Clinical and molecular characterization of a patient with interstitial 6q21q22.1 deletion

Background Interstitial 6q deletions, involving the 6q15q25 chromosomal region, are rare events characterized by variable phenotypes and no clear karyotype/phenotype correlation has been determined yet. Results We present a child with a 6q21q22.1 deletion, characterized by array-CGH, associated with developmental delay, intellectual disability, microcephaly, facial dysmorphisms, skeletal, muscle, and brain anomalies. Discussion In our patient, the 6q21q22.1 deleted region contains ten genes (TRAF3IP2, FYN, WISP3, TUBE1, LAMA4, MARCKS, HDAC2, HS3ST5, FRK, COL10A1) and two desert gene regions. We discuss here if these genes had some role in determining the phenotype of our patient in order to establish a possible karyotype/phenotype correlation. Electronic supplementary material The online version of this article (doi:10.1186/s13039-015-0134-7) contains supplementary material, which is available to authorized users.

The phenotype of patients with medial 6q deletion is generally associated with intrauterine growth retardation (IUGR), abnormal respiration, hypertelorism, and upper limb malformations [1]. However, the patients described to date presented a large spectrum of clinical features, depending on the size of the deleted segment, the involved genes, and the genomic architecture of the region, making genotype-phenotype correlation difficult.
Here, we report on the phenotypic and molecular characterization of a new 6q21q22.1 deletion in a boy with developmental delay, intellectual disability, microcephaly, facial dysmorphisms, and skeletal, muscle, and brain anomalies. We compare the phenotype of our patient with that of previously reported patients and discuss the role of the deleted genes in order to establish a possible karyotype/phenotype correlation.

Case presentation
The patient, a 13-year-old boy, is the only child of nonconsanguineous, healthy Paraguayan parents. The child was born at term by elective caesarean section after an uneventful pregnancy. Birth weight was 4060 g and no perinatal diseases were reported. Data on the patient's history as a child are not available because he lived in Paraguay with his grandparents, however delay in psychomotor development was reported (he was able to sit without support at 8 months and to walk at 18 months). At 12 years, he moved to Italy to join his mother and at 13 years he was admitted to our hospital because of mild intellectual disability and dysmorphic features.
Neurological examination demonstrated mild clumsiness without obvious focal signs. On physical examination, his weight was 42.8 Kg (50-75th percentile), height 161 cm (75-90th percentile), and head circumference 52 cm (3rd-10th percentile). He showed facial dysmorphisms (hypertelorism, wide and flat nose), pectus excavatum and chest asymmetry. The absence of pectoralis major and minor muscles on the right side was demonstrated by ultrasound imaging and the diagnosis of Poland Syndrome (PS) (MIM 173800) was made. Standing X-ray films of the full-length spine showed thoracolumbar scoliosis, without vertebral abnormalities ( Figure 1A). No additional anomalies of the kidney, urinary tract, or heart were detected by ultrasound examination. Ophthalmologic evaluation demonstrated intermittent exotropia, bilateral myopia, and normal fundus oculi. Brain magnetic resonance imaging (MRI) showed cerebellar vermis hypoplasia ( Figure 1B, C). Neurophysiological studies including electroencephalogram (EEG) and brainstem auditory evoked potentials (BAEP) resulted normal.

Results
Cytogenetic analysis, performed on GTG-banded metaphases from cultured lymphocytes of the patient and his mother, showed normal karyotypes. The deletion also contains a 1.5 Mb gene desert region that, conversely, is characterized by the presence of several large intergenic non coding RNAs (lincRNAs) and of transcripts of uncertain coding potential (TUCPs), according to The Human Body Map catalogue [14,15]. The 6q22.1 deleted region includes a 1.878 Mb desert region and 2 OMIM genes: FRK (MIM 606573) fyn-related kinase; COL10A1 (MIM 120110) collagen, type X, alpha-1 ( Figure 2).
Array-CGH analysis performed on peripheral blood of the mother was normal.

Discussion
We report on a 13-year-old boy presenting developmental delay, intellectual disability, microcephaly, facial dysmorphisms, and skeletal, muscle, and brain anomalies. Array-CGH identified a 4.71 Mb interstitial deletion at 6q21q22.1 bands. Rosenfeld et al. [8] described 12 individuals with variable deletions within 6q15q22.33 and compared their clinical features to better define karyotype/phenotype correlations. They reported heterogeneous phenotypes, even among individuals with overlapping deletions. They speculated that phenotypic variability could be related to less penetrance, concomitant mutations in other genes, in noncoding regions, such as transcription factor binding sites, or in methylation patterns. Searching for patients with similar chromosomal imbalances, we select the patient n.6 reported by Rosenfeld et al. (2012) [8] and, in the DECIPHER database (DE-CIPHER, https://decipher.sanger.ac.uk/), another 2 patients (n.257884, n.2498) sharing part of the deleted region with ours.
A comparison of our patient's phenotype with those reported in the literature and in DECIPHER database is shown in Table 1. All the patients were studied by array-CGH. Microcephaly, developmental delay, intellectual disability, and skeletal and ophthalmologic features were common among these patients. Interestingly, our patient also showed some features of Poland syndrome (PS) as the absence of pectoralis major and minor muscles on the right side.
We consider the deleted region (chr6:113,190,061-114,450,408) shared by our case, patient n.6 [8], and the two DECIPHER cases, n.257884 and n.2498 (Figure 2). It contains three genes: MARCKS, HDAC2, and HS3ST5. It is known that MARCKS (myristoylated alanine-rich C kinase substrate) encodes an actin cross-linking protein that plays a role in signal transduction pathways, postnatal survival, cellular migration and adhesion, as well as endo-, exo-, and phagocytosis, and neurosecretion. Moreover, MARCKS is expressed in brain and spinal cord from the early stages of development. It is required during embryogenesis, as revealed by several gene knock-out studies: mice heterozygous for MARCKS appear normal, but exhibit impaired spatial learning while mice lacking the entire MARCKS gene show severe abnormalities of the central nervous system, and all die around birth [16].
The HDAC2 (Histone deacetylase 2) gene encodes a transcription factor that enhances cognitive ability, corrects neurodegenerative impairment, and helps to re-establish long-term memory [17].
HS3ST5 gene encodes a protein that belongs to a group of heparansulfate 3-O-sulfotransferases highly expressed in fetal brain, followed by adult brain and spinal cord [18].
Since these three genes are involved in neural development, we could speculate that their deletion could cause neurological phenotypes like developmental delay, intellectual disability, and brain malformations, all observed in our patient and in the other three similar patients as shown in Table 1.
Moreover, in our patient, the genomic 6q21q22.1 deleted region contained another seven OMIM genes, including FYN, WISP3,and COL10A1. FYN is a non-receptor tyrosine kinase belonging to the Src family kinases. It proved to play important roles in neuronal functions, including myelination and oligodendrocyte formation, and in inflammatory processes [19]. WISP3 encodes a member of the CCN (connective tissue growth factor, Cysteine-rich 61, nephroblastoma overexpressed) family of connective tissue growth factor, known to be mostly extracellular matrixassociated proteins, involved in regulation of cell migration and adhesion, cell proliferation, differentiation, and survival in connective tissues. It is expressed in skeletalderived cells, such as synoviocytes, chondrocytes, and bone marrow-derived mesenchymal progenitor cells, and it is involved in skeletal development and maintenance of cartilage integrity [20]. COL10A1 encodes type X collagen specifically expressed by hypertrophic chondrocytes. As a major component of the hypertrophic zone, type X collagen influences the deposition of other matrix molecules in this region, thereby providing a proper environment for haematopoiesis, mineralization, and modelling, that are essential for endochondral ossification. Mutations and abnormal expression of COL10A1 are closely linked to abnormal chondrocyte hypertrophy, which has been observed in multiple skeletal dysplasia and osteoarthritis [21]. For these reasons, we could speculate that, in our patient, haploinsufficiency of FYN could have contributed to neurological anomalies, and WISP3 and COL10A1 to skeletal defects.
To date, the pathogenic mechanisms underlying PS are still unknown and the genetic origin of the disease is still a matter of debate. It has been hypothesized that PS defects could result from a vascular insult during early embryological stages, which implies that environmental factors could contribute to PS phenotype [22,23].

Conclusions
Interstitial 6q deletion can cause a variable phenotype depending on the size and location of the anomaly. Our paper may contribute to a better understanding of karyotype/phenotype correlation in cases with deletion in 6q21q22.1 and to determine the clinical implication of the genes present in the involved chromosomal region. Identification of additional individuals with overlapping interstitial deletion will help to better define this correlation.

Methods
Standard GTG banding was performed at a resolution of 400-550 bands on metaphase chromosomes from peripheral blood lymphocytes of the patient and his mother; the father refused any analysis. Molecular karyotyping was performed in the patient and his mother using Human Genome CGH Microarray Kit G3 180 (Agilent Technologies, Palo Alto, USA) with~13 Kb overall median probe spacing. Labelling and hybridization were performed following the protocols provided by the manufacturers. A graphical overview was obtained using Agilent Genomic Workbench Lite Edition Software 6.5.0.18.