Integrity of the thyroglobulin locus in tricho-rhino-phalangeal syndrome II

Summary The thyroglobulin gene has been mapped to chromosome band 8q24 by several investigators. This is the band implicated in the causation of Langer-Giedion syndrome (tricho-rhino-phalangeal syndrome II). We have examined a restriction fragment length polymorphism at the thyroglobulin locus in a patient with Langer-Giedion syndrome and 8q deletion in order to: (1) localize the Langer-Giedion deletion more precisely, (2) define the relative map positions of the thyroglobulin gene and the Langer-Giedion locus. The results indicate that the locus of the thyroglobulin gene is intact in the patient with an interstitial deletion of proximal band 8q24.1 which confirms its more distal localization reported earlier by Bergé-Lefranc et al. (1985). It also assigns the critical region for the causation of Langer-Giedion syndrome to the proximal part of band 8q24, viz. 8q24.11q24.13.     

Langer-Giedion syndrome,in a child with complex structural aberration of chromosome 8

A patient with typical features of the Langer-Giedion syndrome (tricho-rhino-phalangeal syndrome, type II) is described. In the karyotype an interstitial deletion of the long arm of chromosome 8 (band 8q22) was observed as the result of a complex rearrangement of chromosomes 1 and 8: 46,XY inv(8)(q23 leads to q242), del(8)(q221 leads to q223), ins(8;1) (q221;p321 p341;q242). Previously reported cases of Langer-Giedion syndrome with deletion of 8q are compared with the present one.     

An integrated physical map of 8q22-q24: use in positional cloning and deletion analysis of Langer-Giedion syndrome

We have developed an integrated map for a 35-cM area of human chromosome 8 surrounding the Langer-Giedion syndrome deletion region. This map spans from approximately 8q22 to 8q24 and includes 10 hybrid cell intervals, 89 polymorphic STSs, 118 ESTs, and 37 known genes or inferred gene homologies. The map locations of 25 genes including osteoprotegerin, syndecan-2, and autotaxin have been refined from the general locations previously reported. In addition, the map has been used to indicate the location of nine deletions in patients with Langer-Giedion syndrome and trichorhinophalangeal syndrome type I to demonstrate the potential usefulness of the map in the analysis of these complex syndromes. The map will also be of interest to anyone trying to clone positionally disease genes in this region, such as Cohen syndrome (8q22-q23), Klip-Feil syndrome (8q22.2), hereditary spastic paraplegia (8q24), and benign adult familial myoclonic epilepsy (8q23.3-q24.1).     

Langer-Giedion syndrome and deletion of the long arm of chromosome 8

Summary Reexamination of a previously reported patient with 8q interstitial deletion reveals the development of a tricho-rhinophalangeal syndrome type II (Langer-Giedion syndrome) with multiple exostoses at the age of 4 years. Together with the two previous reports on 8q deletion and TRP II syndrome the present observation strongly supports the causal relationship between TRP II syndrome and 8q deletion.     

Two cases of the Langer-Giedion syndrome with the same interstitial deletion of the long arm of chromosome 8: 46,XY or XX,del(8)(q23.3q24.13)

Summary Two cases of the Langer-Giedion syndrome (LGS) are reported. Chromosome analysis by high-resolution banding with 850 bands revealed the same abnormal karyotype, 46,XY or XX,del(8)(q23.3q24.13), which was the smallest deletion among those of LGS patients with 8q deletion. The deleted segments found in three patients with LGS analyzed by high-resolution banding have a part of 8q23.3 and 8q24.11 in common.     

Maternal origin of a de novo chromosome 8 deletion in a patient with Langer-Giedion syndrome

Summary The anonymous DNA probe L32, which defines the D8S48 locus within the Langer-Giedion syndrome chromosome region on the long arm of chromosome 8, was used to search for a common restriction fragment length polymorphism. A HindIII and an MspI polymorphism were detected (polymorphism information contents 0.25 and 0.19, respectively). Both polymorphisms were informative in the family of a Langer-Giedion patient carrying a de novo interstitial deletion 8q23-24.1. Lack of transmission of a maternal haplotype indicates that this deletion occurred during maternal gametogenesis. This finding contrasts with the frequent paternal origin of mutations in other microdeletion syndromes.     

Langer-Giedion syndrome with and without del 8q. Assignment of critical segment to 8q23

Summary Two patients with typical Langer-Giedion or trichorhino-phalangeal type II syndrome are reported. One had an apparently normal karyotype. The second had an intercalary del 8q23. Attention is drawn to the severe bone defects seen in the latter and observations from the literature are discussed. The critical segment is assigned to band 8q23. The syndrome may result in a number of cases from a visible deletion, and in other instances from a more conventional gene mutation, although the molecular mechanism is uncertain.     

Langer-Giedion syndrome and deletion in the long arm of chromosome 8

Del(8) (q24.11-q24.13) were detected in 3 patients with typical Langer-Giedion syndrome (LGS) and studied by high-resolution methods. Analysis of the literature strongly suggests the chromosomal ethiology of the LGS, because in all patients examined in detail a deletion of the segment 8(q24.11-q24.13) was revealed, which is critical for the LGS. Interrelationships between the LGS and two monogenic conditions-tricho-rhino-phalangeal syndrome type I and multiple exostoses are discussed. The possible role of c-myc oncogene in exostoses' (including those in LGS) origin is anticipated.     

Langer-Giedion syndrome associated with submucous cleft palate

We report a 4-year-old girl with characteristic features of the Langer-Giedion syndrome (trichorhinophalangeal syndrome type II) who also had submucous cleft palate. When she underwent a palatoplasty, a diagnosis of Langer-Giedion syndrome was made because of the characteristic facial features, multiple exostoses, and partial deletion of the long arm of chromosome 8. This is the first case of trichorhinophalangeal syndrome associated with cleft palate. We review the clinical alterations of trichorhinophalangeal syndromes and differential diagnosis of Langer-Giedion syndrome from trichorhinophalangeal syndrome type I and hereditary multiple exostoses. We also describe the importance of trichorhinophalangeal syndrome in plastic surgery.     

Molecular analysis of overlapping chromosomal deletions in patients with Langer-Giedion syndrome.

We have obtained lymphoblastoid cell lines from three patients with Langer-Giedion syndrome who have overlapping deletions in 8q24.1. To isolate the deletion chromosomes from their normal homologs, patient cell lines were fused with hamster cells and hybrid cells were selected for retention of human chromosome 8. These hybrid cell lines were screened for the presence of chromosome 8 by fluorescence in situ hybridization and by Southern blot hybridization. We have hybridized 31 recombinant DNA clones derived from the 8q22-qter region to Southern blots of the hybrid cell lines; 8 were found to lie within the deletion of at least one patient. One clone identified sequences that were missing from one copy of chromosome 8 in all three patients. These clones help to further define the deletions in these patients and will serve as starting points for detailed characterization of the region.     

Construction and characterization of band-specific DNA libraries

Summary A universally primed polymerase chain reaction was developed to amplify DNA dissected from GTG-banded human chromosomes. The amplification products are cloned into plasmid vectors, which allow the rapid characterization of recombinant clones. Starting from 20–40 chromosome fragments, several thousand independent clones detecting single-copy sequences can be obtained. Although these libraries comprise only a few percent of the dissected DNA, they provide narrowly spaced anchor clones for the molecular characterization of chromosome bands and the identification of gene sequences. Here we describe the construction and characterization of DNA libraries for the Langer-Giedion syndrome chromosome region (LGCR, 8q23–24.1), Wilms tumor chromosome region 1 (WT1, 11p13), Prader-Willi syndrome/Angelman syndrome chromosome region (PWCR/ANCR, 15q11.2–12), meningioma chromosome region (MGCR, 22q12–13), and fragile X chromosome region (FRAXA, Xq27.3).     

Genetic heterogeneity in families with hereditary multiple exostoses

We have carried out a linkage analysis on 11 families segregating gene(s) for hereditary multiple exostoses (EXT). Four highly informative, short tandem-repeat (STR) markers that have been physically mapped to an interval surrounding the Langer-Giedion chromosomal region (8q24.11-q24.13) were used in a multipoint linkage analysis. Significant evidence for linkage of EXT with genetic heterogeneity was found. A model of heterogeneity with linkage of the disease gene to the STR markers in 70% of the families (with a 95% confidence interval of 26%–96%) produced a maximum LOD score of 8.11, with the most likely position of EXT between D8S85 and D8S199. Thus there are at least two genes that are capable of causing hereditary multiple exostoses, one in the Langer-Giedion region and one at another, unlinked location.     

Molecular definition of the shortest region of deletion overlap in the Langer-Giedion syndrome

The Langer-Giedion syndrome (LGS), which is characterized by craniofacial dysmorphism and skeletal abnormalities, is caused by a genetic defect in 8q24.1. We have used 13 anonymous DNA markers from an 8q24.1-specific microdissection library, as well as c-myc and thyroglobulin gene probes, to map the deletion breakpoints in 16 patients with LGS. Twelve patients had a cytogenetically visible deletion, two patients had an apparently balanced translocation, and two patients had an apparently normal karyotype. In all cases except one translocation patient, loss of genetic material was detected. The DNA markers fall into 10 deletion intervals. Clone L48 (D8S51) defines the shortest region of deletion overlap (SRO), which is estimated to be less than 2 Mbp. Three clones--p17-2.3 EE (D8S43), L24 (D8S45), and L40 (D8S49) - which flank the SRO recognize evolutionarily conserved sequences.     

Genes and chromosomal breakpoints in the Langer-Giedion syndrome region on human chromosome 8

The tricho-rhino-phalangeal syndrome type II (TRPS II, or Langer-Giedion syndrome) is an example of contiguous gene syndromes, as it comprises the clinical features of two autosomal dominant diseases, TRPS I and a form of multiple cartilaginous exostoses caused by mutations in the EXT1 gene. We have constructed a contig of cosmid, lambda-phage, PAC, and YAC clones, which covers the entire TRPS I critical region. Using these clones we identified a novel submicroscopic deletion in a TRPS I patient and refined the proximal border of the minimal TRPS1 gene region by precisely mapping the inversion breakpoint of another patient. As a first step towards a complete inventory of genes in the Langer-Giedion syndrome chromosome region (LGCR) with the ultimate aim to identify the TRPS1 gene, we analyzed 23 human expressed sequence tags (ESTs) and four genes (EIF3S3, RAD21, OPG, CXIV) which had been assigned to human 8q24.1. Our analyses indicate that the LGCR is gene-poor, because none of the ESTs and genes map to the minimal TRPS1 gene region and only two of these genes, RAD21 and EIF3S3, are located within the shortest region of deletion overlap of TRPS II patients. Two genes, OPG and CXIV, which are deleted only in some patients with TRPS II may contribute to the clinical variability of this syndrome.     

Identification and molecular characterization of de novo translocation t(8;14)(q22.3;q13) associated with a vascular and tissue overgrowth syndrome

Klippel-Trenaunay syndrome (KTS) is a disorder primarily characterized by capillary-venous vascular malformations associated with altered limb bulk and/or length. We report the identification of a balanced translocation involving chromosomes 8q22.3 and 14q13 in a patient with a vascular and tissue overgrowth syndrome consistent with KTS. We demonstrated that translocation t(8;14)(q22.3;q13) arose de novo. These data suggest that a pathogenic gene for a vascular and tissue overgrowth syndrome (KTS) may be located at chromosome 8q22.3 or 14q13. Fluorescence in situ hybridization (FISH) analysis was used to define the breakpoint on chromosome 8q22.3 to a <5-cM interval flanked by markers AFMA082TG9 and GATA25E10, and the 14q13 breakpoint within a 1-cM region between STSs WI-6583 and D14S989. This study provides a framework for the fine-mapping and ultimate cloning of a novel vascular gene at 8q22.3 or 14q13.     

Partial trisomy of distal 8q derived from mother with mosaic 8q23.3→24.13 deletion,and relatively mild expression of trichorhinophalangeal syndrome I

Summary A 17-month-old girl with a partial trisomy of distal 8q derived from her mother, who has a mosaic 8q23.3q24.13 deletion, was studied. Both showed a relatively mild phenotype of trichorhinophalangeal syndrome I. The karyotype of the proposita was designated as: 46,XX,-8,+der(8),inv ins(8;8)(p23.1;q24.13q23.3)mat. Her phenotype was considered similar to that of her mother despite the trisomies of distal 8q. She seems to be the first example of a partial trisomy of distal 8q derived from a parent with an interstitial deletion of a distal 8q segment and trichorhinophalangeal syndrome I.     

Familial trisomy 3q25----qter. Report of two cases

Two girls with the trisomy 3q2 clinical syndrome are presented. Their fathers were twins and carried a t(3;8)(q25;p23). Case 1, aged 8 months, had a 46,XX,der(8) complement. Case 2, died at 5 months of age before cytogenetic study, was considered to have the same karyotype. Both cases combined showed the majority of phenotypical features of trisomy 3q2 syndrome, including facial appearance, glaucoma, and visceral malformations. This observation suggests that the trisomy 3q25----qter is sufficient to produce the syndrome which shows variable expression in these cases.     

A de novo t (X;8)(p11.2;q24.3) demonstrating Cornelia de Lange syndrome phenotype

Cornelia de Lange syndrome is a rare syndrome of hitherto unknown etiology. We present a 9-months old female patient with de novo t (X;8) (p11.2;q24.3) and Cornelia de Lange Syndrome phenotype. De novo t (X;8)(p11.2;q24.3) was not reported so far in Cornelia de Lange syndrome.     

A jumping translocation (5p;15q), (8q;15q), and (12q;15q) (author's transl)]

Three balanced karyotypes (5p;15q), (8q;15q), and (12q;15q) were found simultaneously in a child with the Willi-Prader syndrome. The hypothesis is presented of a "jumping# translocation by affinity of telomeric and interstitial palindromes. The relationship between the Willi-Prader syndrome and a juxtacentric anomaly of the long arm of chromosome 15 is discussed.     

Partial trisomy 8q and partial monosomy 18p: a case report

We report clinical observations and cytogenetic studies of an inherited partial trisomy 8q and partial monosomy 18p. A full trisomy 8 syndrome (Warkany syndrome) is a clinically recognized syndrome. Partial trisomy 8q has been reported sporadically in the literature with variable phenotypes. Partial monosomy 18p, deletion of the short arm of chromosome 18, is also a well-recognized syndrome. This is the first report to the best of our knowledge of partial trisomy for distal 8q and partial monosomy for distal 18p occurring together in a patient.