Co‐existence of 9p deletion and Silver‐Russell syndromes in a patient with maternally inherited cryptic complex chromosome rearrangement involving chromosomes 4, 9, and 11

We report a patient with a maternally inherited unbalanced complex chromosomal rearrangement (CCR) involving chromosomes 4, 9, and 11 detected by microarray comparative genomic hybridization (aCGH) and fluorescence in situ hybridization (FISH). This patient presents with clinical features of 9p deletion syndrome and Silver‐Russell syndrome (SRS). Chromosome analysis performed in 2000 showed what appeared to be a simple terminal deletion of chromosome 9p22.1. aCGH performed in 2010 revealed a 1.63 Mb duplication at 4q28.3, a 15.48 Mb deletion at 9p24.3p22.3, and a 1.95 Mb duplication at 11p15.5. FISH analysis revealed a derivative chromosome 9 resulting from an unbalanced translocation between chromosomes 9 and 11, a chromosome 4 fragment inserted near the breakpoint of the translocation. The 4q28.3 duplication does not contain any currently known genes. The 9p24.3p22.3 deletion region contains 36 OMIM genes including a 3.5 Mb critical region for the 9p‐phenotype. The 11p15.5 duplication contains 49 OMIM genes including H19 and IGF2. Maternal aCGH was normal. However, maternal chromosomal and FISH analyses revealed an apparently balanced CCR involving chromosomes 4, 9, and 11. To the best of our knowledge, this is the first report of a patient with maternally inherited trans‐duplication of the entire imprinting control region 1 (ICR1) among the 11p15.5 duplications reported in SRS patients. This report supports the hypothesis that the trans‐duplication of the maternal copy of ICR1 alone is sufficient for the clinical manifestation of SRS and demonstrates the usefulness of combining aCGH with karyotyping and FISH for detecting cryptic genomic imbalances. © 2012 Wiley Periodicals, Inc.     

Complex de novo rearrangement of chromosome 9 with clinical features of monosomy 9p syndrome

A girl with a complex rearrangement of chromosome 9 is reported. She shows the characteristic clinical features of monosomy 9p syndrome. The rearrangement was apparently preceded by four breaks which resulted in a presumptive tiny deletion of the distal end of the short arm, inversion of the rest of this arm and a proven deletion of the secondary constriction region of the long arm. By means of C-banding, it was possible to demonstrate the paternal origin of the rearranged chromosome 9. Finally, it is shown that the region determining the phenotypic expression of monosomy 9p syndrome is seemingly located at band 9p24.     

17p11.2p12 triplication and del(17)q11.2q12 in a severely affected child with dup(17)p11.2p12 syndrome

Multiple congenital anomalies/mental retardation syndromes due to genomic rearrangements involving chromosome 17p11.2 include deletion resulting in Smith-Magenis syndrome and a reciprocal duplication of the same region resulting in the 17p11.2 duplication syndrome. We present the clinical and molecular analysis of an 8-year-old male with a dup(17p11.2p12) who was evaluated for unusual severity of the phenotype. Fluorescent in situ hybridization (FISH) analysis not only confirmed the 17p duplication but also identified an approximately 25% mosaicism for tetrasomy 17p11.2p12. Whole-genome array comparative genomic hybridization (aCGH) was performed to identify other genomic rearrangements possibly contributing to the severe phenotype and the unusual features in the patient. The 17p duplication was determined by FISH and aCGH to encompass approximately 7.5 Mb, from COX10 to KCNJ12. An approximately 830 Kb deletion of 17q11.2q12, including exon 1 of an amiloride-sensitive cation channel neuronal gene, ACCN1, was also identified by aCGH; breakpoints of the deletion were confirmed by FISH. Sequencing the non-deleted allele of ACCN1 did not show any mutations. Western analysis of human tissue-specific proteins revealed that ACCN1 is expressed not only in the brain as previously reported but also in all tissues examined, including heart, liver, kidneys, and spleen. The large-sized 17p11.2p12 duplication, partial triplication of the same region, and the 17q11.2q12 deletion create a complex chromosome 17 rearrangement that has not been previously identified. This is the first case of triplication reported for this chromosome. Our study emphasizes the utility of whole-genome analysis for known cases with deletion/duplication syndromes with unusual or severe phenotypes.     

A cryptic unbalanced translocation t(2;9)(p25.2;q34.3) causes the phenotype of 9q subtelomeric deletion syndrome and additional exophthalmos and joint contractures

We report on a 26-year-old woman with microcephaly, typical facial features of 9q subtelomeric deletion syndrome, exophthalmos, contractures of elbow and knee joints, severe muscular hypotonia, no ability to walk, and no speech development.Array CGH revealed a cryptic 9q34.3 deletion and 2p25.2-p25.3 duplication transmitted by her mother, who was carrying a balanced translocation of chromosomes 2p and 9q. There are about 50 reported cases of deletions of the subtelomeric part of chromosome 9q, however, duplications of only the terminal part of chromosome 2p are rare. Neuroblastoma, diaphragmatic hernia, neural tube defects, broncho-pulmonary abnormalities, and congenital heart defects are conditions associated with partial trisomy of larger fragments of 2p. To our knowledge there is only one case described with an isolated duplication as distal as in the patient reported here. Joint contractures and exophthalmos observed in this patient are also seen in our patient. These features are not allegeable by the deletion 9q34.3 identified in the patient reported here and may be a hint that terminal duplication of 2p could be associated with exophthalmos and contractures.     

Deletion 2p15-16.1 syndrome: case report and review

We report on a 9-year-old female patient with facial anomalies and developmental delay, heterozygous for three de novo rearrangements: a paracentric inversion of chromosome 7, an apparently balanced translocation between chromosome 1 and 7, involving the same inverted chromosome 7, detected by standard cytogenetic analysis [46,XX, der(7) inv(7)(q21.1q32.1)t(1;7)(q23q32.1)]; and a 2p16.1 deletion, spanning about 3.5 Mb of genomic DNA, shown by SNP-array analysis [arr 2p16.1 (56,706,666-60,234,485)x1 dn]. Clinical features and cytogenetic imbalance in our patient were similar to those reported in five published cases, suggesting that this genomic region is prone to recombination and its hemizygosity results in a distinct although variable spectrum of clinical manifestations.     

Interstitial deletion of the short arm of chromosome 1 (46XY), del(1)(p13p22.3)

A male patient with a de novo proximal interstitial deletion of the short arm of chromosome 1 (46XY), del(1)(p13p22.3) is described with multiple anomalies and developmental delay. This patient's clinical manifestations are compared to previously reported patients with deletions of chromosome 1p.© 1992 Wiley-Liss, Inc.     

Detection of cryptic chromosome aberrations in a patient with a balanced t(1;9)(p34.2;p24) by array-based comparative genomic hybridization

Mental retardation (MR) is one of the most common phenotypes in congenital disorders, but in many cases the pathogenesis remains unknown. Here, we report on a 5-year-old boy with mild developmental disability, cranial malformation, minor anomalies, and moderate MR. G-banded chromosome analysis revealed that he carried an apparent balanced translocation, t(1;9)(p34.2;p24). However, our array-based comparative genomic hybridization (CGH-array) analysis detected a cryptic genomic duplication and a deletion at the breakpoints. Further fluorescence in situ hybridization (FISH) showed that the duplication was approximately 7.9 Mb in size at 1p34.3-p33, and the deletion was 4 Mb at 9pter-p24. Although some features of the patient were consistent with those of monosomy 9p-syndrome, his features were not typical of cases of the syndrome, suggesting that the small deletion region involved in 9p may limit his phenotype. On the other hand, interstitial duplication at 1p34.3-p33 is very rare and his phenotype did not match with that in previous reports. CGH-array is a potentially useful technique for investigating cryptic copy-number alterations in cases of apparently balanced chromosome rearrangements in patients with unexpected clinical features.     

Complex familial rearrangement of chromosome 9p24.3 detected by FISH

We describe a newborn male with minor facial anomalies, pyloric stenosis, and a chromosome rearrangement that involves deletion and addition of material at 9p24.3. Routine studies showed a 46, XY, add (9) (p24) karyotype. Fluorescence in situ hybridization (FISH) with two different whole chromosome probes for chromosome 9 failed to identify whether the additional material was derived from that chromosome. FISH with single copy YAC probes from 9p24 (D9S1858, D9S1813 and D9S54) showed a more complex rearrangement involving a deletion at D9S1858 but not at D9S1813 or D9S54. Parental chromosome studies demonstrated an apparently identical 9p abnormality in the patient's mother. This report describes a familial chromosome rearrangement in an abnormal child and his normal mother and demonstrates the use and limitations of FISH in characterizing chromosomal abnormalities. Am. J. Med. Genet. 76:306–309, 1998. © 1998 Wiley-Liss, Inc.     

XY sex reversal and gonadal dysgenesis due to 9p24 monosomy

We describe a case of XY sex reversal, gonadal dysgenesis, and gonadoblastoma in a patient with a deletion of 9p24 due to a familial translocation. The rearranged chromosome 9 was inherited from the father; the patient's karyotype was 46,XY,der(9)t(8;9)(p21;p24)pat. A review shows that 6 additional patients with 46,XY sex reversal associated with monosomy of the distal short arm of chromosome 9 have been observed. The observation that all 7 patients with sex reversal share a deletion of the distal short arm of chromosme 9 is consistent with the hypothesis that the region 9p24 contains a gene or genes necessary for male sex determination. This present case narrows the chromosome interval containing a critical sex determination gene to the relatively small region 9p24. A molecular analysis of this region will provide a means to identify a gene invoved in male sex determination. Am. J. Med. Genet. 73:321–326, 1997. © 1997 Wiley-Liss, Inc.     

Partial DiGeorge syndrome in two patients with a 10p rearrangement

We describe 2 patients with a partial DiGeorge syndrome (facial dysmorphism, hypoparathyroidism, renal agenesis, mental retardation) and a rearrangement of chromosome 10p. The first patient carries a complex chromosomal rearrangement, with a reciprocal insertional translocation between the short arm of chromosome 10 and the long arm of chromosome 8, with karyotype 46, XY ins(8;10) (8pter 8q13::10p15-->10p14::8q24.1-->8qter) ins(10:8) (10pter--> 10p15::8q24.1-->8q13::10p14-->10qter). The karyotype of the second patient shows a terminal deletion of the short arm of chromosome 10. In both patients, the breakpoints on chromosome 10p reside outside the previously determined DiGeorge critical region II (DGCRII). This is in agreement with previous reports of patients with a terminal deletion of 10p with breakpoints distal to the DGCRII and renal malformations/hypoparathyroidism, and thus adds to evidence that these features may be caused by haploinsufficiency of one or more genes distal to the DGCRII.     

Characterization of deletions at 9p affecting the candidate regions for sex reversal and deletion 9p syndrome by MLPA

The distal region on the short arm of chromosome 9 is of special interest for scientists interested in sex development as well as in the clinical phenotype of patients with the 9p deletion syndrome, characterized by mental retardation, trigonocephaly and other dysmorphic features. Specific genes responsible for different aspects of the phenotype have not been identified. Distal 9p deletions have also been reported in patients with 46,XY sex reversal, with or without 9p deletion syndrome. Within this region the strongest candidates for the gonadal dysgenesis phenotype are the DMRT genes; however, the genetic mechanism is not clear yet. Multiple ligation-dependent probe amplification represents a useful technique to evaluate submicroscopic interstitial or distal deletions that would help the definition of the minimal sex reversal region on 9p and could lead to the identification of gene(s) responsible of the 46,XY gonadal disorders of sex development (DSD). We designed a synthetic probe set that targets genes within the 9p23-9p24.3 region and analyzed a group of XY patients with impaired gonadal development. We characterized a deletion distal to the DMRT genes in a patient with isolated 46,XY gonadal DSD and narrowed down the breakpoint in a patient with a 46,XY del(9)(p23) karyotype with gonadal DSD and mild symptoms of 9p deletion syndrome. The results are compared with other patients described in the literature, and new aspects of sex reversal and the 9p deletion syndrome candidate regions are discussed.     

Clinical and molecular analyses of deletion 3p25-pter syndrome

Hemizygous deletion of 3p25-pter is associated with a phenotype of profound growth failure, microcephaly, characteristic facial changes, and mental retardation. Since the severity may be quite variable, we have studied 3 cases of del 3p25-pter to define the clinical manifestations and the critical chromosome region for phenotypic expression. The patient we now report died at age 6 months and provided an opportunity for a detailed necropsy analysis for only the second time in a del(3p) patient. He had marked hypoplasia of all organs, hypomyelination of white matter, and multiple renal cortical microcysts. Ordered genomic markers from the distal regions of chromosome 3p aided in determining the parent of origin of each deletion and in defining the boundaries of the deleted chromosomal segments. The deleted markers distal to the RAF1 oncogene in 2 of the 3 patients were consistently hemizygous. One patient had an interstitial deletion based on evidence of diploid inheritance of one of the most distal loci (D3S17). Available genetic linkage maps suggest that the deletion spans at least 19 centimorgans (cM). © 1993 Wiley-Liss, Inc.     

Discordant phenotypes in a mother and daughter with mosaic supernumerary ring chromosome 19 explained by a de novo 7q36.2 deletion and 7p22.1 duplication

We report on a patient with severe intellectual disability, microcephaly, short stature, and dysmorphic features who, based on standard karyotyping, has two cytogenetic abnormalities: an apparently balanced paracentric inversion of chromosome 7, inv(7)(q31.2q36), and a small supernumerary ring chromosome derived entirely of material from chromosome 19. While the inversion was detected in all cells, mosaicism was observed for the ring chromosome. Interestingly, apparently identical cytogenetic abnormalities were detected in the patient's mother, who presented with normal stature, few dysmorphic features, and normal cognition without microcephaly. While the level of mosaicism could not adequately explain the phenotypic discordance, comparative genome hybridization revealed a de novo terminal deletion of chromosome 7, del(7)(q36.2), and a terminal duplication of chromosome 7, dup(7)(p22.1) in the patient. Additional cytogenetic investigation revealed that the patient inherited a recombinant chromosome derived from a cryptic maternal pericentric inversion: inv(7)(p22q36). The patient's distinctive features are consistent with the wide phenotypic spectrum reported in 7p duplication and 7q terminal deletion syndromes. These chromosomal regions contain several candidate genes of clinical significance, including SHH, EN2, and FAM20C. Our findings strongly suggest that our patient's phenotype is largely attributable to partial 7pter trisomy and partial 7qter monosomy rather than mosaic supernumerary ring chromosome 19.     

Acute lymphocytic leukemia with 9p anomalies. A report of four additional cases and review of the literature

Childhood acute lymphocytic leukemia (ALL) with partial deletion of the short arm of chromosome 9 (9p-), particularly in the p21-22 region, associated with bulky disease, has been regarded as a possible subgroup of ALL. We have reviewed clinical and cytologic data in 128 cases of ALL (childhood and adult). Four of them had 9p anomalies. Two patients had a deletion in the 9p21 region associated with another deletion (9p13----pter) in one case and with t(1;19)(q21;p13) in the second patient. A third patient had a t(9;14)(p21;q12) balanced translocation associated with 14q22----qter deletion; the last patient showed a t(5;9)(p14;q21) unbalanced translocation also associated with 14q deletion. All four patients had lymphomatous ALL, but immunophenotype was non-T, in the four cases, (non-T, non-B in two patients and common ALL in the two remaining cases). Acute lymphocytic leukemia with 9p anomalies appears relatively frequently and is usually associated with poor prognostic features (i.e., bulk disease and high leukocyte counts) but does not seem restricted to childhood and T-cell lineage.     

An interstitial deletion of 7.1 Mb in chromosome band 6p22.3 associated with developmental delay and dysmorphic features including heart defects, short neck, and eye abnormalities

Seven cases with an interstitial deletion of the short arm of chromosome 6 involving the 6p22 region have previously been reported. The clinical phenotype of these cases includes developmental delay, brain-, heart-, and kidney defects, eye abnormalities, short neck, craniofacial malformations, hypotonia, as well as clinodactyly or syndactyly. Here, we report a patient with a 7.1 Mb interstitial deletion of chromosome band 6p22.3, detected by genome-wide screening array CGH. The patient is a 4-year-old girl with developmental delay and dysmorphic features including eye abnormalities, short neck, and a ventricular septum defect. The deleted region at 6p22.3 in our patient overlaps with six out of the seven previously reported cases with a 6p22–24 interstitial deletion. This enabled us to further narrow down the critical region for the 6p22 deletion phenotype to 2.2 Mb. Twelve genes are mapped to the overlapping deleted region, among them the gene encoding the ataxin-1 protein, the ATXN1 gene. Mice with homozygous deletions in ATXN1 are phenotypically normal but show cognitive delay. Haploinsufficiency of ATXN1 may therefore contribute to the learning difficulties observed in the patients harboring a 6p22 deletion.     

A patient with interstitial deletion of the short arm of chromosome 3 (pter→p21.2::p12→qter) and a CHARGE-like phenotype

We report on a 4-month-old boy with a de novo interstitial deletion of the short arm of chromosome 3 (pter → p21.2::p12 → qter) and clinical findings typical of proximal 3p deletion together with coloboma of iris, heart defect, choanal atresia, retardation of growth and development, genital hypoplasia, and ear anomalies. Family history was unremarkable and parental chromosomes were normal. The clinical manifestations of the patient are compared with those of 10 patients previously described with a proximal 3p deletion. The additional CHARGE-like phenotype is discussed. Am. J. Med. Genet. 69:413–417, 1997. © 1997 Wiley-Liss, Inc.     

Mild phenotypic manifestation of a 7p15.3p21.2 deletion.

A 28 month old girl with dysmorphic features was found to have an interstitial deletion of the short arm of chromosome 7p15.3-7p21.2. The patient had ptosis, dacryostenosis, pectus excavatum, short hands, and her development was normal or mildly delayed. Craniosynostosis and growth retardation, which were present in two other patients with similar deletions, were not present. Because of the mild manifestations, this case expands the clinical spectrum of the 7p15-7p21 deletion phenotype.     

De novo deletion (2) (p11.2p13): clinical, cytogenetic, and immunological data.

We report a case of a boy with a de novo interstitial deletion of chromosome (2) (p11.2p13). Clinical features included dysmorphism of the face, genital region, and limbs, psychomotor retardation, and vitiligo. A reduced ratio of immunoglobulin (Ig) light chain expression (kappa/lambda ratio: 0.7) was found, compatible with deletion of one Ig kappa allele on chromosome 2p12. The patient had no clinical or laboratory signs of immunodeficiency.     

Interstitial deletion of 8p: report of two patients and review of the literature

Two female infants with de novo interstitial deletions of 8p were studied. One with a deletion from p11.21 to p11.23, and the other patient with a deletion from p11.23 to p21.3 had several clinical manifestations of the terminal 8p— syndrome. Band 8p11.23 was deleted in both patients. The clinical manifestations common to both patients included low birth-weight, growth deficiency, congenital heart disease, mental retardation, dolichocephaly, low-set, malformed ears, high-arched palate, thin lips and micrognathia. Since these features may occur in most patients with chromosomal imbalance, and the terminal 8p— syndrome has hitherto been assumed to result from terminal deletions of 8p, ranging from p21.3 to p23, it is likely that these features are simply related to the chromosomal imbalance rather than to band specific imbalance of 8p11.23. The present study suggests that two different types of deletion, interstitial and terminal, are associated with still poorly defined, rather non-specific clinical features.