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. 2013 Apr 3;14:41. doi: 10.1186/1471-2350-14-41

Genomic imbalances in patients with a clinical presentation in the spectrum of Cornelia de Lange syndrome

Cristina Gervasini 1, Chiara Picinelli 2, Jacopo Azzollini 1, Daniela Rusconi 2,6, Maura Masciadri 2, Anna Cereda 3, Cinzia Marzocchi 4, Giuseppe Zampino 5, Angelo Selicorni 3, Romano Tenconi 4, Silvia Russo 2, Lidia Larizza 1,2, Palma Finelli 2,6,7,
PMCID: PMC3626829  PMID: 23551878

Abstract

Background

Cornelia de Lange syndrome (CdLS) is a rare autosomal-dominant disorder characterised by facial dysmorphism, growth and psychomotor developmental delay and skeletal defects. To date, causative mutations in the NIPBL (cohesin regulator) and SMC1A (cohesin structural subunit) genes account for > 50% and 6% of cases, respectively.

Methods

We recruited 50 patients with a CdLS clinical diagnosis or with features that overlap with CdLS, who were negative for mutations at NIPBL and SMC1A at molecular screening. Chromosomal rearrangements accounting for the clinical diagnosis were screened for using array Comparative Genomic Hybridisation (aCGH).

Results

Four patients were shown to carry imbalances considered to be candidates for having pathogenic roles in their clinical phenotypes: patient 1 had a 4.2 Mb de novo deletion at chromosome 20q11.2-q12; patient 2 had a 4.8 Mb deletion at chromosome 1p36.23-36.22; patient 3 carried an unbalanced translocation, t(7;17), with a 14 Mb duplication of chromosome 17q24.2-25.3 and a 769 Kb deletion at chromosome 7p22.3; patient 4 had an 880 Kb duplication of chromosome 19p13.3, for which his mother, who had a mild phenotype, was also shown to be a mosaic.

Conclusions

Notwithstanding the variability in size and gene content of the rearrangements comprising the four different imbalances, they all map to regions containing genes encoding factors involved in cell cycle progression or genome stability. These functional similarities, also exhibited by the known CdLS genes, may explain the phenotypic overlap between the patients included in this study and CdLS. Our findings point to the complexity of the clinical diagnosis of CdLS and confirm the existence of phenocopies, caused by imbalances affecting multiple genomic regions, comprising 8% of patients included in this study, who did not have mutations at NIPBL and SMC1A. Our results suggests that analysis by aCGH should be recommended for CdLS spectrum cases with an unexplained clinical phenotype and included in the flow chart for diagnosis of cases with a clinical evaluation in the CdLS spectrum.

Background

Cornelia de Lange syndrome (CdLS) is a rare, genetically heterogeneous (OMIM #122470, #300590 and #610759), multiple congenital anomaly/intellectual disability disease [1,2], characterised by distinctive facial dysmorphism, pre- and post-natal growth deficiency, psychomotor delay, intellectual disability and malformations of the upper limbs (ranging from small hands to complete limb reduction). CdLS also often involves specific medical complications such as gastroesophageal reflux, hypoacusia and seizures. Its clinical presentation ranges from mild/borderline to severe [3], and this variability has led to the definition of a list of consensus diagnostic criteria integrated into a global scoring system of phenotype severity [4], which are an accepted standard [5-7].

Known CdLS-associated genes encode structural and regulatory proteins of the cohesin pathway, which is involved in chromosome segregation, DNA repair, gene expression and chromosome conformation [8]. The first major gene to be identified was NIPBL, which is located at chromosome 5p13.2, encodes a member of the adherin family [9,10], and mutations in this gene are responsible for > 50% of CdLS patients. All types of NIPBL point mutations have been described, although truncating mutations are generally associated with a more severe phenotype than missense and regulatory mutations [5,9-24]. Microdeletions involving one or more exons of the NIPBL genomic region, and large rearrangements extending to the NIPBL flanking regions, and correlating with severe syndromic presentation, have also been reported [25-27].

Locus heterogeneity in CdLS has been demonstrated by the X-linked form caused by mutation of the SMC1A gene, which encodes a subunit of the cohesin complex [28]. SMC1A alterations contribute up to 6% of all CdLS cases and include only missense mutations or in-frame deletions that preserve the protein reading frame [14,24,28-31]. So far, only one patient has been found to have a mutation in the SMC3 gene, which encodes the other SMC cohesin component, and its epidemiological impact has not yet been defined [29]. Very recently, mutations in the HDAC8 gene, a vertebrate SMC3 deacetylase, have been identified in CdLS probands [32], and mutations in RAD21 gene have been found in six patients with CdLS features [33]. The remaining CdLS cases may be due to as yet undetected mutations in the known genes or by other causative anomalies.

The genomic technology of array Comparative Genomic Hybridisation (aCGH), which monitors losses or gains in chromosome regions that may harbour novel candidate genes, is not yet a standard test for investigation of NIPBL- and SMC1A-mutation-negative CdLS patients [11,18,34,35], but results obtained with the technique to date are consistent with those of > 30 conventional cytogenetic and FISH-targeted studies that have shown chromosomal abnormalities associated with the CdLS phenotype involving almost all of the chromosomes (reviewed [36]). One study has used aCGH to study probands with CdLS-like features, who had been previously screened for mutations in the two major causative genes; however, this was performed in a relatively small patient cohort [35].

This aCGH study of 50 probands including patients fulfilling CdLS diagnostic criteria and those not completely fulfil the criteria [4], and negative for mutations at the NIPBL and SMC1A loci, led to the detection of four carriers of large genomic imbalances that are candidates to explain the clinical phenotype and represent a fraction (8%) of patients with features overlapping those of CdLS. We herein describe how the analysis of the gene content of these imbalances, affecting different genomic regions, links the altered dosage of specific gene classes, shared by all rearrangements, to a common CdLS-like phenotype.

Methods

Patients

CdLS is characterized by a wide phenotypic spectrum; despite some features are quite typical the patients present with a highly variable phenotype ranging from severe to very mild. Out of the fifty probands (26 males and 24 females) investigated in this study diagnosis by our clinical geneticists (AS, RT, GZ) was CdLS for those (60%) fulfilling the international CdLS diagnosis criteria [4] or CdlS-like for the remaining (40%,) not fully satisfying the CdLS criteria. According to the CdLS scoring system [4] the overall phenotype of the patients was severe (~10%) or moderate-mild (~90% with slight prevalence of moderate phenotype). All patients were found negative for NIPBL and SMC1A mutations by DHPLC, direct sequencing and MLPA analyses.

Written informed consent to the research study, which was approved by the Ethical Clinical Research Committee of Istituto Auxologico Italiano, and to the publication of the face photo(s) was obtained from one of the parents.

Array-CGH analysis

The probands were investigated by means of aCGH. Genome scans were performed using the Human Genome CGH Microarray Kit 244 K (Agilent Technologies, Palo Alto, CA), which consists of ~236,000 60-mer oligonucleotide probes covering the entire genome at an average spatial resolution of ~30 kb. The samples were labelled and hybridised following the protocols provided by Agilent, and the arrays were analysed using the Agilent Scanner Control (v 7.0) and Feature Extraction software (v 9.5.1). Graphical overviews were obtained using CGH Analytic software (v4.0.81). Aberration calls were identified using the ADM-2 algorithm.

An in silico analysis of the unbalanced regions indicated by aCGH was performed using the March, 2006, release of the UCSC Genome Browser (http://genome.ucsc.edu/) and the Database of Genomic Variants (http://projects.tcag.ca/variation).

FISH

Chromosome preparations were obtained by standard cytogenetic techniques using peripheral blood lymphocytes cultured by 72 h. BAC probes were selected on the basis of their physical location (http://www.genome.ucsc.edu/ release March, 2006), and provided by Invitrogen Ltd., UK. Their physical positions were verified on control metaphase chromosomes derived from peripheral blood lymphocytes. FISH experiments were performed using standard procedures [37].

Results

The 50 probands negative for NIPBL and SMC1A mutations were considered an ideal cohort to scan for the presence of genomic gains/losses by aCGH, in the search for novel genes responsible for phenotypes with features that overlap CdLS.

We identified four probands with large or de novo copy number variants (CNVs) (Table 1), whose clinical data at birth and at age of evaluation are summarised in Table 2 (see also Additional file 1: Table S1 for auxological parameters). The four probands display a high degree of phenotypic heterogeneity, but all share the minimal diagnostic CdLS clinical features. Three of them (Probands 1, 2 and 3) fulfil the diagnostic CdLS criteria, whereas the fourth (Proband 4) does not fulfil completely the criteria having synophrys and only two (and not three) other facies criteria (Additional file 2: Table S2).

Table 1.

Chromosomal position and boundaries of large rearrangements identified by aCGH in four CdLS probands negative for mutations in NIPBL and SMC1A

Pt Rearrangement Size Boundaries (bp)* Origin
1
 del(20)(q11.2q12)
 4.2 Mb (min 4.259-max 4.313)
 chr20:33228486-37488426
 de novo**
2
 del(1)(p36.23p36.22)
 4.8 Mb (min 4.889-max 4.914)
 chr1:7161146-12049775
 de novo**
3
 der(7)t(7;17)(p22.3;q24.2)
 769 Kb del(7)(p22.3) (min 769-max 916)
 chr7:140213-909190
 t(7;17)(p22.3;q24.2)pat
 
  
 14 Mb dup(17)(q24.2q25.3) (min 14.744-max 14.763)
 chr17:63665720-78409550
4 dup(19)(p13.3) 880 Kb (min 880–891) chr19:662118-1541750 mother: mos dup(19)(p13.3)***
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*UCSC Genome Browser assembly Mar.2006 (NCBI36/hg18).

**Paternity confirmed by inheritance of benign CNVs.

***Mosaic condition.

Table 2.

Spectrum of clinical features in CdLS probands carrying imbalances compared to those of classic CdLS probands

Clinical features CdLS 1 2 3* 4** 4**
 
  
 del(20)(q11.2q12)
 del(1)(p36.23p36.22)
 der(7)t(7;17)(p22.3;q24.2)
 dup(19)(p13.3)
 mos dup(19)(p13.3)
Pre-/post-natal growth retardation
 IUGR; PNGR
 IUGR; PNGR
 IUGR; PNGR
 PNGR; swallowing difficulties
 IUGR
 NA
Neurological involvement
 Psychomotor/cognitive impairment; hypertonicity/ hypotonia; seizures (25%)
 Psychomotor retardation; hypertonicity
 Severe psychomotor and intellectual disability.; hyperactivity
 Psychomotor and intellectual disability
 Hyperactivity; mild intellectual disability; emotional problems
 Dyslexia; bulimia
Craniofacial appearance
 microbrachycephaly
 plagiocephaly
 Microcephaly; temporal narrowing
 microbrachycephaly
  
  
Face
 Long and prominent philtrum; micrognathia (80%)
 Normal
 Long philtrum; micrognathia
 Long face; long and prominent philtrum
 Long philtrum
 Long hypoplastic philtrum
Eyes Eyelashes Eyebrows
 Myopia; long curly eyelashes; synophrys; arched eyebrows
 Myopic astigmatism; long eyelashes; synophrys
 Long eyelashes; synophrys
 Long eyelashes; synophrys; large eyebrows
 Synophrys
 Synophrys
Nose
 Depressed/broad nasal bridge; upturned nasal tip; anteverted nares
 Columella below alae nasi
 Large nasal tip; anteverted nares
 Depressed nasal bridge; large columella
 NA
 NA
Mouth
 Thin upper lip; downturned corners of the mouth; high and arched palate; cleft lip/palate
 Thin upper lip; downturned corners of the mouth; arched palate
 Large mouth; thin upper lip
 Thin upper lip; high palate; downturned corners of the mouth
 Thin upper lip
 Thin upper lip
Ears
 Low-set posteriorly rotated and/or hirsute ears; thickened helices
 Bilateral hypoplastic helix
 NA
 Low-set ears
 Ear lobe creases
 Ear lobe creases
Hair
 Hirsutism (>80%); low posterior hairline
 Frontotemporal hypertrichosis and truncal hirsutism
 Slight hirsutism
 Hirsutism
 NA
 NA
Skeleton
 Ranging from severe reduction defects to milder defects such as micromelia, proximally placed thumbs fifth finger clinodactyly, limited elbow extension, syndactyly of the toes, and occasional orthopedic complications (scoliosis)
 Normal
 Proximally placed thumb; small hands; slight toenail dysplasia
 Post-axial polydactyly of left hand and foot#
 Clynodactyly of 5th finger
 NA
Cardiovascular
 Cardiac defects (ASD/VSD, …)
 Secundum small atrial septal defect
 Mitral valve prolapse
 Normal
 Normal
 NA
Gastrointestinal
 Gastroesophageal reflux (30-80%); congenital diaphragmatic hernia (1%)
 Feeding problems in the first year of life
 Gastroesophageal reflux
 Feeding problems in the first years of life
 Normal
 NA
Breast
 Small nipples
 Normal
 NA
 Normal
 Polythelia
 NA
Other
  
 Thenar and hypothenar hypoplasia; bilateral inguinal hernia; hyperactivity
 NA
 Cryptorchidism
 Scoliosis; cryptorchidism
 Monolateral hypoplastic kidney
Age at evaluation   9 years 10 months 12 years 12 years 6 months 10 years NA
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ASD/VSD: atrial septal defect/ventricular septal defect.

IUGR: intra-uterine growth retardation.

NA not assessed.

OFC Occipitofrontal Circumference.

PNGR: post-natal growth retardation.

# not inherited.

* Balanced translocation inherited from healthy father.

** Familial case (4′: mother of proband 4).

Proband 1

The first proband was a 9-year-old girl who showed both intra-uterine (IUGR) and post-natal growth retardation (PNGR) (Table 2 and Additional file 1: Table S1).

Post-natal growth was poor and psychomotor development retarded due to feeding problems (sucking and swallowing difficulties), and surgical correction of a bilateral inguinal hernia was performed at 3 months of age. At the age of 3.5 months, she developed behavioural disorders including hyperactivity, frequent outbursts/temper tantrums and self-injurious behaviour, with self-hitting and self-biting.

When she was 6 years old, a clinical examination revealed generalised hirsutism and dysmorphic features, such as synophrys, long and downward-slanting palpebral fissures, epicanthic folds, long and curved eyelashes, malar hypoplasia, hypoplastic nasal bone, the columella below the alae nasi, a thin upper lip and downturned corners of the mouth and a high-arched palate (Figure 1a). She also had slight limb involvement with bilateral thenar and hypothenar hypoplasia. At the age of 9 years and 10 months, she had developed brachycephaly and her dysmorphic facial features were unchanged. Heart sonography revealed a secundum small atrial septal defect. She no longer presented gastrointestinal problems except for mild rectal bleeding due to multiple juvenile polyps (> 15) throughout the colon.

Figure 1.

Figure 1

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Facial appearance, genomic imbalances and genes with altered copy number in probands. (a, d, g, j) The facial appearance of patients 1 (age 6 years), 2 (age 15 years), 3 (age 22 years) and 4 (age 9 years). (b, e, h, k) aCGH profiles. (Left) Ideogram of the chromosome(s) involved in the imbalances with the log2 probe ratio plotted as a function of chromosomal position; h) profile of patient 4 (left) and his mother (right). (c, f, i, m) The gene content of each genomic imbalance. Magnification of the deleted/duplicated region indicating the distal and proximal breakpoint positions (horizontal dotted lines) and a selection of gene content. Blue colour indicates genes cited in the main text. The red bar in m) corresponds to the CTD-3009K5 BAC clone used in the FISH analysis (not to scale). l) FISH analysis using the CTD-3009K5 BAC clone mapping to chromosome 19p13.3 shows a duplicated signal in all cells of proband 4 (left) and in approximately 76% of the nuclei in a maternal sample, confirming the presence of the rearrangement in a mosaic state (right). White arrows indicate nuclei with a duplicated signal.

The aCGH analysis showed a large, 4.2 Mb, de novo deletion of chromosome 20q11.2-q12 (Table 1, Figure 1b) that was not found in her healthy parents (not shown). More than 50 genes are localised to the deleted region (Figure 1c).

Proband 2

Proband 2 was a 22-year-old woman who had been affected by both IUGR and PNGR (Table 2 and Additional file 1: Table S1). Clinical evaluation revealed slight hirsutism and dysmorphic features, including microcephaly with temporal narrowing, synophrys, long eyelashes, a large nasal tip, anteverted nares, a long philtrum, a large mouth, a thin upper lip and micrognathia (Figure 1d). Limb involvement was mild, marked by small hands, a proximally placed thumb and slight toenail dysplasia. The patient suffered from gastroesophageal reflux, and mitral valve prolapse.

Neurological assessment showed severe psychomotor and intellectual disability, with some behavioural disorders such as hyperactivity.

The aCGH analysis revealed the presence of a ~4.8 Mb interstitial deletion of chromosome 1p36.23-36.22 1 (Table 1, Figure 1e). Her healthy parents have a normal molecular karyotype (not shown), indicating the de novo origin of the rearrangement. The large deleted region includes > 50 genes and does not overlap with the 1p36 syndrome regions (Figure 1f).

Proband 3

In the first years of life, proband 3, a 22-year-old man, suffered from cryptorchidism and feeding problems with swallowing difficulties, as well as post-natal growth delay and cognitive impairment, with both psychomotor and intellectual disability (Table 2 and Additional file 1: Table S1).

His current phenotype is characterised by hirsutism and facial features consisting of microbrachycephaly, a long face, low-set ears, synophrys, thick eyebrows, long eyelashes, a depressed nasal bridge, a large columella, a long and prominent philtrum, a thin upper lip, a high palate and downturned corners of the mouth (Figure 1g). Limb involvement includes post-axial polydactily of the left hand and foot.

The proband is a carrier of an unbalanced 46,XY translocation der(7)t(7;17)(p22.3;q24.2), inherited from his father, who carries a t(7;17)(p22.3;q24.2) balanced translocation. The aCGH analysis performed to characterise the double segmental imbalances revealed a 14 Mb duplication at chromosome 17q24.2-25.3 and a 769 kb deletion of 7p22.3 (Table 1, Figure 1h). Both affected genomic intervals include a number of genes (Figure 1i).

Proband 4

This 10-year-old boy, who had presented prenatally with IUGR, was found at clinical evaluation to have dysmorphic facial features including synophrys, a long philtrum, a thin upper lip and ear lobe creases (Figure 1l), along with musculoskeletal anomalies (clynodactyly of the fifth finger and scoliosis); other features were polythelia and cryptorchidism (Table 2 and Additional file 1: Table S1). He also had psychological and cognitive disorders, including hyperactivity, emotional problems and mild intellectual disability. The mother of the proband had similar facial features (synophrys, a long hypoplastic philtrum, a thin upper lip and ear lobe creases), and a monolateral hypoplasic kidney. She has different neurocognitive and psychological disorders, characterised by dyslexia and bulimia.

The aCGH analyses of the proband and his parents revealed an 880 Kb chromosome 19p13.3 duplication in the son and mother who, on the basis of the signals ratio, appeared to be a mosaic (Table 1, Figure 1m).

To estimate the mosaicism rate with a cell-to-cell-based technique, an interphase FISH experiment was carried out on the mother’s nuclei using the CTD-3009K5 BAC clone, which maps within the duplicated region (Figure 1m). Hybridisation signals were scored on 100 nuclei each from mother and son. A signal of either duplicated or increased intensity was identified in all of the son’s cells, whereas in the sample from the mother, cells containing nuclei with this abnormal pattern were prevalent (76%), but the remaining fraction showed a normal hybridisation pattern, confirming the presence of mosaicism for the mutation (Figure 1n).

Forty-three RefSeq genes are located in the duplicated interval (Figure 1o).

Discussion

CdLS is a genetically heterogeneous disorder, with only 50–60% of clinically diagnosed probands shown to have mutations in one of the known cohesin-associated genes NIPBL, SMC1A, SMC3, HDAC8 or RAD21. This partial knowledge of the molecular basis of CdLS parallels the wide clinical spectrum, which ranges from extremely mild to severe and includes “borderline” cases, which are often at the interface with other syndromic conditions caused by defects in interconnected cohesion pathways [33]. The genes for cohesin structural subunits and regulators perform crucial roles in the maintenance of genome stability through surveillance of chromatid cohesion throughout the cell cycle, double-strand DNA break repair and long-range regulation of transcription (see [38] for a review). While transcriptional activation and regulation occurs only in cycling and postmitotic cells, the more ancient roles of cohesion in adhesion of sister chromatids and DNA repair are performed throughout the cell cycle (see [39] for a review). Filtering atypical/borderline cases from the overall set of patients with a presumptive or possible CdLS clinical diagnosis is a major challenge. The technology used in this study (aCGH) can identify genomic regions implicated in CdLS and overlapping phenotypes by identifying CNVs that may harbour genes encoding the large number of proteins that may interact with those of the cohesin pathway. Here, we describe four probands with a CdLS-like phenotype and without evidence of mutations in NIPBL and SMC1A. The aCGH analyses detected unbalanced rearrangements of various sizes and involving chromosomal regions that have not previously been associated with the Cornelia de Lange phenotypic spectrum.

The four imbalances detected were: i) a de novo deletion at chromosome 20q11.2-q12 (4.2 Mb); ii) a de novo 1p36.23-36.22 deletion (4.8 Mb); iii) a der(7)t(7;17)(p22.3;q24.2) with a 14 Mb duplication in 17q24.2-25.3 and a 769 Kb deletion in 7p22.3; and iv) a familial 880 Kb duplication in 19p13.3, apparently de novo in the mother, who presented with a mosaic state and transmitted the duplication to the affected child.

A number of patients carrying pathogenic deletions or duplications partially overlapping those of our cases have been deposited in DECIPHER or ISCA databases. However, the paucity of the accessory clinical data does not permit conclusive comparisons for genotype phenotype correlations.

To the best of our knowledge, only the chromosome 20q imbalance has previously been described in three patients not classified as having CdLS (although they have some features in common with CdLS) who carry a pure 20q deletion that completely or partially overlaps that identified in our proband 1 (Additional file 3: Figure S1 and Additional file 4: Table S3) [40-42]. No patients have been reported in the literature sharing imbalances in the same regions as the other probands. Four patients have been described bearing a terminal or interstitial deletion of 1p36, with proximal breakpoints falling within the region deleted in our proband 2 (patients A, B, and F in [43], and patient D1P3 in [44]), with whom they share a very small part of the deleted region, consistent with the lack of a common clinical picture. Five patients with a duplicated 19p13.3 region have been described, but all carry a deletion of a different genomic region, thus making them not directly comparable to our proband 4 [45-49].

A large number of the genes located in the regions involved in the imbalances identified in this study have been associated with clinical conditions, making it likely that the phenotypes of our probands are the result of contiguous gene syndromes that mimic the multifaceted CdLS syndrome. Our four probands display a high degree of phenotypic heterogeneity, but all share the minimal diagnostic CdLS clinical features including pre- and post-natal growth retardation (Additional file 1: Table S1), mild to severe psychomotor and cognitive impairment and a cranio-facial appearance (Figure 1) characterised by microcephaly or plagiocephaly, long eyelashes, synophrys, thin upper lip and downturned corners of the mouth, long and prominent philtrum, and hirsutism (Table 2).

It is interesting to note that all of the genomic regions involved in the imbalances described here harbour some dosage-altered genes whose functions are directly or indirectly related to those of the known CdLS genes (NIPBL, SMC1A, SMC3) (Figure 1). The genes of interest (CEP250, DSN1, MAD2L2, APITD1/CENP-S, RECQL5, ANAPC11, MED16, MBD3) encode proteins involved in controlling cell cycle progression, including components of the centrosome, the kinetochore, the mitotic spindle assembly checkpoint, the anaphase-promoting complex, and proteins involved in the methylation and unwinding of DNA (Table 3) [50-63].

Table 3.

Potential functionally relevant genes residing in regions showing imbalances in patients with CdLS-like phenotypes

Pt Gene Name Function Biological process Ref Position* Gene alteration
1
 CEP250
 Centrosomal protein 250kDa
 Core centrosomal protein required for centriole-centriole cohesion during the interphase of the cell cycle.
 Cell cycle progression (centriole-centriole cohesion) ; transcritpion regulation
 50
 chr20:33506637-33563217
 Loss
 
 DSN1
 MIND kinetochore complex component, homologue (S. cerevisiae)
 Kinetochore protein that functions as part of the minichromosome instability-12 centromere complex, required for proper kinetochore assembly and progression through the cell cycle.
 Cell cycle progression (kinetochore assembly)
 51,52
 chr20:34813608-34835644
 Loss
2
 MAD2L2
 MAD2 mitotic arrest deficient-like 2 (yeast)
 Component of the mitotic spindle assembly checkpoint that prevents the onset of anaphase until all chromosomes are properly aligned at the metaphase plate.
 Cell cycle progression; DNA repair
 53
 chr1:11657124-11674265
 Loss
 
 APITD1/CENPnS
 Apoptosis-inducing, TAF9-like domain 1
 Component of multiple complexes, including the Fanconi anemia (FA) core complex, the APITD1/CENPS complex, and the CENPA-CAD (nucleosome distal) complex. Known role in the stable assembly of the outer kinetochore.
 Mitotic cell cycle progression; DNA repair; DNA-dependent transcription initiation
 54
 chr1:10412746-10425459
 Loss
3
 RECQL5
 RecQ protein-like 5
 Member of DNA-helicase with a specific role being coupled to RNAPII transcription and DNA recombination.
 DNA helicase activity (DNA repair, transcription regulation)
 55,56, 57
 chr17:71134545-71174860
 Gain
 
 ANAPC11
 Anaphase-promoting complex subunit 11
 Component of the anaphase.promoting complex/cyclosome (APC/C), a cell cycle-regulated E3 ubiquitin ligase that controls progression through mitosis and the G1 phase of the cell cycle.
 Mitotic cellcycle progression
 58,59,60
 chr17:77442895-77451655
 Gain
4
 MED16
 Mediator complex subunit 16
 Component of the Mediator complex, a coactivator involved in the regulated transcription of nearly all RNA polymerase II-dependent genes
 Transcription regulation
 61
 chr19:867,962-893,218
 Gain
  MBD3 Methyl-CpG binding domain protein 3 Subunit of the NuRD, a multisubunit complex containing nucleosome remodelling and histone deacetylase activities. It acts as a transcriptional repressor and plays a role in gene silencing Histone acetylation (transcription regulation, cell cycle progression) 62, 63 chr19:1527678-1543652 Interrupted
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*UCSC Genome Browser assembly Mar.2006 (NCBI36/hg18).

In addition to the presence of genes whose products functionally overlap with those of known CdLS genes, further findings supporting the hypothesis that our probands are phenocopies of CdLS include: i) the localisation of the CEP170 gene which encodes a component of the centrosome [64], within a region (chromosome 1q44) shown to be deleted in a CdLS proband by Borck et al. [11]; ii) the localisation of the TNKS gene, involved in sister chromatid cohesion, within the chromosome 8p23.1 region in the CdLS proband reported by Baynam et al. [65].

Moreover, genes with similar functions (RECQL4, BUB1B, BUB3, CENPA, CENPL, SMARCA4, SMARCC1 and ATRX) have also been found to be dysregulated in expression studies of CdLS patients with mutations in NIPBL[66].

Conclusions

We found that a considerable fraction (8%) of the NIPBL and SMC1A mutation-negative probands with features overlapping with CdLS included in this study were carriers of chromosomal imbalances that may underlie their phenotypes.

The four probands had different chromosomal imbalances, but all involved a number of genes related to progression through the cell cycle and the safeguarding of chromosomal stability (Table 3). Given the similar functions of delangin and the proteins of the cohesin network, we hypothesise that an imbalance of these genes, which probably act in concert with other functionally related genes, contributes to the observed CdLS-like phenotypes.

Our data raise the issue of the complex clinical diagnosis of a syndrome such as CdLS which, through the multifunctional proteins encoded by its known causative genes, has an impact on a myriad of interconnected pathways. It is therefore not surprising that the clinical diagnosis of a CdLS-like phenotype often includes cases of carriers of chromosomal imbalances affecting multiple genomic regions.

Competing interests

The authors declare they have no competing interests.

Author’s contributions

CG, LL and PF conceived and designed the study and wrote the manuscript. CP and DR performed the aCGH work and the FISH experiments. CG, JA, MM and SR performed the mutation screening of NIPBL and SMC1A. CG, CP, JA and PF contributed to interpretation of the aCGH results. AS, GZ, RT, AC and CM recruited the patients and reviewed the clinical data. All of the authors approved the final version of the manuscript.

Pre-publication history

The pre-publication history for this paper can be accessed here:

http://www.biomedcentral.com/1471-2350/14/41/prepub

Supplementary Material

Additional file 1: Table S1

Auxological parameters (at birth and at age of evaluation) of probands 1–4 compared with those characteristic of CdLS patients.

Click here for file (29KB, xls)
Additional file 2: Table S2

CdLS diagnostic criteria applied to the described patients.

Click here for file (10.2KB, xlsx)
Additional file 3: Figure S1

20q11.2q12 map showing region involved in our patient 1 rearrangement compared to molecularly characterized 20q deletions reported in the literature.

Click here for file (34.6KB, pdf)
Additional file 4: Table S3

Clinical signs of proband 1 compared with those characteristic of CdLS patients and patients carrying an overlapping 20q deletion.

Click here for file (35KB, xls)

Contributor Information

Cristina Gervasini, Email: cristina.gervasini@unimi.it.

Chiara Picinelli, Email: chiara.picinelli@libero.it.

Jacopo Azzollini, Email: jacopo.wdl@gmail.com.

Daniela Rusconi, Email: d.rusconi@auxologico.it.

Maura Masciadri, Email: maura.masciadri@alice.it.

Anna Cereda, Email: anna21cereda@gmail.com.

Cinzia Marzocchi, Email: cinziaxyz@libero.it.

Giuseppe Zampino, Email: gzampino@alice.it.

Angelo Selicorni, Email: angelo.selicorni@gmail.com.

Romano Tenconi, Email: romano.tenconi@unipd.it.

Silvia Russo, Email: s.russo@auxologico.it.

Lidia Larizza, Email: lidia.larizza@unimi.it.

Palma Finelli, Email: palma.finelli@unimi.it.

Acknowledgements

We would like to thank the patients families for participating in this study, and the clinicians who provided some of the patients negative for known causative mutations.

This study was supported by a Ministry of Health “Ricerca Corrente” grant to Istituto Auxologico Italiano IRCCS (08C001-2010) and by a “Accordo quadro Università-Regione Lombardia n° 17292” grant to LL and PF.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Additional file 1: Table S1

Auxological parameters (at birth and at age of evaluation) of probands 1–4 compared with those characteristic of CdLS patients.

Click here for file (29KB, xls)
Additional file 2: Table S2

CdLS diagnostic criteria applied to the described patients.

Click here for file (10.2KB, xlsx)
Additional file 3: Figure S1

20q11.2q12 map showing region involved in our patient 1 rearrangement compared to molecularly characterized 20q deletions reported in the literature.

Click here for file (34.6KB, pdf)
Additional file 4: Table S3

Clinical signs of proband 1 compared with those characteristic of CdLS patients and patients carrying an overlapping 20q deletion.

Click here for file (35KB, xls)

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