Your search keyword '"Valeria Palumbo"' showing total 2 results

1. Intimate functional interactions between TGS1 and the Smn complex revealed by an analysis of the Drosophila eye development

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Author

Stefano Cacchione, Laura Ciapponi, Gemma Noviello, Paolo Maccallini, James G. Wakefield, Giovanni Cenci, S. D'Angeli, Veronica Lisi, Elisabetta Bucciarelli, Grazia D. Raffa, Livia Scatolini, Francesca Bavasso, Maurizio Gatti, and Valeria Palumbo more...

Subjects

0303 health sciences, Telomerase, animal diseases, Transgene, Trimethylguanosine synthase, Spinal muscular atrophy, Biology, medicine.disease, Phenotype, nervous system diseases, Cell biology, 03 medical and health sciences, 0302 clinical medicine, nervous system, SMN complex, medicine, Eye development, Gene, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Trimethylguanosine synthase 1 (TGS1) is a conserved enzyme that mediates formation of the trimethylguanosine cap on several RNAs, including snRNAs and telomerase RNA. Previous studies have shown that TGS1 binds the Survival Motor Neuron (SMN) protein, whose deficiency causes spinal muscular atrophy (SMA). In addition, TGS1 depletion results in increased hTR levels and telomere elongation in human cells. Here, we analyzed the roles of theDrosophilaorthologs of the humanTGS1andSMNgenes. We show that theDrosophilaTGS1 protein (dTgs1) physically interacts with all subunits of theDrosophilaSmn complex (Smn, Gem2, Gem3, Gem4 and Gem5), and that a humanTGS1transgene rescues the mutant phenotype caused bydTgs1loss. We demonstrate that bothdTgs1andSmnare required for viability of retinal progenitor cells and that downregulation of these genes leads to a reduced eye size. Importantly, overexpression ofdTgs1partially rescues the eye defects caused by Smn depletion, and vice versa. These results suggest that theDrosophilaeye model can be exploited for screens aimed at the identification of genes and drugs that modify the phenotypes elicited by Tgs1 and Smn deficiency. These modifiers could help to devise new therapies for SMA and diseases caused by telomerase insufficiency. more...

Published

2020

2. Neocentromeres in 15q24-26 Map to Duplicons Which Flanked an Ancestral Centromere in 15q25

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Author

Nicoletta Archidiacono, Jonathan M. Mudge, Michael S. Jackson, Valeria Palumbo, Roberto Giorda, Mauro Pierluigi, Mario Ventura, Mariano Rocchi, Orsetta Zuffardi, Sally F. Burn, and Elisabeth Blennow

Subjects

Genetic Markers, Animals, Centromere, Cercopithecidae, Chromosome Inversion, Chromosomes, Human, Pair 14, Chromosomes, Human, Pair 15, Gene Rearrangement, Genome, Human, Humans, Physical Chromosome Mapping, Recombination, Genetic, Evolution, Molecular, Gene Duplication, Neocentromere, Evolution, Biology, Chromosomes, Phobic disorder, Genetic, Genetics, Letters, Genetics (clinical), Chromosomal inversion, Genome, Pair 14, Pair 15, Molecular, Chromosome, Gene rearrangement, Recombination, Chromosomal region, Human

Abstract

The existence of latent centromeres has been proposed as a possible explanation for the ectopic emergence of neocentromeres in humans. This hypothesis predicts an association between the position of neocentromeres and the position of ancient centromeres inactivated during karyotypic evolution. Human chromosomal region 15q24-26 is one of several hotspots where multiple cases of neocentromere emergence have been reported, and it harbors a high density of chromosome-specific duplicons, rearrangements of which have been implicated as a susceptibility factor for panic and phobic disorders with joint laxity. We investigated the evolutionary history of this region in primates and found that it contains the site of an ancestral centromere which became inactivated about 25 million years ago, after great apes/Old World monkeys diverged. This inactivation has followed a noncentromeric chromosomal fission of an ancestral chromosome which gave rise to phylogenetic chromosomes XIV and XV in human and great apes. Detailed mapping of the ancient centromere and two neocentromeres in 15q24-26 has established that the neocentromere domains map approximately 8 Mb proximal and 1.5 Mb distal of the ancestral centromeric region, but that all three map within 500 kb of duplicons, copies of which flank the centromere in Old World Monkey species. This suggests that the association between neocentromere and ancestral centromere position on this chromosome may be due to the persistence of recombinogenic duplications accrued within the ancient pericentromere, rather than the retention of “centromere-competent” sequences per se. The high frequency of neocentromere emergence in the 15q24-26 region and the high density of clinically important duplicons are, therefore, understandable in the light of the evolutionary history of this region. more...

Published

2003