BTA 28, while they were only suggestive of the presence of QTL on BTA 18. In summary, our results firstly indicate that AFLP markers may be used to seek QTL exploiting a selective genotyping approach in GDD, a wide used experimental design in cattle; secondly, propose two approaches for AFLP mapping, namely in-silico mapping exploiting most updated release from the bovine whole genome sequencing project, and physical mapping exploiting a panel of Bovine/Hamster Radiation Hybrids; and thirdly, provide new information on QTLs for an economic important trait in a never investigated Holstein cattle population. AFLP in combination with selective genotyping can be a useful strategy for QTL searching in minor livestock species, sometimes having large economic impact in marginal areas, where more informative markers are still poorly developed.

The other side of comparative genomics: genes with no orthologs between the cow and other mammalian species

BackgroundWith the rapid growth in the availability of genome sequence data, the automated identification of orthologous genes between species (orthologs) is of fundamental importance to facilitate functional annotation and studies on comparative and evolutionary genomics. Genes with no apparent orthologs between the bovine and human genome may be responsible for major differences between the species, however, such genes are often neglected in functional genomics studies.ResultsA BLAST-based method was exploited to explore the current annotation and orthology predictions in Ensembl. Genes with no orthologs between the two genomes were classified into groups based on alignments, ontology, manual curation and publicly available information. Starting from a high quality and specific set of orthology predictions, as provided by Ensembl, hidden relationship between genes and genomes of different mammalian species were unveiled using a highly sensitive approach, based on sequence similarity and genomic comparison.ConclusionsThe analysis identified 3,801 bovine genes with no orthologs in human and 1010 human genes with no orthologs in cow, among which 411 and 43 genes, respectively, had no match at all in the other species. Most of the apparently non-orthologous genes may potentially have orthologs which were missed in the annotation process, despite having a high percentage of identity, because of differences in gene length and structure. The comparative analysis reported here identified gene variants, new genes and species-specific features and gave an overview of the other side of orthology which may help to improve the annotation of the bovine genome and the knowledge of structural differences between species.

Identification of candidate genes for paratuberculosis resistance in the native Italian Garfagnina goat breed

Paratuberculosis disease is a chronic bacterial disease infection of ruminants of global relevance, caused by MAP (Mycobacterium avium subsp. paratuberculosis). The present study was conducted on the Garfagnina goat breed that is an Italian native goat population registered on the Tuscan regional repertory of genetic resources at risk of extinction. Forty-eight adult goats (27 serologically positive to MAP-positive and 21 serologically negative to MAP-negative) belonging to a single flock that had experienced annual mortalities due to MAP infection were identified and genotyped with the Illumina GoatSNP60 BeadChip. Diagnosis was achieved by serological tests, as well as post-mortem examination of affected animals. A genome-wide scan was then performed on the individual marker genotypes, in an attempt to identify genomic regions associated with MAP infection disease. Nine significant markers were highlighted and they were located within, or nearby, annotated genes. Two genes found in this study encode are linked to protein kinases that are among the most important enzymes involved in the immune response to Johne’s disease, and four genes are involved in the functions of the Golgi complex.

Genome assembly and transcriptome resource for river buffalo, Bubalus bubalis (2n = 50)

Abstract Water buffalo is a globally important species for agriculture and local economies. A de novo assembled, well-annotated reference sequence for the water buffalo is an important prerequisite for studying the biology of this species, and is necessary to manage genetic diversity and to use modern breeding and genomic selection techniques. However, no such genome assembly has been previously reported. There are 2 species of domestic water buffalo, the river (2n = 50) and the swamp (2n = 48) buffalo. Here we describe a draft quality reference sequence for the river buffalo created from Illumina GA and Roche 454 short read sequences using the MaSuRCA assembler. The assembled sequence is 2.83 Gb, consisting of 366 983 scaffolds with a scaffold N50 of 1.41 Mb and contig N50 of 21 398 bp. Annotation of the genome was supported by transcriptome data from 30 tissues and identified 21 711 predicted protein coding genes. Searches for complete mammalian BUSCO gene groups found 98.6% of curated single copy orthologs present among predicted genes, which suggests a high level of completeness of the genome. The annotated sequence is available from NCBI at accession GCA_000471725.1.

Nanotechnologies Applied to the Analysis of the Animal Genome

Ajmone Marsan, P., Tramontana, S. and Mazza, R., 2007. Nanotechnologies applied to the analysis of the animal genome. Veterinary Research Communications, 31(Suppl. 1), 153–159ABSTRACTWhole genome sequence information and high throughput technologies are speeding up the investigation of cellular processes leading to the phenotypic expression of genetic information. Nanotechnologies provide innovative tools to accomplish this task, increasing throughput and sensitivity and decreasing cost and time of analyses. Goals as ambitious as the sequencing of a mammalian-sized genome in a matter of hours, and of detecting gene expression from a single cell, are just around the corner. Animal breeding will benefit from these advances in the understanding of the genetic basis of complex traits and in the application of molecular information for marker and gene assisted selection.

Assessment of AFLP® marker behaviour in enriching STS radiation hybrid maps

Radiation hybrid (RH) mapping provides a powerful tool to build high-resolution maps of genomes. Here, we demonstrate the use of the AFLP technique for high-throughput typing of RH cell lines. Cattle were used as the model species because an RH panel was available to investigate the behaviour of AFLP markers within the microsatellite- and STS-based maps of this species. A total of 747 AFLP markers were typed on the TM112 RH radiation panel and 651 of these were assigned by two-point analysis to the 29 bovine autosomes and sex chromosomes. AFLP markers were added to the 1222 microsatellite and STS markers that were included in earlier RH maps. Multipoint maps were constructed for seven example chromosomes, which retained 248 microsatellite and STS markers, and added 123 AFLP markers at LOD 4. The addition of the AFLP markers increased the number of markers by 42.1% and the map length by 10.4%. The AFLP markers showed lower retention frequency (RF) values than the STS markers. The comparison of RF values in AFLP markers and their corresponding AFLP-derived STSs demonstrated that the lower RF values were due to the lower detection sensitivity of the AFLP technique. Despite these differences, AFLP and AFLP-derived STS markers mapped to identical or similar positions. These results demonstrate that it is possible to merge AFLP and microsatellite markers in the same map. The application of AFLP technology could permit the rapid construction of RH maps in species for which extensive genome information and large numbers of SNP and microsatellite markers are not available.