NTNG1 mutations are a rare cause of Rett syndrome

A translocation that disrupted the netrin G1 gene (NTNG1) was recently reported in a patient with the early seizure variant of Rett syndrome (RTT). The netrin G1 protein (NTNG1) has an important role in the developing central nervous system, particularly in axonal guidance, signalling and NMDA receptor function and was a good candidate gene for RTT. We recruited 115 patients with RTT (females: 25 classic and 84 atypical; 6 males) but no mutation in the MECP2 gene. For those 52 patients with epileptic seizure onset in the first 6 months of life, CDKL5 mutations were also excluded. We aimed to determine whether mutations in NTNG1 accounted for a significant subset of patients with RTT, particularly those with the early onset seizure variant and other atypical presentations. We sequenced the nine coding exons of NTNG1 and identified four sequence variants, none of which were likely to be pathogenic. Mutations in the NTNG1 gene appear to be a rare cause of RTT but NTNG1 function demands further investigation in relation to the central nervous system pathophysiology of the disorder.     

Molecular cloning of a constitutional t(7;22) translocation associated with risk of hematological malignancy

We report the molecular characterization of a reciprocal constitutional translocation t(7;22)(p13;q11.2) carried by three family members who have each developed a hematological malignancy. The chromosome 7 breakpoint was localized to a single BAC clone, RP11-571N3, by sequential fluorescence in situ hybridization analysis of clones selected from the NCBI chromosome 7 map. This was further refined to a 739-bp region by Southern blot analysis of DNA from the two cell lines 1193 and 1194 digested with EcoRI, HindIII, PstI, and PvuII. A 2.8-kb fragment spanning the der(22) breakpoint was amplified by long-range inverse PCR. The sequence of this fragment was used to predict the composition of the der(7) breakpoint, and a 1.3-kb fragment was amplified by use of primers from both chromosomes 7 and 22 based on this prediction. The breakpoint on chromosome 22 is located between the 3rd and 4th V regions of the immunoglobulin lambda (IGL) locus, and the breakpoint on chromosome 7 is located 122 kb proximal to the insulin-like growth factor binding protein (IGFBP) 3 gene. Examination of both reciprocal junctions showed that four bases were lost from chromosome 22, whereas 75 bases were lost from chromosome 7. Small insertions of 46 bases and 13 bases were found at the der(22) and the der(7) junctions, respectively. As a consequence of this event, the entire IGL locus, less the first three Vlambda elements, is translocated to chromosome 7, whereas the three remaining Vlambda elements on the der(22) are juxtaposed with IGFBP3 and IGFBP1.     

Rearrangement in the PITX2 and MIPOL1 genes in a patient with a t(4;14) chromosome

We report the molecular characterization of a patient with mild craniofacial and acallosal central nervous system midline defects and a t(4;14)(q25)(q13) chromosome. With the use of flow sorted chromosomes, the translocation breakpoint junction was defined within a 100 kb region with markers mapping to chromosomes 4q25 and 14q13. Analysis of genomic sequences demonstrated that the breakpoint junction at 14q13 was within the third intron of the 5' untranslated region of the MIPOL1 gene (GI: 22048098). On chromosome 4q25, two breakpoint junctions were found. One was about 47 kb distal to the 5' end of a putative gene (GI: 8923996) with unknown function but with partial similarity to kinases, and a second breakpoint was within the 3' end of the PITX2 gene (GI: 21361182) that resulted in the deletion of exons 6 and 7 of this gene. We also searched for microdeletions in a panel of candidate genes mapping within 2 Mb of the translocation breakpoint junction on chromosomes 4 and 14, however, no evidence for deletions or rearrangements was found. The finding of two breaks on chromosome 4q25 suggests a complex microrearrangement, such as an inversion, in addition to a translocation in this patient.     

A novel gene is disrupted at a 14q13 breakpoint of t(2;14) in a patient with mirror-image polydactyly of hands and feet

Mirror-image polydactyly of hands and feet (MIP) is a very rare congenital anomaly characterized by mirror-image duplication of digits. To isolate the gene responsible for MIP, we performed translocation breakpoint cloning from an MIP patient with t(2;14)(p23.3;q13). We isolated a good candidate gene for MIP that was disrupted by the translocation of the patient. We had previously constructed a 1.2-megabase bacterial artificial chromosome (BAC)/P1-derived artificial chromosome (PAC) contig covering the 14q13 breakpoint of t(2;14)(p23.3;q13). From a 500-kb segment consisting of seven BAC/PAC clones in the contig, we isolated a novel gene (the mirror-image polydactyly 1 gene, designated as MIPOL1, GenBank Accession No. AY059470), in addition to the hepatocyte nuclear factor 3 alpha gene (HNF3A, GenBank Accession No. XM 007360). MIPOL1 spans about 350 kb, comprises 15 exons, and encodes 442 amino acids. Northern blot analysis revealed that MIPOL1 expression is definite but very weak in adult heart, liver, skeletal muscle, kidney, and pancreas, and in fetal kidney. In view of the genome sequence and the contig map constructed, the 14q13 breakpoint of the patient was identified as located in intron 11 of MIPOL1, indicating that the gene was disrupted by the translocation, and that the breakage resulted in MIPOL1 protein truncation. Whole-mount in situ hybridization in mouse resulted in mouse Mipol1 signals all over E10.5–E13.5 mouse embryos. Two other unrelated patients with limb anomalies similar to MIP were subjected to mutation analysis of MIPOL1, but none had any mutations. We then isolated BAC clones from the other breakpoint, 2p23.3. A search for genes and expressed sequence tags in a more than 300-kb region around the 2p23.3 breakpoint found only the neuroblastoma-amplified protein gene (NAG, GenBank Accession No. NM 015909), which is located at least 50 kb centromeric to the breakpoint and is not likely to be related to MIP. MIPOL1 is a good candidate gene for the MIP type of anomaly. Received: October 29, 2001 / Accepted: December 27, 2001     

Rubinstein-Taybi syndrome caused by a De Novo reciprocal translocation t(2;16)(q36.3;p13.3)

Rubinstein-Taybi syndrome (RTS) is a multiple congenital anomalies and mental retardation syndrome characterized by facial abnormalities, broad thumbs, and broad big toes. We have shown previously that disruption of the human CREB-binding protein (CBP) gene, either by gross chromosomal rearrangements or by point mutations, leads to RTS. Translocations and inversions involving chromosome band 16p13.3 form the minority of CBP mutations, whereas microdeletions occur more frequently (approximately 10%). Breakpoints of six translocations and inversions in RTS patients described thus far were found clustered in a 13-kb intronic region at the 5' end of the CBP gene and could theoretically only result in proteins containing the extreme N-terminal region of CBP. In contrast, in one patient with a translocation t(2;16)(q36.3;p13.3) we show by using fiber FISH and Southern blot analysis that the chromosome 16 breakpoint lies about 100 kb downstream of this breakpoint cluster. In this patient, Western blot analysis of extracts prepared from lymphoblasts showed both a normal and an abnormal shorter protein lacking the C-terminal domain, indicating expression of both the normal and the mutant allele. The results suggest that the loss of C-terminal domains of CBP is sufficient to cause RTS. Furthermore, these data indicate the potential utility of Western blot analysis as an inexpensive and fast approach for screening RTS mutations.     

Mutation screening in Rett syndrome patients

Rett syndrome (RTT) was first described in 1966. Its biological and genetic foundations were not clear until recently when Amir et al reported that mutations in the MECP2 gene were detected in around 50% of RTT patients. In this study, we have screened the MECP2 gene for mutations in our RTT material, including nine familial cases (19 Rett girls) and 59 sporadic cases. A total of 27 sporadic RTT patients were found to have mutations in the MECP2 gene, but no mutations were identified in our RTT families. In order to address the possibility of further X chromosomal or autosomal genetic factors in RTT, we evaluated six candidate genes for RTT selected on clinical, pathological, and genetic grounds: UBE1 (human ubiquitin activating enzyme E1, located in chromosome Xp11.23), UBE2I (ubiquitin conjugating enzyme E2I, homologous to yeast UBC9, chromosome 16p13.3), GdX (ubiquitin-like protein, chromosome Xq28), SOX3 (SRY related HMG box gene 3, chromosome Xq26-q27), GABRA3 (gamma-aminobutyric acid type A receptor alpha3 subunit, chromosome Xq28), and CDR2 (cerebellar degeneration related autoantigen 2, chromosome 16p12-p13.1). No mutations were detected in the coding regions of these six genes in 10 affected subjects and, therefore, alterations in the amino acid sequences of the encoded proteins can be excluded as having a causative role in RTT. Furthermore, gene expression of MECP2, GdX, GABRA3, and L1CAM (L1 cell adhesion molecule) was also investigated by in situ hybridisation. No gross differences were observed in neurones of several brain regions between normal controls and Rett patients.     

A novel gene, FGA7, is fused to RUNX1/AML1 in a t(4;21)(q28;q22) in a patient with T-cell acute lymphoblastic leukemia

AML1 is among the most frequent targets of chromosomal rearrangements in human leukemias. We report here the molecular analysis of a t(4;21)(q28;q22) that has disrupted AML1 in a patient with de novo T-cell acute lymphoblastic leukemia. By using 3'-RACE analysis, we show that this rearrangement results in the fusion of a novel gene immediately downstream of exon 5 or exon 6 of AML1, indicating that the AML1 breakpoint lies in intron 6 and that alternative fusion splice variants are generated. The sequence of the novel gene, located at 4q28, does not have any significant homology with any of the known genes in the human GenBank DNA database. However, the first 118 bases are identical to a part of a human ovarian EST. Also, its high homology with mouse and rat sequences suggests that this sequence most probably represents a part of a novel gene, which we named FGA7 (Fused Gene 7 to AML1). Following the AML1 open reading frame, the FGA7 sequence encodes an unknown protein of 27 amino acids. We isolated three bacterial artificial chromosome (BAC) clones that contain the FGA7 sequence and confirmed the breakpoint of the gene on the patient's metaphase spreads by fluorescence in situ hybridization using these BACs as probes. RT-PCR and Northern blot analyses revealed that FGA7 is expressed in ovarian and skeletal muscle tissues. The predicted AML1-FGA7 chimeric proteins contained a limited number of residues fused to AML1 in a situation similar to that reported for the AML1-EAP fusion that is a product of t(3;21). It is possible that the expression of a constitutively shortened AML1 could compete with full-length AML1 and act as a dominant negative inhibitor of the promoters that the core binding factor activates.     

Localization of the 17q breakpoint of a constitutional 1;17 translocation in a patient with neuroblastoma within a 25-kb segment located between the ACCN1 and TLK2 genes and near the distal breakpoints of two microdeletions in neurofibromatosis type 1 patients

We have constructed a 1.4-Mb P1 artificial chromosome/bacterial artificial chromosome (PAC/BAC) contig spanning the 17q breakpoint of a constitutional translocation t(1;17)(p36.2;q11.2) in a patient with neuroblastoma. Three 17q breakpoint-overlapping cosmids were identified and sequenced. No coding sequences were found in the immediate proximity of the 17q breakpoint. The PAC/BAC contig covers the region between the proximally located ACCN1 gene and the distally located TLK2 gene and SCYA chemokine gene cluster. The observation that the 17q breakpoint region could not be detected in any of the screened yeast artificial chromosome libraries and the localization of the 17q breakpoint in the vicinity of the distal breakpoints of two microdeletions in patients with neurofibromatosis type 1 suggest that this chromosomal region is genetically unstable and prone to rearrangements.     

Physical mapping of a tandem duplication on the long arm of chromosome 7 associated with a multidrug resistant phenotype

Both the expression of the multidrug transporter, P-glycoprotein (Pgp), and abnormalities of the long arm of chromosome 7 have been shown to be adverse prognostic indicators in acute leukemias. In this study, a clonal duplication, dup(7)(q11.1q31.1), inherited with the classical multidrug resistant phenotype in a drug-resistant derivative of a human T-cell leukemia cell line was characterized. The position of the duplication was of interest as the gene which encodes Pgp, MDR1, is located on the long arm of chromosome 7 at position 7q21.1. Fluorescence in situ hybridization (FISH) analysis with a chromosome 7-specific painting probe confirmed the composition of the abnormal chromosome. A YAC clone hybridizing to the MDR1 locus confirmed that this gene was located within the duplicated region of the derivative chromosome. With a panel of well-characterized YAC clones, the duplicated segment was found to be a direct tandem duplication, somewhat larger than estimated by conventional cytogenetics. The proximal and distal breakpoints of the abnormality were located and a YAC clone spanning the distal breakpoint was identified. This clone is of particular interest, as it harbors the markers D7S523 and D7S471, close to which a putative tumor suppressor gene is thought to lie. Further examination of the breakpoint region may therefore illuminate the mechanism of Pgp upregulation as well as providing information about a tumor suppressor gene.     

Isolation of MECP2-null Rett Syndrome patient hiPS cells and isogenic controls through X-chromosome inactivation

Rett syndrome (RTT) is a neurodevelopmental autism spectrum disorder that affects girls due primarily to mutations in the gene encoding methyl-CpG binding protein 2 (MECP2). The majority of RTT patients carry missense and nonsense mutations leading to a hypomorphic MECP2, while null mutations leading to the complete absence of a functional protein are rare. MECP2 is an X-linked gene subject to random X-chromosome inactivation resulting in mosaic expression of mutant MECP2. The lack of human brain tissue motivates the need for alternative human cellular models to study RTT. Here we report the characterization of a MECP2 mutation in a classic female RTT patient involving rearrangements that remove exons 3 and 4 creating a functionally null mutation. To generate human neuron models of RTT, we isolated human induced pluripotent stem (hiPS) cells from RTT patient fibroblasts. RTT-hiPS cells retained the MECP2 mutation, are pluripotent and fully reprogrammed, and retained an inactive X-chromosome in a nonrandom pattern. Taking advantage of the latter characteristic, we obtained a pair of isogenic wild-type and mutant MECP2 expressing RTT-hiPS cell lines that retained this MECP2 expression pattern upon differentiation into neurons. Phenotypic analysis of mutant RTT-hiPS cell-derived neurons demonstrated a reduction in soma size compared with the isogenic control RTT-hiPS cell-derived neurons from the same RTT patient. Analysis of isogenic control and mutant hiPS cell-derived neurons represents a promising source for understanding the pathogenesis of RTT and the role of MECP2 in human neurons.     

The myeloperoxidase gene is translocated from chromosome 17 to 15 in a patient with acute promyelocytic leukemia

This study demonstrates that a differentiation-specific gene, the myeloperoxidase (MPO) gene, is translocated in a patient with acute promyelocytic leukemia (APL). The MPO gene recently has been mapped to chromosome #17, close to the breakpoint involved in the t(15;17) commonly seen in APL. By in situ hybridization, we showed that this gene was translocated from chromosome #17 to #15 in an APL patient. Although the significance of this translocation remains unclear, MPO is known to be highly expressed in APL. The causal relationship between the high expression and translocation of this gene requires further investigation.     

A Rett syndrome patient with a ring X chromosome: further evidence for skewing of X inactivation and heterogeneity in the aetiology of the disease

Rett syndrome (RTT) is an X-linked neurodevelopmental disorder, characterised by regression of development in young females. Recently, mutations in the MECP2 gene were found to be present in 80% of sporadic cases, but in much lower frequency (< 30%) among familial cases. Several reports claim that the pattern of X chromosome inactivation (XCI) relates to the penetrance of RTT; in some cases skewed XCI is seen in Rett patients, and in others it is observed among normal carriers. We present here a case of RTT with a 46,X,r(X) in which complete skewed inactivation of the ring was demonstrated. Further, no mutations were found in the MECP2 gene present on the intact X. Our data, in conjunction with two previously published cases of X chromosome abnormalities in RTT, indicate that X chromosome rearrangements are sporadically associated with RTT in conjunction with extreme skewing of X inactivation. Based on our case and reported data, we discuss the evidence for a second X-linked locus for RTT associated with lower penetrance, and a different pattern of XCI, than for MECP2. This would result in a larger proportion of phenotypically normal carrier women transmitting the mutation for this putative second locus, and account for the minority of sporadic and majority of familial cases that are negative for MECP2 mutations.     

Rubinstein‐Taybi syndrome caused by a de novo reciprocal translocation t(2;16)(q36.3;p13.3)

Rubinstein‐Taybi syndrome (RTS) is a multiple congenital anomalies and mental retardation syndrome characterized by facial abnormalities, broad thumbs, and broad big toes. We have shown previously that disruption of the human CREB‐binding protein (CBP) gene, either by gross chromosomal rearrangements or by point mutations, leads to RTS. Translocations and inversions involving chromosome band 16p13.3 form the minority of CBP mutations, whereas microdeletions occur more frequently (∼10%). Breakpoints of six translocations and inversions in RTS patients described thus far were found clustered in a 13‐kb intronic region at the 5′ end of the CBP gene and could theoretically only result in proteins containing the extreme N‐terminal region of CBP. In contrast, in one patient with a translocation t(2;16)(q36.3;p13.3) we show by using fiber FISH and Southern blot analysis that the chromosome 16 breakpoint lies about 100 kb downstream of this breakpoint cluster. In this patient, Western blot analysis of extracts prepared from lymphoblasts showed both a normal and an abnormal shorter protein lacking the C‐terminal domain, indicating expression of both the normal and the mutant allele. The results suggest that the loss of C‐terminal domains of CBP is sufficient to cause RTS. Furthermore, these data indicate the potential utility of Western blot analysis as an inexpensive and fast approach for screening RTS mutations. Am. J. Med. Genet. 92:47–52, 2000. © 2000 Wiley‐Liss, Inc.