Your search keyword '"C. Jodice"' showing total 2 results

1. Variation of the 3'RR1 HS1.2 Enhancer and Its Genomic Context.

Author

Jodice C, Malaspina P, Ciminelli BM, Martinez-Labarga C, Biancolella M, Novelli G, and Novelletto A

Subjects

Humans, Alleles, Haplotypes, Genome, Human, Transcription Factors genetics, Binding Sites, Enhancer Elements, Genetic genetics, Polymorphism, Single Nucleotide

Abstract

In humans, the HS1.2 enhancer in the Ig heavy-chain locus is modular, with length polymorphism. Previous studies have shown the following features for this variation: (i) strong population structuring; (ii) association with autoimmune diseases; and (iii) association with developmental changes in Ig expression. The HS1.2 region could then be considered as a contributor to inter-individual diversity in humoral response in adaptive immunity. We experimentally determined the HS1.2-length class genotype in 72 of the 1000 Genomes CEU cell lines and assigned the HS1.2 alleles to haplotypes defined by 18 landmark SNPs. We also sequenced the variable portion and ~200 bp of the flanking DNA of 34 HS1.2 alleles. Furthermore, we computationally explored the ability of different allelic arrangements to bind transcription factors. Non-random association between HS1.2 and Gm allotypes in the European population clearly emerged. We show a wealth of variation in the modular composition of HS1.2, with five SNPs further contributing to diversity. Longer alleles offer more potential sites for binding but, for same-length alleles, SNP variation creates/destroys potential binding sites. Altogether, the arrangements of modules and SNP alleles both inside and outside HS1.2 denote an organization of diversity far from randomness. In the context of the strong divergence of human populations for this genomic region and the reported disease associations, our results suggest that selective forces shaped the pattern of its diversity.

Published

2024

2. DNA Damage Stress Response and Follicle Activation: Signaling Routes of Mammalian Ovarian Reserve.

Author

Gonfloni S, Jodice C, Gustavino B, and Valentini E

Subjects

Female, Animals, Humans, Ovarian Follicle, Mammals, Signal Transduction, DNA Damage, Ovarian Reserve

Abstract

Chemotherapy regimens and radiotherapy are common strategies to fight cancer. In women, these therapies may cause side effects such as premature ovarian insufficiency (POI) and infertility. Clinical strategies to protect the ovarian reserve from the lethal effect of cancer therapies needs better understanding of the mechanisms underlying iatrogenic loss of follicle reserve. Recent reports demonstrate a critical role for p53 and CHK2 in the oocyte response to different DNA stressors, which are commonly used to treat cancer. Here we review the molecular mechanisms underlying the DNA damage stress response (DDR) and discuss crosstalk between DDR and signaling pathways implicated in primordial follicle activation.

Published

2022