Raffaella Stallone

3p14.1 de novo microdeletion involving the FOXP1 gene in an adult patient with autism, severe speech delay and deficit of motor coordination

Interstitial deletion of chromosome region 3p14.1, including FOXP1 gene, is relatively rare and, until recently, there were no strong evidences to support the hypothesis that this microdeletion could play a role in the etiology of genomic disorders. Here, we report on an adult patient with a recognizable phenotype of autism, severe speech delay, deficit of motor coordination and typical dysmorphic features. Analysis of a dense whole genome single-nucleotide polymorphism (SNP) array showed a 1Mb interstitial deletion of chromosome region 3p14.1 including the entire coding region of FOXP1 (MIM 605515) gene. In order to study the parental origin of the deletion, we analyzed selected SNPs in the deleted area in the proband and his parents showing Mendelian incompatibilities suggesting a de novo deletion on the chromosome of paternal origin. Despite the frequency of this genomic alteration has not been estimated, our patient confirm the hypothesis that microdeletion of 3p14.1 seems to be a rare cause of cognitive disorders and that haploinsufficiency of FOXP1 may play a role in neurological and language deficits in patients carrying a 3p14.1 deletion. Finally, our patient is also important because useful to further delineate the clinical spectrum secondary to the 3p14.1 microdeletions.

A novel deletion in 2q24.1q24.2 in a girl with mental retardation and generalized hypotonia: a case report

BackgroundChromosomal imbalances, recognized as the major cause of mental retardation, are often due to submicroscopic deletions or duplications not evidenced by conventional cytogenetic methods. To date, interstitial deletion of long arm of chromosome 2 have been reported for more than 100 cases, although studies reporting small interstitial deletions involving the 2q24.1q24.2 region are rare. With the widespread clinical use of comparative genomic hybridization chromosomal microarray technology, several cryptic chromosome imbalances have outlined new genotype-phenotype correlations and isolated a number of distinctive clinical conditions.Resultshere we report on a girl with mental retardation and generalized hypotonia. A genome-wide screen for copy number variations (CNVs) using single nucleotide polymorphisms (SNPs) array revealed a 7.5 Mb interstitial deletion of chromosome region 2q24.1q24.2 encompassing 59 genes, which was absent in parents. The gene content analysis of the deleted region and review of the literature revealed the presence of some genes that may be indicated as good candidate in generating the main clinical features of the patient.Discussionthe present case represents a further patient described in the literature with an interstitial deletion of chromosome 2q24.1q24.2. Our patient shares some clinical features with the previously reported patients carriers of overlapping 2q24 deletion. Although more cases are needed to delineate the full-blown phenotype of 2q24.1q24.2 deletion syndrome, published data and present observation suggest that hemizygosity of this region results in a clinically recognizable phenotype. Considering these clinical and cytogenetic similarities, we suggest the existence of an emerging syndrome associated to 2q24.1q24.2 region.

Interstitial 16p13.3 microduplication: Case report and critical review of genotype–phenotype correlation

We report on a patient with a recognizable phenotype of intellectual disability, multiple congenital anomalies, musculoskeletal anomalies and craniofacial dysmorphisms, carrying a de novo 0.4 Mb duplication of chromosome region 16p13.3 detected by SNP-array analysis. In addition, myopia, microcephaly and growth retardation were observed. The causal 16p13.3 duplication is one of the smallest reported so far, and includes the CREB binding protein gene (CREBBP, MIM 600140), whose haploinsufficiency is responsible for the Rubinstein-Taybi syndrome, and the adenylate cyclase 9 gene (ADCY9, MIM 603302). By comparing the clinical manifestations of our patient with those of patients carrying similar rearrangements, we confirmed that 16p13.3 microduplications of the Rubinstein-Taybi region result in a recognizable clinical condition that likely represents a single gene disorder. In addition, our case allowed us to define with more precision the smallest region of overlap (SRO) in all patients reported so far, encompassing only the CREBBP gene, and is useful to confirm and further define the phenotypic characteristics due to duplication of the CREBBP gene, being the first case of interstitial duplication with microcephaly and growth defects reported to date.

An emerging phenotype of interstitial 15q25.2 microdeletions: clinical report and review.

Interstitial deletions of chromosome 15q25.2 are rare. To date, only nine patients with microdeletions within this chromosomal region have been described. Here, we report on a girl with severe speech and psychomotor delay, behavioral problems and mild dysmorphic features with a 1.6 Mb deletion in 15q25.2 region. In order to study the parental origin of the rearrangement, we analyzed selected SNPs in the deleted area in the patient and her parents, showing Mendelian incompatibilities suggesting a de novo deletion on the chromosome of maternal origin. By comparing the clinical and molecular features of our patient with five previously reported cases of an overlapping deletion, we suggest that 15q25.2 deletion is an emerging syndrome characterized by a distinct although variable spectrum of clinical manifestations, including mild dysmorphic features, neurodevelopmental delay, and a recognizable pattern of congenital malformation. Furthermore, our patient is the second one in which a behavioral phenotype characterized by hyperactivity, anxiety, and autistic features was reported, indicating that these features might be part of this new syndromic condition. Breakpoints of the deletion in the patient reported here are useful to better define the smallest region of overlap (SRO) among all the patients. Selected genes that are present in the hemizygous state and which might be important for the phenotype of these patients, are discussed in context of the clinical features. In conclusion, our patient increases the knowledge about the molecular and phenotypic consequences of interstitial 15q25.2 deletions, highlighting that deletions of this region may be responsible for a new microdeletion syndrome.

Microdeletion of 12q24.31: Report of a girl with intellectual disability, stereotypies, seizures and facial dysmorphisms

We provide a detailed clinical and molecular characterization of an 11‐year‐old female patient presenting with neurodevelopmental delay (NDD), intellectual disability (ID), seizures, stereotypies and dysmorphic features. Chromosomal microarrays analysis (CMA) detected a small, rare de novo deletion on chromosome 12q24.31 encompassing 31 protein‐coding RefSeq genes and a microRNA. Phenotypic comparison with molecularly well‐defined cases previously reported in the literature harboring an overlapping 12q24.31 microdeletion indicate that these patients shared common clinical features including neurodevelopmental delay, intellectual disability and behavioral problems. Also, seizures and dysmorphic features are frequent and a consistent pattern was recognized. Since there are remarkable resemblance between the patient described here and at least another one previously reported, our report is provides supportive evidence for the existence of an emerging syndrome caused by a microdeletion in 12q24.31. We propose a minimal region shared among patients contributing to the etiology of the common clinical features observed suggesting as candidate, for the first time, the gene SETD1B which is a component of a histone methyltransferase complex. In addition, we speculate on the possible contributive role of the MIR4304 to some clinical features observed in our patient. Evaluation of more patients with well‐characterized deletions within 12q24.31, as well as careful clinical assessment of them, is needed to corroborate our hypothesis, to perform a more detailed genotype‐phenotype correlation and, finally, to fully delineate this emerging microdeletion syndrome.

8q12.1q12.3 de novo microdeletion involving the CHD7 gene in a patient without the major features of CHARGE syndrome: Case report and critical review of the literature

CHARGE syndrome is an autosomal dominant inherited disorder characterized by a specific and recognizable pattern of anomalies. De novo mutations or deletions of the gene encoding chromodomain helicase DNA binding protein 7 (CHD7) are the major cause of CHARGE syndrome. In this report, we describe a patient with a typical phenotype characterized by psychomotor retardation, hypertrichosis, facial asymmetry, synophria, failure to thrive, developmental delay and gastro-esophageal reflux, carrying a de novo 6.04Mb interstitial deletion in 8q12.1q12.3 detected by single nucleotide polymorphism (SNP) array analysis. Despite the deletion includes CHD7 and although the patient shares some of the clinical features of the CHARGE syndrome, she does not fulfill the clinical criteria for this syndrome. To the best of our knowledge, this is the second case with an entire deletion of the CHD7 gene not leading to CHARGE syndrome and, for this reason, useful to expand and further delineate the clinical features associated with the 8q12.1q12.3 deletion. Furthermore, the literature review revealed that the phenotype secondary to duplications of the same region partially overlaps with the phenotype reported in this study. Selected genes that are present in the hemizygous state and which might be important for the phenotype of this patient, are discussed in context of the clinical features.

Putative TMPRSS3/GJB2 digenic inheritance of hearing loss detected by targeted resequencing

The paper describes a putative digenic form of deafness in two siblings affected by non-syndromic hereditary hearing loss, detected by a Targeted resequencing approach. Given that a previous paper suggested TMPRSS3 and GJB2 genes as responsible for a digenic form of hearing loss, our data support and reinforce this hypothesis.

Refinement of the critical 7p22.1 deletion region: Haploinsufficiency of ACTB is the cause of the 7p22.1 microdeletion-related developmental disorders

Non-recurrent microdeletion (≤2 Mb in size) in 7p22.1 is a rarely described cytogenetic aberration, only recently reported in patients with developmental delay/intellectual disability, short stature and microcephaly. The size of the deletions ranged from 0.37 to 1.5 Mb, and reported genotype-phenotype correlations identified a minimum deleted region of 0.37 Mb involving the FBLX18, ACTB, FSCN1, RNF216 and ZNF815P genes. The authors suggested that deletion of ACTB, which encodes β-actin, an essential component of the cytoskeleton, could be responsible for the clinical features observed in the patients with a 7p22.1 microdeletion. Here, we describe a 23-month-old child displaying developmental delay, short stature, microcephaly and distinctive facial features. Chromosomal microarray analysis performed using high-resolution SNP-array platform revealed a de novo interstitial 60 Kb microdeletion in the 7p22.1 region (from 5,509,127 bp to 5,569,096 bp, hg19) encompassing only two genes: FBXL18 and ACTB. To the best of our knowledge, this is the smallest deletion at 7p22.1 to date reported in medical literature (Pubmed). Combining our data with phenotypic and genotypic data of cases from literature, we were able to narrow the minimal critical region, which contained only two genes, i.e., FBXL18 and ACTB. Our finding is useful to perform a more accurate genotype-phenotype correlation and strongly strengthen the hypothesis that haploinsufficiency of ACTB is the main cause of the clinical phenotype observed in the patients with 7p22.1 microdeletions, facilitating genetic diagnosis and counseling.

Multifaceted enrichment analysis of RNA–RNA crosstalk reveals cooperating micro-societies in human colorectal cancer

Alterations in the balance of mRNA and microRNA (miRNA) expression profiles contribute to the onset and development of colorectal cancer. The regulatory functions of individual miRNA-gene pairs are widely acknowledged, but group effects are largely unexplored. We performed an integrative analysis of mRNA–miRNA and miRNA–miRNA interactions using high-throughput mRNA and miRNA expression profiles obtained from matched specimens of human colorectal cancer tissue and adjacent non-tumorous mucosa. This investigation resulted in a hypernetwork-based model, whose functional backbone was fulfilled by tight micro-societies of miRNAs. These proved to modulate several genes that are known to control a set of significantly enriched cancer-enhancer and cancer-protection biological processes, and that an array of upstream regulatory analyses demonstrated to be dependent on miR-145, a cell cycle and MAPK signaling cascade master regulator. In conclusion, we reveal miRNA-gene clusters and gene families with close functional relationships and highlight the role of miR-145 as potent upstream regulator of a complex RNA–RNA crosstalk, which mechanistically modulates several signaling pathways and regulatory circuits that when deranged are relevant to the changes occurring in colorectal carcinogenesis.

PARK2 Microduplication: Clinical and Molecular Characterization of a Further Case and Review of the Literature.

We report on a patient with psychomotor deficits, language delay, dyspraxia, skeletal anomalies, and facial dysmorphisms (hirsutism, right palpebral ptosis, a bulbous nasal tip with enlarged and anteverted nares, and a mild prominent antihelix stem). Using high-resolution SNP array analysis, we identified a 0.49-Mb microduplication in chromosome 6q26 inherited from the mother involving the PARK2 gene: arr[hg19] 6q26(162,672,821-163,163,143)×3 mat. To the best of our knowledge, this is the third patient to date described in whom a 6q26 microduplication encompassing only the PARK2 gene has been reported in medical literature. The PARK2 gene is a neurodevelopmental gene that was initially discovered as one of the causes of autosomal recessive juvenile Parkinson disease and subsequently reported to be linked to autism spectrum disorders and attention-deficit hyperactivity disorders. We provide an overview of the literature on PARK2 microduplications and further delineate the associated phenotype. Taken together, our findings confirm the involvement of this gene in neurodevelopmental disorders and are useful to strengthen the hypothesis that, although with variable expressivity and incomplete penetrance, the PARK2 microduplication is associated with a new emerging neurodevelopmental delay syndrome. However, clinical and molecular evaluations of more patients with the microduplication are needed for full delineation of this syndrome.