Your search keyword '"Mazzagatti A"' showing total 4 results

1. Replication stress generates distinctive landscapes of DNA copy number alterations and chromosome scale losses

Author

Shaikh, Nadeem, Mazzagatti, Alice, De Angelis, Simone, Johnson, Sarah C., Bakker, Bjorn, Spierings, Diana C. J., Wardenaar, René, Maniati, Eleni, Wang, Jun, Boemo, Michael A., Foijer, Floris, and McClelland, Sarah E.

Published

2022

2. Genome-wide evolutionary and functional analysis of the Equine Repetitive Element 1: an insertion in the myostatin promoter affects gene expression

Author

Lela Khoriauli, Riccardo Gamba, Alessandra Russo, Francesco Vella, Ori Klipstein, Alice Mazzagatti, Claudia Badiale, Marco Santagostino, Solomon G. Nergadze, Elena Giulotto, Margherita Bonuglia, Francesca M. Piras, and Elena Raimondi

Subjects

Genotype, Retroelements, Population, Molecular Sequence Data, Retrotransposon, Locus (genetics), Myostatin, Horse genome, Biology, Genome, Polymorphism, Single Nucleotide, Evolution, Molecular, Genes, Reporter, Genetics, Consensus sequence, Animals, Genetics(clinical), Horses, education, Promoter Regions, Genetic, Gene, Genetics (clinical), Conserved Sequence, Phylogeny, Repetitive Sequences, Nucleic Acid, education.field_of_study, Base Sequence, Myostatin gene expression, Mutagenesis, Insertional, Gene Expression Regulation, Genetic Loci, biology.protein, Equids, Research Article, SINEs

Abstract

Background In mammals, an important source of genomic variation is insertion polymorphism of retrotransposons. These may acquire a functional role when inserted inside genes or in their proximity. The aim of this work was to carry out a genome wide analysis of ERE1 retrotransposons in the horse and to analyze insertion polymorphism in relation to evolution and function. The effect of an ERE1 insertion in the promoter of the myostatin gene, which is involved in muscle development, was also investigated. Results In the horse population, the fraction of ERE1 polymorphic loci is related to the degree of similarity to their consensus sequence. Through the analysis of ERE1 conservation in seven equid species, we established that the level of identity to their consensus is indicative of evolutionary age of insertion. The position of ERE1s relative to genes suggests that some elements have acquired a functional role. Reporter gene assays showed that the ERE1 insertion within the horse myostatin promoter affects gene expression. The frequency of this variant promoter correlates with sport aptitude and racing performance. Conclusions Sequence conservation and insertion polymorphism of ERE1 elements are related to the time of their appearance in the horse lineage, therefore, ERE1s are a useful tool for evolutionary and population studies. Our results suggest that the ERE1 insertion at the myostatin locus has been unwittingly selected by breeders to obtain horses with specific racing abilities. Although a complex combination of environmental and genetic factors contributes to athletic performance, breeding schemes may take into account ERE1 insertion polymorphism at the myostatin promoter. Electronic supplementary material The online version of this article (doi:10.1186/s12863-015-0281-1) contains supplementary material, which is available to authorized users.

Published

2015

3. The major horse satellite DNA family is associated with centromere competence.

Author

Cerutti, Federico, Gamba, Riccardo, Mazzagatti, Alice, Piras, Francesca M., Cappelletti, Eleonora, Belloni, Elisa, Nergadze, Solomon G., Raimondi, Elena, and Giulotto, Elena

Subjects

HORSES, CENTROMERE, SATELLITE DNA, CYTOGENETICS, NUCLEOTIDE sequence, GENETICS

Abstract

Background: The centromere is the specialized locus required for correct chromosome segregation during cell division. The DNA of most eukaryotic centromeres is composed of extended arrays of tandem repeats (satellite DNA). In the horse, we previously showed that, although the centromere of chromosome 11 is completely devoid of tandem repeat arrays, all other centromeres are characterized by the presence of satellite DNA. We isolated three horse satellite DNA sequences (37cen, 2P1 and EC137) and described their chromosomal localization in four species of the genus Equus. Results: In the work presented here, using the ChIP-seq methodology, we showed that, in the horse, the 37cen satellite binds CENP-A, the centromere-specific histone-H3 variant. The 37cen sequence bound by CENP-A is GC-rich with 221 bp units organized in a head-to-tail fashion. The physical interaction of CENP-A with 37cen was confirmed through slot blot experiments. Immuno-FISH on stretched chromosomes and chromatin fibres demonstrated that the extension of satellite DNA stretches is variable and is not related to the organization of CENP-A binding domains. Finally, we proved that the centromeric satellite 37cen is transcriptionally active. Conclusions: Our data offer new insights into the organization of horse centromeres. Although three different satellite DNA families are cytogenetically located at centromeres, only the 37cen family is associated to the centromeric function. Moreover, similarly to other species, CENP-A binding domains are variable in size. The transcriptional competence of the 37cen satellite that we observed adds new evidence to the hypothesis that centromeric transcripts may be required for centromere function. [ABSTRACT FROM AUTHOR]

Published

2016

4. Genome-wide evolutionary and functional analysis of the Equine Repetitive Element 1: an insertion in the myostatin promoter affects gene expression.

Author

Santagostino, Marco, Khoriauli, Lela, Gamba, Riccardo, Bonuglia, Margherita, Klipstein, Ori, Piras, Francesca M., Vella, Francesco, Russo, Alessandra, Badiale, Claudia, Mazzagatti, Alice, Raimondi, Elena, Nergadze, Solomon G., and Giulotto, Elena

Subjects

FUNCTIONAL analysis, MYOSTATIN, GENE expression, GENETIC polymorphisms, RETROTRANSPOSONS

Abstract

Background: In mammals, an important source of genomic variation is insertion polymorphism of retrotransposons. These may acquire a functional role when inserted inside genes or in their proximity. The aim of this work was to carry out a genome wide analysis of ERE1 retrotransposons in the horse and to analyze insertion polymorphism in relation to evolution and function. The effect of an ERE1 insertion in the promoter of the myostatin gene, which is involved in muscle development, was also investigated. Results: In the horse population, the fraction of ERE1 polymorphic loci is related to the degree of similarity to their consensus sequence. Through the analysis of ERE1 conservation in seven equid species, we established that the level of identity to their consensus is indicative of evolutionary age of insertion. The position of ERE1s relative to genes suggests that some elements have acquired a functional role. Reporter gene assays showed that the ERE1 insertion within the horse myostatin promoter affects gene expression. The frequency of this variant promoter correlates with sport aptitude and racing performance. Conclusions: Sequence conservation and insertion polymorphism of ERE1 elements are related to the time of their appearance in the horse lineage, therefore, ERE1s are a useful tool for evolutionary and population studies. Our results suggest that the ERE1 insertion at the myostatin locus has been unwittingly selected by breeders to obtain horses with specific racing abilities. Although a complex combination of environmental and genetic factors contributes to athletic performance, breeding schemes may take into account ERE1 insertion polymorphism at the myostatin promoter. [ABSTRACT FROM AUTHOR]

Published

2015