Characterization of a cytogenetic 17q11.2 deletion in an NF1 patient with a contiguous gene syndrome

We report on a rare patient screened as a putative carrier of a contiguous gene syndrome on the basis of a complex phenotype characterized by sporadic neurofibromatosis type 1 (NF1), dysmorphism, mental retardation and severe skeletal anomalies. A cytogenetically visible 17q11.2 deletion was detected in the patient’s karyotype by high-resolution banding and confirmed by fluorescence in situ hybridization with yeast artificial chromosomes targeting the NF1 region. Analysis of the segregation from parents to proband of 13 polymorphic DNA markers, either contiguous or contained within the NF1 gene, showed that the patient is hemizygous at sites within the NF1 gene – the AAAT-Alu repeat in the 5′ region of intron 27b, the CA/GT microsatellite in the 3′ region of intron 27b, and the CA/GT microsatellite in intron 38 – and at the extragenic D17S798 locus, distal to the 3′ end of NF1. The patient may be an important resource in the identification of genes downstream of NF1 that may contribute to some of his extra-NF1 clinical signs. Received: 8 May 1996 / Revised: 17 June 1996     

Molecular characterization and gene content of breakpoint boundaries in patients with neurofibromatosis type 1 with 17q11.2 microdeletions

Homologous recombination between poorly characterized regions flanking the NF1 locus causes the constitutional loss of approximately 1.5 Mb from 17q11.2 covering > or =11 genes in 5%-20% of patients with neurofibromatosis type 1 (NF1). To elucidate the extent of microheterogeneity at the deletion boundaries, we used single-copy DNA fragments from the extreme ends of the deleted segment to perform FISH on metaphase chromosomes from eight patients with NF1 who had large deletions. In six patients, these probes were deleted, suggesting that breakage and fusions occurred within the adjacent highly homologous sequences. Reexamination of the deleted region revealed two novel functional genes FLJ12735 (AK022797) and KIAA0653-related (WI-12393 and AJ314647), the latter of which is located closest to the distal boundary and is partially duplicated. We defined the complete reading frames for these genes and two expressed-sequence tag (EST) clusters that were reported elsewhere and are associated with the markers SHGC-2390 and WI-9521. Hybrid cell lines carrying only the deleted chromosome 17 were generated from two patients and used to identify the fusion sequences by junction-specific PCRs. The proximal breakpoints were found between positions 125279 and 125479 in one patient and within 4 kb of position 143000 on BAC R-271K11 (AC005562) in three patients, and the distal breakpoints were found at the precise homologous position on R-640N20 (AC023278). The interstitial 17q11.2 microdeletion arises from unequal crossover between two highly homologous WI-12393-derived 60-kb duplicons separated by approximately 1.5 Mb. Since patients with the NF1 large-deletion syndrome have a significantly increased risk of neurofibroma development and mental retardation, hemizygosity for genes from the deleted region around the neurofibromin locus (CYTOR4, FLJ12735, FLJ22729, HSA272195 (centaurin-alpha2), NF1, OMGP, EVI2A, EVI2B, WI-9521, HSA272196, HCA66, KIAA0160, and WI-12393) may contribute to the severe phenotype of these patients.     

Somatic mosaicism in a patient with neurofibromatosis type 1.

Using loss of heterozygosity analysis, a method designed to detect moderate to large gene deletions, we have identified a new-mutation neurofibromatosis type 1 (NF1) patient who is somatically mosaic for a large maternally derived deletion in the NF1 gene region. The deletion extends at least from exon 4 near the 5' end of the gene to intron 39 near the 3' end. The gene-coding region is, therefore, mostly or entirely deleted, encompassing a loss of > or = 100 kb. We hypothesize that the deletion occurred at a relatively early developmental timepoint, since signs of NF1 in this patient are not confined to a specific body region, as seen in "segmental" NF, and since both mesodermally and ectodermally derived cells are affected. This report provides the first molecular evidence of somatic mosaicism in NF1 and, taken together with a recent report of germ-line mosaicism in NF1, adds credence to the concept that mosaicism plays an important role in phenotypic and genetic aspects of NF1 and may even be a relatively common phenomenon.     

Formation of a minichromosome by excision of the proximal region of 17q in a patient with von Recklinghausen neurofibromatosis

An interstitial deletion, 17cen----q11.2 (or q12), and a small extra chromosome was found in a sporadic case of von Recklinghausen neurofibromatosis (NF1). In situ hybridization with a chromosome 17-specific alpha-satellite probe showed that the small chromosome was derived from the deleted region, most likely by an excision/ring formation. This chromosome rearrangement is in agreement with the localization of the von Recklinghausen neurofibromatosis (NF1) locus to the proximal region of 17q, but with a more distal breakpoint than observed in two previously described reciprocal translocations associated with NF1. If the NF1 gene has been truncated by the present rearrangement, it may suggest that the NF1 gene is a very large gene at the genomic level. Alternatively, NF1 in this patient may be caused by the gradual loss in somatic cells of the small chromosome carrying an intact NF1 gene, thereby suggesting a recessive mechanism at the gene level. Finally, an intact NF1 gene may have been placed in close proximity with alpha-satellite sequences, which might cause inactivation of the gene. The small supernumerary chromosome may not only facilitate the cloning of the NF1 gene itself, but also offers explanations of the mechanism underlying development of the disease.     

Familial reciprocal translocation t(17;19) (q11.2;q13.2) associated with neurofibromatosis type 1, including one patient with non-Hodgkin lymphoma and an additional t(14;20) in B lymphocytes

The cosegregation of a reciprocal translocation t(17;19) (q11.2;13.2) with neurofibromatosis type 1 in three generations suggested that the breakpoint on chromosome 17 involved the NF1 gene. In order to map the breakpoint, we analysed DNAs of patients using parts of the NF1 gene as probes. Southern analysis revealed that the chromosome 17 breakpoint lies within intron 23 of the NF1 gene. One of the patients of the family developed a non-Hodgkin lymphoma. An additional translocation t(14;20) (q32;13.1) in his B lymphocytes points to a gene on chromosome 20 that is juxtaposed to the IGH locus on 14q32, and that may be of relevance for the development of this tumor type.     

Two independent chromosomal rearrangements, a very small (550 kb) duplication of the 7q subtelomeric region and an atypical 17q11.2 (NF1) microdeletion, in a girl with neurofibromatosis

Most patients with neurofibromatosis (NF1) are endowed with heterozygous mutations in the NF1 gene. Approximately 5% show an interstitial deletion of chromosome 17q11.2 (including NF1) and in most cases also a more severe phenotype. Here we report on a 7-year-old girl with classical NF1 signs, and in addition mild overgrowth (97th percentile), relatively low OFC (10th-25th percentile), facial dysmorphy, hoarse voice, and developmental delay. FISH analysis revealed a 17q11.2 microdeletion as well as an unbalanced 7p;13q translocation leading to trisomy of the 7q36.3 subtelomeric region. The patient's mother and grandmother who were phenotypically normal carried the same unbalanced translocation. The 17q11.2 microdeletion had arisen de novo. Array comparative genomic hybridization (CGH) demonstrated gain of a 550-kb segment from 7qter and loss of 2.5 Mb from 17q11.2 (an atypical NF1 microdeletion). We conclude that the patient's phenotype is caused by the atypical NF1 deletion, whereas 7q36.3 trisomy represents a subtelomeric copy number variation without phenotypic consequences. To our knowledge this is the first report that a duplication of the subtelomeric region of chromosome 7q containing functional genes (FAM62B, WDR60, and VIPR2) can be tolerated without phenotypic consequences. The 17q11.2 microdeletion (containing nine more genes than the common NF1 microdeletions) and the 7qter duplication were not accompanied by unexpected clinical features. Most likely the 7qter trisomy and the 17q11.2 microdeletion coincide by chance in our patient.     

De novo deletion of 1q31.1-q32.1 in a patient with developmental delay and behavioral disorders

We describe the case of a 6-year-old boy with a de novo deletion of the long arm of chromosome 1 encompassing band 1q31.1-q32.1, minor facial anomalies, mild developmental delay, and behavioral disorders. His postnatal karyotype was normal. Using array-comparative genomic hybridization, we identified and characterized a de novo 1q interstitial deletion of about 15.6 Mb, which partially overlaps those of other reported cases. We considered the gene content of the deleted region in an attempt to compare the clinical features of our patient with these other cases, even though they were not characterized molecularly in detail. The most remarkable difference was the absence of microcephaly. To the best of our knowledge, this is the first report of a de novo 1q31.1-q32.1 deletion. Moreover, it illustrates how molecular delineation associated with fine clinical characterization can improve the genotype-phenotype correlations of classical cytogenetic abnormalities.     

Cytogenetic and in situ DNA-hybridization studies in intracranial tumors of a patient with central neurofibromatosis

Summary We have studied a meningioma and an acoustic neurinoma of a patient with central neurofibromatosis. In the meningioma cells, one chromosome 22 was replaced by an almost metacentric, bisatellited marker chromosome that appeared monocentric after CBG-staining. In situ hybridization with a chromosome 22 centromere specific DNA probe (p22hom48.4) revealed specific signals in the pericentromeric region of the marker chromosome, indicating the presence of at least the short arm and the centromere of chromosome 22. The pericentromeric localization of the hybridization signals suggests the marker consists of an isoformation of the short arm of chromosome 22, resulting in a monosomy for the long arm of chromosome 22. In contrast to these finding in meningioma cells, no chromosomal abnormality could be detected in acoustic neurinoma cells. Our finding provide further evidence that loss of genetic material on the long arm of chromosome 22 is associated with the development of central neurofibromatosis.     

Translocation t(1;17)(q12;q25) with a clinical picture like of a proximal deletion of 1q: identification by in situ hybridization with chromosome 1-specific satellite DNA probes

Summary The authors report a case of a balanced 1;17 translocation with breakpoints located in the secondary constriction of chromosome 1. This translocation is associated with pathological symptoms similar to those observed following a proximal deletion of 1q. We request contact with colleques who have observed similar, or related, cases of translocation with breakpoints in heterochromatic regions of human chromosomes.     

A Turner patient with a 45,X,t(1;2) (q41;p11.2) karyotype

The most common chromosomal anomaly is 45,X in the Turner syndrome. In addition to this, anomaly, mosaicism such as structural 46,X,i(Xq), 46,X,del(Xp), 46,X,r(X), 46,X,t(X;Y) and numerical 46XO/46,XX/47XXX are seen rather frequently. An infant with the Turner syndrome was found to have a karyotype 45X,t(1;2) (q41;p16) using high resolution banding. Based on our knowledge, we present the first case of 45X,t(1;2) (q41;p11.2), a karyotype in Turner's syndrome in the literature.     

c-KIT positive Gastrointestinal Stromal Tumor presenting with acute bleeding in a patient with neurofibromatosis type 1: a case report

Background

Gastrointestinal stromal tumours are rare (GIST). However, the incidence of GIST among neurofibromatosis type 1 (NF-1) patients is approximately 3.9-25%. GIST can present clinically in different ways such as abdominal pain, gastrointestinal bleeding and obstruction.

Case report

We present 51 year female patient admitted with Background of neurofibromatosis type 1 admitted with melena. OGD has been done and showed duodenitis with large volume fresh blood in distal duodenum but no obvious bleeding point. Exploratory laparotomy revealed smooth nodular masses on the serosal surface of jejunum. Small bowel resection and side-to-side anastomosis were performed. Histopathoogical examination revealed small bowel gasrointestinal stromal tumour with low risk malignant potential.

Conclusion

The incidence of GIST among neurofibromatosis type 1 (NF-1) patients is not uncommon and we should pay attention to gastrointestinal manifestation in such patients.

     

Teaching cases: A patient with loss of vision in the right eye and neurofibromatosis type 1

Abstract: Neurofibromatosis type 1 is a common autosomal dominant condition that affects about 1 in 5000 people. We describe a 75-year-old man who, in addition to many classic developmental changes of the disease in his skin, eyes and nervous system, had blindness in his right eye as a complication.Case: A 75-year-old man with long-standing neurofibromatosis type 1 was admitted because the vision in his right eye had decreased progressively over 3 months. Physical examination showed disseminated cutaneous and subcutaneous neurofibromas of varying size (Figure 1) and café-au-lait spots (Figure 2). The patient had a visual acuity of 6/18 (20/60) in his right eye and Lisch nodules (iris hamartomas) (Figure 3). A neurologic examination showed no abnormalities other than his loss of vision. Axial T₁-weighted magnetic resonance imaging of the brain and orbits (Figure 4) showed an isointense mass lateral to the right optic nerve that appeared atrophic and pushed to the left. The mass showed a hyperintense signal on T₂-weighted images with contrast enhancement. These findings are compatible with glioma of the optic nerve.Open in a separate windowFigure 1: Disseminated cutaneous and subcutaneous neurofibromas of varying size on the torso of a patient with neurofibromatosis type 1.Open in a separate windowFigure 2: A café-au-lait spot on the patient''s right knee.Open in a separate windowFigure 3: Lisch nodules on the left iris.Open in a separate windowFigure 4: T₁-weighted axial magnetic resonance imaging of the brain and orbits, showing an isointense mass lateral to the right optic nerve (white arrow) that appears atrophic and pushed to the left (black arrow on inset).Axial and coronal magnetic resonance imaging (Figure 5) showed a mass in the left parietal lobe with hyperintensity on T₂-weighted images and hypointensity on T₁-weighted images. After a contrast medium was administered, the lesion showed a thickened, enhanced wall with a central necrotic area. These findings are compatible with astrocytoma.Open in a separate windowFigure 5: T₂-weighted axial (left) and coronal (right) magnetic resonance imaging showing a mass with hyperintensity (arrow) in the left temporal lobe. After administration of a contrast medium, the lesion is visible with a thickened enhanced wall and a central necrotic area.Because of slight enlargement and increased hardness of the subcutaneous lesions, an excisional biopsy was performed. Histology showed delicate fascicles consisting of cells with oval or spindle-shaped nuclei, scant cytoplasm and round cells with entrapped axons (Figure 6). Only scattered neoplastic Schwann cells were stained during immunostaining for S-100 protein (Figure 7). This pattern is consistent with neurofibroma. The patient chose not to receive further treatment and was discharged.Open in a separate windowFigure 6: Biopsy specimen of a subcutaneous neurofibroma showing spindle-shaped and round cells with entrapped axons (hematoxylin and eosin, original magnification ×10).Open in a separate windowFigure 7: Only scattered neoplastic Schwann cells (arrow) are stained after immunostaining for S-100 protein. Normally, S-100 protein is present in cells derived from the neural crest, such as Schwann cells. It can be found in melanoma cells, in malignant peripheral nerve sheath tumours and in certain types of sarcomas.Neurofibromatosis type 1, also known as von Recklinghausen disease,¹ is characterized by changes in pigmentation and the growth of tumours along nerves in the skin and other parts of the body. It is caused by a defect in a tumour-suppressing gene on chromosome 17q11.2. Normally the gene produces neurofibromin, a protein that regulates cellular proliferation.² With the gene mutation, the lack of neurofibromin results in overgrowth of cells from neural crest areas in both the central nervous system (causing Schwann cell tumours on virtually every nerve) and the skin. All people who inherit a copy of the mutated gene are affected. As the pattern of inheritance is autosomal dominant, only 1 copy of the defective gene is needed to cause the condition. However, it is not necessary to have an affected parent. About 30%–50% of patients have a new mutation.Neurofibromatosis type 2 is a much rarer form of neurofibromatosis caused by mutations in both alleles of a different tumour suppressor gene on chromosome 22q12.1.About 1 in 3000–5000 individuals are affected by neurofibromatosis type 1, without differences related to ethnic background.³ Pigmented small macules and café-au-lait patches are often present shortly after birth, although neurofibromas are rare in early childhood. In later childhood and adolescence, both neurofibromas and pigmented lesions become common. Clinical manifestations are variable (4Table 1Open in a separate windowA diagnosis of neurofibromatosis type 1 is based on clinical findings. The patient should have 2 or more of the following: 6 or more café-au-lait spots of ≥ 1.5 cm in postpubertal individuals or ≥ 0.5 cm in prepubertal individuals; 2 or more neurofibromas of any type or 1 or more plexiform neurofibroma; and freckling in the underarms and groin.¹ The differential diagnosis includes benign café-au-lait pigmentation (present in up to 10% of the general population), multiple lipomas, and sporadic schwannomas, gliomas and meningiomas in the central nervous system.Most people with mild neurofibromatosis have little disability. People affected by more severe variants have a shortened life expectancy, especially if tumours of the central nervous system or other malignant neoplasms arise during the course of illness.^1,3 The condition can have a serious psychological impact because the accumulation of skin nodules can be quite disfiguring.⁵ Surgical excision and laser treatment of the neurofibromas are possible, but neither treatment is universally effective.⁶ Transplantation with an allograft of composite tissue on the lower and middle parts of a patient''s face was recently reported.⁷Gliomas of the optic nerve are found in up to 15% of pediatric patients with neurofibromatosis type 1. Best detected using magnetic resonance imaging, these gliomas are symptomatic in about 50% of patients at diagnosis. A minority will progress to vision loss.⁸ The high prevalence of gliomas of the optic nerve that are asymptomatic may, however, be biased by referral patterns, Indeed, in patients with neurofibromatosis type 1, the threshold of risk for optic nerve glioma is low.⁹Guidelines are available for the diagnosis and management of neurofibromatosis type 1.^10,11 Physicians who identify patients with neurofibromatosis type 1 should refer them early to facilities where appropriate evaluation and monitoring of lesions can be carried out. Early detection and monitoring may help to prevent disability and death.     

Small terminal 10q26 deletion in a male patient with Noonan-like stigmata: diagnosis by cytogenetic and FISH analysis

A male patient is reported with terminal 10q26 deletion, developmental retardation, special behaviour, and multiple clinical anomalies including hypotonia, short stature of postnatal onset, short webbed neck, craniofacial dysmorphism, pectus excavatum with widely spaced small nipples, cryptorchidism with scrotal hypoplasia, limb and musculoskeletal anomalies. The facial dysmorphism mainly consisted of trigonocephaly, a long, triangular and asymmetrical face, hypertelorism with pseudoepicanthus, broad nasal bridge, high-arched palate, retrognathia, low-set dysplastic auricles and, on ophthalmologic examination, strabismus, astigmatism and myopia. Some of these clinical stigmata were suggesting the diagnosis of Noonan syndrome. The extremities showed special features including shortening of proximal limbs, brachydactyly with syndactyly of toes II-III and left fingers III-IV, hypoplastic toenails and joint abnormalities. A diastasis of abdominal muscles was noted and, on X-rays a thoracic scoliosis and bilateral coxa valga were evidenced. Analyses of G- and T-banded chromosomes complemented by FISH analyses using different subtelomere probes detected a terminal 10q26 deletion. Subsequent FISH studies using different probes of the 10q26 region were performed in an attempt to closely define the breakpoint and the extent of the deletion and, thereby, to allow karyotype/phenotype comparison between this patient and a previously reported case with an apparently similar 10q26 deletion.     

Mutational analysis and expression studies of the neurofibromatosis type 2 (NF2) gene in a patient with a ring chromosome 22 and NF2

The case of a seriously disabled and retarded female patient with neurofibromatosis type 2 (NF2) is reported. She suffered from bilateral vestibular schwannomas, multiple intracranial meningiomas and neurinomas. The constitutional karyotype of the patient was 46,XX, r(22)/45,XX,–22. A constitutional G to A transition in the proximal 3′ untranslated region of isoforms 1 and 2 was identified in the patient’s NF2 gene and shown not to affect differential splicing or mRNA stability. The instability of the ring chromosome 22 with the associated loss of tumor suppressor genes on chromosome 22, in particular the loss of the NF2 gene, are assumed to have caused multiple tumorigenesis in this patient Received: 7 February 1997 / Accepted: 26 February 1997     

15q11.2 microdeletion and FMR1 premutation in a family with intellectual disabilities and autism

Genomic rearrangements of chromosome 15q11–q13 are responsible for diverse phenotypes including intellectual disabilities and autism. 15q11.2 deletion, implicating common PWS/AS breakpoints BP1–BP2, has been described in patients with delayed motor and speech development and behavioural problems. Here we report the clinical and molecular characterisation of a maternally inherited BP1–BP2 deletion in two siblings with intellectual, motor and speech delay, autistic syndrome disorder and several dysmorphic features. One of the patients was also a carrier of an FMR1 allele in the low premutation range. The four genes within the deletion were under-expressed in all deletion carriers but FMR1 mRNA levels remained normal. Our results suggest that BP1-BP2 deletion could be considered as a risk factor for neuropsychological phenotypes and that it presents with variable clinical expressivity.