Your search keyword '"Cameli, Cinzia"' showing total 4 results

1. Investigation of genetic risk variants for nicotine dependence and cluster headache

Author

Cameli, Cinzia

Subjects

BIO/18 Genetica

Abstract

The main focus of my PhD has been the analysis of rare and common variants in genetic susceptibility to two complex traits: nicotine dependence (ND) and cluster headache (CH). Firstly, we conducted a genetic study to investigate the role of genetic variation at CHRNA7 and CHRFAM7A in smoking phenotypes, and to test the hypothesis that 7nAChR variation may modulate the efficacy of varenicline in smoking cessation. The study was performed on 408 regular tobacco smokers, recruited at smoking cessation centers, including 142 individuals treated with varenicline. We determined the CHRNA7 and CHRFAM7A copy number, the rs67158670 genotypes in CHRFAM7A and we resequenced the CHRNA7 proximal promoter. Our results point to a role for CHRNA7 promoter variants in tobacco addiction mechanisms; moreover, our study provides the first evidence that CHRFAM7A copy number variation could affect the response to varenicline treatment. Secondly, In order to investigate the genetic background of CH we performed a genome-wide association analysis on 99 Italian CH patients and 359 controls, using the Infinium PsychArray (Illumina). SNPs genotyping data were used to conduct genome-wide single marker case-control association analysis using common SNPs. Even if no genome-wide significant loci were reported, this analysis led to the identification of a suggestive association with a common variant of the PACAP receptor gene (ADCYAP1R1). Furthermore, we performed a gene-based association analysis considering rare protein altering variants in 745 candidate genes with a possible role in CH. This analysis provided evidence of association for a rare potentially damaging missense variant in the MME gene. ADCYAP1R1 and MME both represent very interesting candidate genes for CH, as their gene products are known to have an important function in pain mechanisms; thus, our study provides the first evidence that genetic variation in genes related to pain processing might have a role in CH susceptibility.

Published

2018

2. Dissecting the multifaceted contribution of the mitochondrial genome to autism spectrum disorder

Author

Leonardo Caporali, Claudio Fiorini, Flavia Palombo, Martina Romagnoli, Flavia Baccari, Corrado Zenesini, Paola Visconti, Annio Posar, Maria Cristina Scaduto, Danara Ormanbekova, Agatino Battaglia, Raffaella Tancredi, Cinzia Cameli, Marta Viggiano, Anna Olivieri, Antonio Torroni, Elena Maestrini, Magali Jane Rochat, Elena Bacchelli, Valerio Carelli, Alessandra Maresca, Caporali, Leonardo, Fiorini, Claudio, Palombo, Flavia, Romagnoli, Martina, Baccari, Flavia, Zenesini, Corrado, Visconti, Paola, Posar, Annio, Scaduto, Maria Cristina, Ormanbekova, Danara, Battaglia, Agatino, Tancredi, Raffaella, Cameli, Cinzia, Viggiano, Marta, Olivieri, Anna, Torroni, Antonio, Maestrini, Elena, Rochat, Magali Jane, Bacchelli, Elena, Carelli, Valerio, and Maresca, Alessandra

Subjects

Genetics, Molecular Medicine, mitochondrial DNA, mitochondrial haplogroups, universal heteroplasmy, autism spectrum disorder, autism risk, Genetics (clinical)

Abstract

Autism spectrum disorder (ASD) is a clinically heterogeneous class of neurodevelopmental conditions with a strong, albeit complex, genetic basis. The genetic architecture of ASD includes different genetic models, from monogenic transmission at one end, to polygenic risk given by thousands of common variants with small effects at the other end. The mitochondrial DNA (mtDNA) was also proposed as a genetic modifier for ASD, mostly focusing on maternal mtDNA, since the paternal mitogenome is not transmitted to offspring. We extensively studied the potential contribution of mtDNA in ASD pathogenesis and risk through deep next generation sequencing and quantitative PCR in a cohort of 98 families. While the maternally-inherited mtDNA did not seem to predispose to ASD, neither for haplogroups nor for the presence of pathogenic mutations, an unexpected influence of paternal mtDNA, apparently centered on haplogroup U, came from the Italian families extrapolated from the test cohort (n = 74) when compared to the control population. However, this result was not replicated in an independent Italian cohort of 127 families and it is likely due to the elevated paternal age at time of conception. In addition, ASD probands showed a reduced mtDNA content when compared to their unaffected siblings. Multivariable regression analyses indicated that variants with 15%–5% heteroplasmy in probands are associated to a greater severity of ASD based on ADOS-2 criteria, whereas paternal super-haplogroups H and JT were associated with milder phenotypes. In conclusion, our results suggest that the mtDNA impacts on ASD, significantly modifying the phenotypic expression in the Italian population. The unexpected finding of protection induced by paternal mitogenome in term of severity may derive from a role of mtDNA in influencing the accumulation of nuclear de novo mutations or epigenetic alterations in fathers’ germinal cells, affecting the neurodevelopment in the offspring. This result remains preliminary and needs further confirmation in independent cohorts of larger size. If confirmed, it potentially opens a different perspective on how paternal non-inherited mtDNA may predispose or modulate other complex diseases.

Published

2022

3. Contribution of CACNA1H Variants in Autism Spectrum Disorder Susceptibility

Author

Marta Viggiano, Tiziano D'Andrea, Cinzia Cameli, Annio Posar, Paola Visconti, Maria Cristina Scaduto, Roberta Colucci, Magali J. Rochat, Fabiola Ceroni, Giorgio Milazzo, Sergio Fucile, Elena Maestrini, Elena Bacchelli, Viggiano, Marta, D'Andrea, Tiziano, Cameli, Cinzia, Posar, Annio, Visconti, Paola, Scaduto, Maria Cristina, Colucci, Roberta, Rochat, Magali J., Ceroni, Fabiola, Milazzo, Giorgio, Fucile, Sergio, Maestrini, Elena, and Bacchelli, Elena

Subjects

Cav3.2, Psychiatry and Mental health, VGCCs, CACNA1H, mental disorders, rare variants, calcium channel, ASD, rare variants, VGCCs, CACNA1H, Cav3.2, calcium channel, ASD

Abstract

Autism Spectrum Disorder (ASD) is a highly heterogeneous neuropsychiatric disorder with a strong genetic component. The genetic architecture is complex, consisting of a combination of common low-risk and more penetrant rare variants. Voltage-gated calcium channels (VGCCs or Cav) genes have been implicated as high-confidence susceptibility genes for ASD, in accordance with the relevant role of calcium signaling in neuronal function. In order to further investigate the involvement of VGCCs rare variants in ASD susceptibility, we performed whole genome sequencing analysis in a cohort of 105 families, composed of 124 ASD individuals, 210 parents and 58 unaffected siblings. We identified 53 rare inherited damaging variants in Cav genes, including genes coding for the principal subunit and genes coding for the auxiliary subunits, in 40 ASD families. Interestingly, biallelic rare damaging missense variants were detected in the CACNA1H gene, coding for the T-type Cav3.2 channel, in ASD probands from two different families. Thus, to clarify the role of these CACNA1H variants on calcium channel activity we performed electrophysiological analysis using whole-cell patch clamp technology. Three out of four tested variants were shown to mildly affect Cav3.2 channel current density and activation properties, possibly leading to a dysregulation of intracellular Ca2+ ions homeostasis, thus altering calcium-dependent neuronal processes and contributing to ASD etiology in these families. Our results provide further support for the role of CACNA1H in neurodevelopmental disorders and suggest that rare CACNA1H variants may be involved in ASD development, providing a high-risk genetic background.

Published

2022

4. Analysis ofCHRNA7rare variants in autism spectrum disorder susceptibility

Author

Silvia Lomartire, Raffaella Tancredi, James S. Sutcliffe, Agatino Battaglia, Elena Bacchelli, Susanne Thomson, Cinzia Cameli, Elena Maestrini, Bacchelli, Elena, Battaglia, Agatino, Cameli, Cinzia, Lomartire, Silvia, Tancredi, Raffaella, Thomson, Susanne, Sutcliffe, James S., and Maestrini, Elena

Subjects

Male, Adolescent, alpha7 Nicotinic Acetylcholine Receptor, Autism Spectrum Disorder, DNA Mutational Analysis, Genetic Association Studie, Copy number variant, Polymorphism, Single Nucleotide, DNA Mutational Analysi, Exon, symbols.namesake, Neurodevelopmental disorder, Genetics, medicine, Humans, Coding region, Genetic Predisposition to Disease, Copy-number variation, Gene, Genetic Association Studies, Genetics (clinical), Sanger sequencing, biology, CHRNA7, 15q13.3, medicine.disease, Sequence variant, Autism spectrum disorder, Case-Control Studies, biology.protein, symbols, Autism, Female, Case-Control Studie, Human

Abstract

Chromosome 15q13.3 recurrent microdeletions are causally associated with a wide range of phenotypes, including autism spectrum disorder (ASD), seizures, intellectual disability, and other psychiatric conditions. Whether the reciprocal microduplication is pathogenic is less certain. CHRNA7, encoding for the alpha7 subunit of the neuronal nicotinic acetylcholine receptor, is considered the likely culprit gene in mediating neurological phenotypes in 15q13.3 deletion cases. To assess if CHRNA7 rare variants confer risk to ASD, we performed copy number variant analysis and Sanger sequencing of the CHRNA7 coding sequence in a sample of 135 ASD cases. Sequence variation in this gene remains largely unexplored, given the existence of a fusion gene, CHRFAM7A, which includes a nearly identical partial duplication of CHRNA7. Hence, attempts to sequence coding exons must distinguish between CHRNA7 and CHRFAM7A, making next-generation sequencing approaches unreliable for this purpose. A CHRNA7 microduplication was detected in a patient with autism and moderate cognitive impairment; while no rare damaging variants were identified in the coding region, we detected rare variants in the promoter region, previously described to functionally reduce transcription. This study represents the first sequence variant analysis of CHRNA7 in a sample of idiopathic autism.

Published

2015