Recurrent deletions of 2q32q33 have recently been reported as a new microdeletion syndrome. Clinical features of this syndrome include severe mental retardation, growth retardation, dysmorphic features, thin and sparse hair, feeding difficulties and cleft or high palate. The commonly deleted region contains at least seven genes. Haploinsufficiency of one of these genes, SATB2, a DNA-binding protein that regulates gene expression, has been implicated as causative in the cleft or high palate of individuals with 2q32q33 microdeletion syndrome. In this study we describe three individuals with smaller microdeletions of this region, within 2q33.1. The deletions ranged in size from 173.1 kb to 185.2 kb and spanned part of SATB2. Review of clinical records showed similar clinical features among these individuals, including severe developmental delay and tooth abnormalities. Two of the individuals had behavioral problems. Only one of the subjects presented here had a cleft palate, suggesting reduced penetrance for this feature. Our results suggest that deletion of SATB2 is responsible for several of the clinical features associated with 2q32q33 microdeletion syndrome.
Citation: Rosenfeld JA, Ballif BC, Lucas A, Spence EJ, Powell C, Aylsworth AS, et al. (2009) Small Deletions of SATB2 Cause Some of the Clinical Features of the 2q33.1 Microdeletion Syndrome. PLoS ONE 4(8): e6568. doi:10.1371/journal.pone.0006568
Editor: Alexander Idnurm, University of Missouri-Kansas City, United States of America
Received: February 26, 2009; Accepted: April 23, 2009; Published: August 10, 2009
Copyright: © 2009 Rosenfeld et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was performed at Signature Genomic Laboratories, LLC. Senior author Dr. Lisa G. Shaffer, Ph.D. is President and CEO of Signature and assisted in study design, data analysis, decision to publish and preparation of the manuscript.
Competing interests: L.G. Shaffer sits on the Members' Board of, owns shares in, and is an employee of Signature Genomic Laboratories, LLC. J.A. Rosenfeld, B.C. Ballif and B.A. Torchia are employees of Signature Genomic Laboratories, LLC.
Special AT-rich sequence binding protein 2 (SATB2; OMIM 608148) is a DNA-binding protein that regulates gene expression through chromatin modification and interaction with other proteins and plays roles in mammalian development –. In humans haploinsufficiency has been implicated in isolated cleft palate (CPI, OMIM 119540) , . A single case of a de novo nonsense mutation of SATB2 has been described in an individual with cleft palate, osteoporosis, profound mental retardation, epilepsy, a jovial personality, and craniofacial dysmorphism including gum hyperplasia, mandibular hypoplasia, and anterior-pointing incisors . Three individuals with apparently balanced translocations with a breakpoint within SATB2 or in a highly conserved region 3′ of the gene have also been reported , . Two of these individuals had cleft palate, mild learning disabilities with speech delay and strikingly similar dysmorphic features with a prominent nasal bridge, underhanging columella, and a small mouth with a distinctive upper lip . The third individual was diagnosed with Toriello-Carey syndrome because of the presence of Robin sequence, agenesis of the corpus callosum, dysmorphic features, and global developmental delay . A fourth case of a balanced translocation predicted to disrupt the SATB2 gene has been reported in an individual with autism spectrum disorder and developmental dyspraxia . Mouse studies have shown a role for Satb2 beyond the palatal shelves, with roles in B-cell differentiation , osteoblast differentiation , establishment of neural corticocortical connections across the corpus callosum , and in the developing jaw and incisors , . Because SATB2 is highly conserved between species (99.6% between humans and mice), a deletion of this gene in humans is predicted to affect multiple systems.
Recently, Van Buggenhout et al.  used a 1-Mb bacterial artificial chromosome (BAC) microarray and characterized deletions of 2q32.2q33.3 in four individuals with severe mental retardation and growth retardation, facial dysmorphism, thin and sparse hair, micrognathia, cleft or high palate, persistent feeding difficulties, inguinal hernia, and broad-based gait. Three of these individuals had a distinctive behavioral phenotype with hyperactivity, motor restlessness, chaotic behavior, and happy personality with periods of aggression and anxiety. The authors suggested that, based on the common clinical features in these individuals and several previously reported individuals with cytogenetically visible deletions of 2q32q33 –, microdeletions of 2q32q33 constitute a distinct syndrome (OMIM 612313). An additional case of this microdeletion has been reported in a male patient with a similar phenotype, including severe mental retardation, growth retardation, dysmorphic features, high palate, hyperactive and aggressive behavior, and hypotonia in infancy that changed to hypertonia . Deletion of SATB2 has been suggested to be responsible for the cleft or high palates in these individuals .
We report the clinical and molecular characterization of three individuals with microdeletions within 2q33.1 spanning part of the SATB2 gene. From our review of the published literature these appear to be the smallest deletions associated with the 2q32q33 microdeletion syndrome reported to date and suggest haploinsufficiency of SATB2 may be responsible for some of the clinical features associated with the syndrome.
We identified three individuals with microdeletion of 2q33.1 among our patient population. We characterized the deletions in more detail using a high-density 105K oligonucleotide microarray. Microarray analysis identified single-copy losses of the region containing SATB2 in each of the individuals (Figure 1). A 183.6 kb deletion spanning all but the 5′ end of the SATB2 gene at 2q33.1 (chr2:199,837,205–200,020,800) was found in subject 1; a 173.1 kb deletion at 2q33.1 within the SATB2 gene (chr2:199,860,227–200,033,309) was found in subject 2; and a 185.2 kb deletion at 2q33.1 encompassing all but the 3′ end of SATB2 (chr2:199,860,027–200,045,201) was found in subject 3. The only gene contained in each of the three deletions was SATB2. No other clinically significant gains or losses were detected in these individuals. A search of the Database of Genomic Variants (projects.tcag.ca/variation/) showed seven normal individuals have been reported with small deletions in SATB2; however, each of the deletions was entirely within an intron of the gene.
(A–D) Oligonucleotide microarray profiles for (A) normal chromosome 2, (B) a single-copy loss of 183.6 kb at 2q33.1 in subject 1, (C) a single-copy loss 173.1 kb at 2q33.1 in subject 2, and (D) a single-copy loss of 185.2 kb at 2q33.1 in subject 3. For the microarray plots, clones are ordered on the x axis according to physical mapping positions with proximal 2q33.1 to the left and distal 2q33.1 to the right. (E) Summary of the deletion sizes in individuals with microdeletions encompassing 2q33.1. Green bars indicate the approximate deletion sizes in individuals in the Van Buggenhout et al.  study (upper portion of diagram) and the current study (bottom of diagram). The SATB2 gene is indicated by a red box.
FISH using BAC probe RP11-404F23 to the SATB2 locus confirmed a deletion in all subjects. Parental specimens were available only for the mothers of subjects 1 and 2, and neither mother carried the deletion of 2q33.1. Biological parents of subject 3 were unavailable for testing.
Clinical information was available for subjects 1–3 (Table 1). Subject 1 is a 9-year 8-month old female with severe mental retardation, dysmorphic features, and behavior problems. Family history was negative for any individuals with similar developmental delays. The subject was born to a 30-year-old mother via a somewhat difficult vaginal delivery following a pregnancy complicated by gestational diabetes. Fetal activity was normal. Exposures were denied. There was perinatal distress with difficulty in delivering the head. Labor was induced. Birth weight was 8 pounds 9 ounces. She had a fractured clavicle and some transient tachypnea and was discharged home at 7 days. Developmental delays were noted in early childhood, and intelligence testing placed her IQ below 50. She had delayed primary dentition, with eruption of her first tooth at age 2. At age 9 years 8 months she has 20 words, four to five signs, and one two-word phrase. Head MRI at age 2 was normal, and head CT at age 7 was also unremarkable. She has a heart murmur with no known further workup. Dysmorphic features include frontal bossing, a long and narrow face with a prominent maxillary arch, a class II malocclusion with relative micrognathia, slightly large ears, a smooth upper lip, and a smooth philtrum (Figure 2A–B). The subject was uncooperative with direct examination of her palate, but her history is not consistent with any palatal clefting. At age 9 years 8 months height is at the 25th–50th percentile, weight is at the 50th–75th percentile, and head circumference is at the 75th percentile. She has normal dentition. The subject is very social, repeats actions multiple times, frequently washes her hands, likes to have her hair washed, has touch avoidance, has good eye contact, is somewhat photophobic, and has nodules on the dorsal surfaces of her fifth fingers bilaterally consistent with the effects of chewing on her hands.
(A) Facial image of subject 1 at age 2 years, 9 months. (B) Facial image of subject 1 at age 9 years, 8 months. Subject is in mixed dentition and is missing her maxillary central incisors. (C) Front and (D) profile facial images of subject 2 at age 10 years. Note the broad nasal midsection, small mandible, and macrocephaly.
Subject 2 is a 21-year-old male with severe mental retardation, dysmorphic features, cleft palate, and behavior problems. The subject was born to an 18-year-old G3P0→1020 mother at term via spontaneous vaginal vertex delivery following a pregnancy complicated by maternal smoking (1/2 pack per day), maternal x-rays following a car accident, and bleeding at 6 months, followed by bed rest. Birth weight was at the 50th percentile. The subject had a cleft palate, which was repaired before 1 year of age. He had feeding difficulties as an infant with frequent vomiting. Developmentally, he smiled at 1 month, rolled over at 4 months, and walked alone at 2–3 years. At age 21 he does not put words together and is not toilet trained. Formal evaluation at 10 years of age put his development at 18–24 months. Dysmorphic features include a broad nasal midsection, short tongue, short oropharynx with poor movement, small mandible with crowded teeth, small testes, slightly broad thumbs and first toes, prominent heels, and macrocephaly. Figures 2C and D show subject 2's facial features at age 10. At age 21 height is at the 10th percentile, weight is at the 5th–10th percentile, and head circumference is greater than the 98th percentile (59 cm). Neurological examination revealed increased tone, normal strength, and deep tendon reflexes measuring 3+. The subject has a happy demeanor, although he has a history of aggression at times and will pick his skin. Food is locked up because of overeating and vomiting, and he will eat non-food items. He also has a high tolerance for pain.
Subject 2's family history is significant for a full brother with speech delays as a child, but he is not having any problems at age 20. A paternal half-sister has a cleft lip/palate and mental retardation. The subject's father is of normal intellect. There is also a paternal first cousin who was born with a cleft palate and an unspecified ear anomaly that required plastic surgery. Two maternal half-sisters are developmentally normal. Learning disabilities were present in a maternal uncle and a maternal first cousin. Ancestry is African-American, and consanguinity was denied.
Subject 3 is a 6-year-old female with severe mental retardation. She is of Guatemalan ancestry, and no family history information is available. Developmental delays were noted at 6 months of age. At 4.5 years, developmental assessment placed her at an 18-month level. Intelligence testing showed an IQ of 32. On the Vineland Adaptive Behavior Scale, she had a standard score for adaptive behavior of 56 with strength in socialization skills and a standard score of 66 with other scores clustering in the mid 50s. She does not have any speech, but she does have some signs. The only dysmorphic features present are borderline microcephaly with some brachycephaly and fused mandibular central incisors. She does not have a cleft palate. At age 6 height is at the 75th percentile, weight is at the 50th–75th percentile, and head circumference is at the 2nd percentile (48 cm). The only troublesome behavior noted by her parents was her inability to sleep through the night until she was 5 years old.
We report the characterization of three individuals with microdeletions of 2q33.1. The microdeletions range in size from 173.1 kb to 185.3 kb, and each spans part of SATB2. To our knowledge, these are the smallest deletions associated with the 2q32q33 microdeletion syndrome; the minimal deletion region in the four individuals reported by Van Buggenhout et al.  was 8.1 Mb. The three individuals in the present study had clinical features characteristic of 2q33.1 microdeletion syndrome, including severe developmental delay with little to no speech and tooth abnormalities (Table 1). Two of the subjects also have unusual behavior.
All three individuals in our study had dentofacial abnormalities. Subjects 1 and 2 had micrognathia or a small mandible, likely contributing to the crowding of the teeth. Several of the individuals previously reported with cytogenetically visible deletions of 2q32q33 have had dental abnormalities, including missing teeth, abnormally shaped teeth, malocclusion, and diastema , , , , , . The role of SATB2 in tooth and jaw development is supported by the identification of a de novo SATB2 mutation in a male with profound mental retardation and jaw and tooth abnormalities  and a translocation interrupting SATB2 in an individual with Robin sequence . In addition, mouse models have demonstrated haploinsufficiency of Satb2 results in craniofacial defects that phenocopy those caused by 2q32q33 deletion in humans; moreover, full functional loss of Satb2 amplifies these defects. Satb2+/− mice have small mouths, premaxillary and nasocapsular hypoplasia, micrognathia, and variable incisor agenesis. Satb2−/− mice have fully penetrant incisor adontia. Loss of Satb2 correlates with increased cell death in the developing jaw along with altered expression of other craniofacial developmental genes . The individuals reported by Van Buggenhout et al.  also presented with thin and sparse hair and thin and transparent skin, and two had nail abnormalities. This combination of features is suggestive of an ectodermal dysplasia, although the individuals in the present study did not have any of these other ectodermal-related features. The detection of a deletion of 2q31.2q32.3 that did not encompass SATB2 in an individual with abnormal teeth and thin skin suggests other genes in the region may impact ectodermal development . Thus, SATB2 haploinsufficiency likely contributes to the tooth abnormalities in the 2q32q33 microdeletion subjects, but deletion of other genes may be necessary for the full ectodermal phenotype.
Although haploinsufficiency of SATB2 has been suggested to cause isolated cleft palate in humans, within our cohort SATB2 deletions show reduced penetrance for cleft palate (Table 1). Subject 2 is the only individual in this study with a cleft palate, and his family history was significant for clefting, suggesting there could be other genetic factors contributing to the clefting. These relatives were not available for testing to determine their SATB2 genotype. Incomplete penetrance has been observed in mouse models; one study of Satb2-haploinsufficient mice showed cleft palate in approximately 25% , whereas another population was reported as phenotypically normal . Thus, SATB2 haploinsufficiency alone may not be sufficient for cleft palate; other factors, environmental or genetic, may need to be present to lead to clefting.
SATB2 also likely influences brain development, as illustrated by the severe mental retardation seen in these subjects. This is consistent with mouse studies that show Satb2 is necessary for proper establishment of cortical neuron connections across the corpus callosum , despite the apparently normal corpus callosum in heterozygous knockout mice. One subject in this report who had brain imaging, subject 1, had a normal study.
A behavioral phenotype in some individuals with 2q32q33 microdeletions further implicates a role of this gene in brain development. Subjects 1 and 2 in the present study had characteristic behaviors, including repetitive behaviors, touch avoidance, chewing on hands, skin picking, aggression, and pica. Subject 3, who did not have a history of behavior problems, did have a history of sleeping difficulties. Some of these behaviors overlap with those seen in previously reported individuals , , , . Additionally, one individual with a balanced translocation disrupting SATB2 had autism spectrum disorder . By excluding the deletion of the individual in their study without behavioral problems, Van Buggenhout et al.  proposed a 0.5-Mb common deletion region at 2q32.3 proximal to SATB2 for behavioral problems. However, the presence of a rather typical behavioral phenotype in two of the individuals in our report suggests a role for SATB2 haploinsufficiency in these characteristic behaviors. However, not all individuals with SATB2 abnormalities exhibit behavioral problems; the individuals reported by Brewer et al.  with balanced translocations disrupting SATB2  had mild learning disabilities with speech delay and no report of behavior problems. Haploinsufficiency for other genes in the region may also have an impact on behavior, because the individual with a 2q31.2q32.3 deletion that did not include SATB2 also had hyperactivity, anxiety, aggressiveness, and self mutilation .
Our results suggest haploinsufficiency of SATB2 causes some of the clinical features associated with the 2q32q33 microdeletion syndrome, including palate abnormalities, tooth anomalies, MR and behavior problems. Because many chromosomal syndromes are caused by more than one gene (contiguous gene syndromes), identification and characterization of additional individuals may elucidate the full etiology of this syndrome.
Materials and Methods
For the individuals with 2q33.1 microdeletions described here, informed consent was obtained to perform high-resolution microarray-based molecular cytogenetic testing and to publish photographs.
Subjects and controls
During the period encompassing November 2007 through October 2008, we tested 9,773 samples submitted to Signature Genomic Laboratories from the United States and abroad. The most common clinical presentations were mental retardation, developmental delay, or multiple congenital anomalies.
BAC Microarray analysis
Microarray-based comparative genomic hybridization (aCGH) was performed with a BAC microarray (the SignatureChip; Signature Genomic Laboratories, Spokane, WA) . The SignatureChip Whole Genome (SignatureChipWG) is currently in use in this laboratory. Results were visualized using Signature Genomic Laboratories' laboratory-developed computer software program Genoglyphix (http://www.signaturegenomics.com/genoglyphix.html). Each BAC clone was verified by fluorescence in situ hybridization (FISH) for its chromosomal location prior to microarray construction and validated for use in FISH to visualize chromosome abnormalities identified by the microarray. Microarray analysis was performed as previously described .
Oligonucleotide Microarray analysis
Oligonucleotide-based microarray analysis was performed on individuals with microdeletions of 2q33.1 using a 105K-feature whole-genome microarray (SignatureChip Oligo Solution, made for Signature Genomic Laboratories by Agilent Technologies, Santa Clara, CA) with one probe every 10 kb in targeted regions—microdeletion/microduplication syndromes, the pericentromeric regions, subtelomeres and genes in important developmental pathways—and an average probe spacing of one probe every 35 kb throughout the rest of the genome. Genomic DNA was extracted from peripheral blood using a Qiagen M48 Biorobot automated DNA extraction system. Purified genomic DNA was then sonicated and labeled with Alexaflour dyes 555 or 647 using a BioPrime Total DNA labeling kit (Invitrogen Corp, Carlsbad, CA). Array hybridization and washing was performed as specified by the manufacturer (Agilent Technologies). Arrays were scanned using an Axon 4000B scanner (Molecular Devices) and analyzed using Agilent Feature Extraction software v9.5.1 and Agilent CGH Analytics software v3.5.14. Results were then displayed using custom oligonucleotide aCGH analysis software (Oligoglyphix; Signature Genomic Laboratories).
Genomic sequence analysis
Computational analysis of 2q32q33 was performed using the annotated May 2006 assembly of the human genome on the UCSC genome browser (http://genome.ucsc.edu; build hg18).
Fluorescence in situ hybridization
Deletions of the SATB2 locus were confirmed and visualized by metaphase FISH using BAC clone RP11-404F23 as previously described .
We thank Aaron Theisen (Signature Genomic Laboratories, Spokane, WA) for his critical editing of our manuscript and Sara Minier (Signature Genomic Laboratories) for assistance with Figure 1.
Conceived and designed the experiments: LGS. Performed the experiments: BCB. Analyzed the data: JAR BCB BAT LGS. Contributed reagents/materials/analysis tools: AL EJS CP ASA. Wrote the paper: JAR.
- 1. Britanova O, Akopov S, Lukyanov S, Gruss P, Tarabykin V (2005) Novel transcription factor Satb2 interacts with matrix attachment region DNA elements in a tissue-specific manner and demonstrates cell-type-dependent expression in the developing mouse CNS. Eur J Neurosci 21: 658–668.
- 2. Dobreva G, Dambacher J, Grosschedl R (2003) SUMO modification of a novel MAR-binding protein, SATB2, modulates immunoglobulin mu gene expression. Genes Dev 17: 3048–3061.
- 3. Alcamo EA, Chirivella L, Dautzenberg M, Dobreva G, Farinas I, et al. (2008) Satb2 regulates callosal projection neuron identity in the developing cerebral cortex. Neuron 57: 364–377.
- 4. Dobreva G, Chahrour M, Dautzenberg M, Chirivella L, Kanzler B, et al. (2006) SATB2 is a multifunctional determinant of craniofacial patterning and osteoblast differentiation. Cell 125: 971–986.
- 5. FitzPatrick DR, Carr IM, McLaren L, Leek JP, Wightman P, et al. (2003) Identification of SATB2 as the cleft palate gene on 2q32-q33. Hum Mol Genet 12: 2491–2501.
- 6. Brewer CM, Leek JP, Green AJ, Holloway S, Bonthron DT, et al. (1999) A locus for isolated cleft palate, located on human chromosome 2q32. Am J Hum Genet 65: 387–396.
- 7. Leoyklang P, Suphapeetiporn K, Siriwan P, Desudchit T, Chaowanapanja P, et al. (2007) Heterozygous nonsense mutation SATB2 associated with cleft palate, osteoporosis, and cognitive defects. Hum Mutat 28: 732–738.
- 8. Tegay DH, Chan KK, Leung L, Wang C, Burkett S, et al. (2009) Toriello-Carey syndrome in a patient with a de novo balanced translocation [46,XY,t(2;14)(q33;q22)] interrupting SATB2. Clin Genet 75: 259–264.
- 9. Marshall CR, Noor A, Vincent JB, Lionel AC, Feuk L, et al. (2008) Structural variation of chromosomes in autism spectrum disorder. Am J Hum Genet 82: 477–488.
- 10. Britanova O, Depew MJ, Schwark M, Thomas BL, Miletich I, et al. (2006) Satb2 haploinsufficiency phenocopies 2q32-q33 deletions, whereas loss suggests a fundamental role in the coordination of jaw development. Am J Hum Genet 79: 668–678.
- 11. Van Buggenhout G, Van Ravenswaaij-Arts C, Mc Maas N, Thoelen R, Vogels A, et al. (2005) The del(2)(q32.2q33) deletion syndrome defined by clinical and molecular characterization of four patients. Eur J Med Genet 48: 276–289.
- 12. Ramer JC, Mowrey PN, Robins DB, Ligato S, Towfighi J, et al. (1990) Five children with del (2)(q31q33) and one individual with dup (2)(q31q33) from a single family: review of brain, cardiac, and limb malformations. Am J Med Genet 37: 392–400.
- 13. Ramer JC, Ladda RL, Frankel CA, Beckford A (1989) A review of phenotype-karyotype correlations in individuals with interstitial deletions of the long arm of chromosome 2. Am J Med Genet 32: 359–363.
- 14. Al-Awadi SA, Farag TI, Naguib K, Teebi A, Cuschieri A, et al. (1983) Interstitial deletion of the long arm of chromosome 2: del(2)(q31q33). J Med Genet 20: 464–465.
- 15. Benson K, Gordon M, Wassman ER, Tsi C (1986) Interstitial deletion of the long arm of chromosome 2 in a malformed infant with karyotype 46,XX,del(2)(q31q33). Am J Med Genet 25: 405–411.
- 16. Buchanan PD, Rhodes RL, Stevenson CE Jr (1983) Interstitial deletion 2q31 leads to q33. Am J Med Genet 15: 121–126.
- 17. Dallapiccola B, Novelli G, Giannotti A (1988) Deletion 2q31.3–2q33.3: gene dosage effect of ribulose 5-phosphate 3-epimerase. Hum Genet 79: 92.
- 18. Franceschini P, Cirillo Silengo M, Davi G, Bianco R, Biagioli M (1983) Interstitial deletion of the long arm of chromosome 2 (q31q33) in a girl with multiple anomalies and mental retardation. Hum Genet 64: 98.
- 19. Glass IA, Swindlehurst CA, Aitken DA, McCrea W, Boyd E (1989) Interstitial deletion of the long arm of chromosome 2 with normal levels of isocitrate dehydrogenase. J Med Genet 26: 127–130.
- 20. Hiroyama Y, Hatanaka H, Ikenoue T, Ishihara Y (1990) Interstitial deletion of long arm of chromosome 2(q31q33). Acta Paediatr Jpn 32: 563–565.
- 21. Markovic S, Krstic M, Sulovic V, Radojkovic Z, Adzic S (1985) Interstitial deletion of chromosome 2. J Med Genet 22: 154–155.
- 22. Miyazaki K, Yamanaka T, Ogasawara N (1988) Interstitial deletion 2q32.1–q34 in a child with half normal activity of ribulose 5-phosphate 3-epimerase (RPE). J Med Genet 25: 850–851.
- 23. Palmer CG, Heerema N, Bull M (1990) Deletions in chromosome 2 and fragile sites. Am J Med Genet 36: 214–218.
- 24. Sumi S, Obayashi M, Murakami M, Ito J, Okada N, et al. (1988) Interstitial deletion of the long arm of chromosome 2: a dose study on isocitrate dehydrogenase 1. Jinrui Idengaku Zasshi 33: 461–467.
- 25. Taysi K, Dengler DR, Jones LA, Heersma JR (1981) Interstitial deletion of the long arm of chromosome 2: case report and review of literature. Ann Genet 24: 245–247.
- 26. Vogels A, Haegeman J, Fryns JP (1997) Pierre-Robin sequence and severe mental retardation with chaotic behaviour associated with a small interstitial deletion in the long arm of chromosome 2 (del(2)(q331q333)). Genet Couns 8: 249–252.
- 27. Young RS, Shapiro SD, Hansen KL, Hine LK, Rainosek DE, et al. (1983) Deletion 2q: two new cases with karyotypes 46,XY,del(2)(q31q33) and 46,XX,del(2)(q36). J Med Genet 20: 199–202.
- 28. de Ravel TJ, Balikova I, Thiry P, Vermeesch JR, Frijns JP (2009) Another patient with a de novo deletion further delineates the 2q33.1 microdeletion syndrome. Eur J Med Genet.
- 29. Mencarelli MA, Caselli R, Pescucci C, Hayek G, Zappella M, et al. (2007) Clinical and molecular characterization of a patient with a 2q31.2-32.3 deletion identified by array-CGH. Am J Med Genet A 143A: 858–865.
- 30. Bejjani BA, Saleki R, Ballif BC, Rorem EA, Sundin K, et al. (2005) Use of targeted array-based CGH for the clinical diagnosis of chromosomal imbalance: Is less more? Am J Med Genet A 134: 259–267.
- 31. Ballif BC, Theisen A, Coppinger J, Gowans GC, Hersh JH, et al. (2008) Expanding the clinical phenotype of the 3q29 microdeletion syndrome and characterization of the reciprocal microduplication. Mol Cytogenet 1: 8.
- 32. Shaffer LG, McCaskill C, Han JY, Choo KH, Cutillo DM, et al. (1994) Molecular characterization of de novo secondary trisomy 13. Am J Hum Genet 55: 968–974.