Maternal repression of the human GRB10 gene in the developing central nervous system; evaluation of the role for GRB10 in Silver-Russell syndrome

The GRB10 gene encodes a growth suppressor and maps to human chromosome 7p11.2-p13. Maternal duplication (matdup) of this region has recently been associated with Silver-Russell syndrome (SRS), which is characterised by pre- and postnatal growth restriction, craniofacial dysmorphism and lateral asymmetry. Maternal uniparental disomy for chromosome 7 (mUPD7) occurs in approximately 7% of SRS patients. Exposure of a recessive allele due to isodisomy has been ruled out in five mUPD7 cases, suggesting genomic imprinting as the basis for disease. Assuming SRS patients with matdup of 7p11.2-p13 and mUPD7 share a common aetiology, this would implicate a maternally expressed gene from this interval, which is involved in growth inhibition. Murine Grb10 was identified as a maternally expressed gene by subtractive hybridisation using normal and androgenetic mouse embryos. Grb10 maps to the homologous region of proximal mouse chromosome 11, for which mUPD incurs reduced birthweight. A role for GRB10 in SRS was evaluated by determining its imprinting status in multiple human foetal tissues using expressed polymorphisms, and by screening the coding region for mutations in 18 classic non-mUPD7 SRS patients. Maternal repression of GRB10 was observed specifically in the developing central nervous system including brain and spinal cord, with biallelic expression in peripheral tissues. This is in contrast to mouse Grb10, and represents the first example of opposite imprinting in human and mouse homologues. While a role for GRB10 in mUPD7 SRS cases can not be ruled out on the basis of imprinting status, no mutations were identified in the patients screened.     

The imprinted region on human chromosome 7q32 extends to the carboxypeptidase A gene cluster: an imprinted candidate for Silver-Russell syndrome

Imprinted gene(s) on human chromosome 7q32-qter have been postulated to be involved in intrauterine growth restriction associated with Silver-Russell syndrome (SRS) as 7–10% of patients have mUPD(7). Three imprinted genes, MEST, MESTIT1, and COPG2IT1 on chromosome 7q32, are unlikely to cause SRS since epigenetic and sequence mutation analyses have not shown any changes. One hundred kilobases proximal to MEST lies a group of four carboxypeptidase A (CPA) genes. Since most imprinted genes are found in clusters, this study focuses on analysing these CPAs for imprinting effects based on their proximity to an established imprinted domain. Firstly, a replication timing study across 7q32 showed that an extensive genomic region including the CPAs, MEST, MESTIT1, and COPG2IT1 replicates asynchronously. Subsequently, SNP analysis by sequencing RT-PCR products of CPA1, CPA2, CPA4, and CPA5 indicated preferential expression of CPA4. Pyrosequencing was used as a quantitative approach, which confirmed predominantly preferential expression of the maternal allele and biallelic expression in brain. CPA5 expression levels were too low to allow reliable evaluation of allelic expression, while CPA1 and CPA2 both showed biallelic expression. CPA4 was the only gene from this family in which an imprinting effect was shown despite the location of this family of genes next to an imprinted cluster. As CPA4 has a potential role in cell proliferation and differentiation, two preferentially expressed copies in mUPD patients with SRS syndrome would result in excess expression and could alter the growth profiles of these subjects and give rise to intrauterine growth restriction.     

The genetic aetiology of Silver-Russell syndrome

Silver-Russell syndrome (SRS MIM180860) is a disorder characterised by intrauterine and/or postnatal growth restriction and typical facies. However, the clinical picture is extremely diverse due to numerous diagnostic features reflecting a heterogeneous genetic disorder. The mode of inheritance is variable with sporadic cases also being described. Maternal uniparental disomy (mUPD) of chromosome 7 accounts for 10% of SRS cases and many candidate imprinted genes on 7 have been investigated. Chromosome 11 has moved to the forefront as the key chromosome in the aetiology, with reports of methylation defects in the H19 imprinted domain associated with the phenotype in 35-65% of SRS patients. Methylation aberrations have been described in a number of other imprinted growth related disorders such as Beckwith-Wiedmann syndrome. This review discusses these recent developments as well as the previous work on chromosome 7. Other candidate genes/chromosomal regions previously investigated are tabled.     

An analysis of the distribution of hetero- and isodisomic regions of chromosome 7 in five mUPD7 Silver-Russell syndrome probands

Silver-Russell syndrome (SRS) shares common features of intrauterine growth retardation (IUGR) and a number of dysmorphic features including lateral asymmetry in about 50% of subjects. Its genetic aetiology is complex and most probably heterogeneous. Approximately 7% of patients with SRS have been found to have maternal uniparental disomy of chromosome 7 (mUPD7). Genomic DNA samples from five SRS patients with mUPD7 have been analysed for common regions of isodisomy using 40 polymorphic markers distributed along the length of chromosome 7. No regions of common isodisomy were found among the five patients. It is most likely that imprinted gene(s) rather than recessive mutations cause the common phenotype. Heterodisomy of markers around the centromere indicated that the underlying cause of the mUPD7 is a maternal meiosis I non-disjunction error in these five subjects.     

Human PEG1/MEST, an imprinted gene on chromosome 7

The mouse Peg1/Mest gene is an imprinted gene that is expressed particularly in mesodermal tissues in early embryonic stages. It was the most abundant imprinted gene among eight paternally expressed genes (Peg 1-8) isolated by a subtraction-hybridization method from a mouse embryonal cDNA library. It has been mapped to proximal mouse chromosome 6, maternal duplication of which causes early embryonic lethality. The human chromosomal region that shares syntenic homology with this is 7q21-qter, and human maternal uniparental disomy 7 (UPD 7) causes apparent growth deficiency and slight morphological abnormalities. Therefore, at least one paternally expressed imprinted gene seems to be present in this region. In this report, we demonstrate that human PEG1/MEST is an imprinted gene expressed from a paternal allele and located on chromosome 7q31-34, near D7S649. It is the first imprinted gene mapped to human chromosome 7 and a candidate for a gene responsible for primordial growth retardation including Silver-Russell syndrome (SRS).      

Maternally inherited duplication of chromosome 7, dup(7)(p11.2p12), associated with mild cognitive deficit without features of Silver-Russell syndrome

We report on a familial duplication in the short arm of chromosome 7, dup(7)(p11.2p12), present in three generations. The duplication was identified by GTG-banding and fluorescence in situ hybridization (FISH) with a whole chromosome 7 DNA painting probe that verified that the duplicated material originated from chromosome 7. The multicolor banding (mBAND) was used to refine the breakpoint assignment. The duplication identified in the proband was also present in her son and mother. All three carriers have mild cognitive deficiencies. Interstitial duplications of the short arm of chromosome 7, although relatively uncommon, have been described in association with a variety of clinical features, including mental retardation of varying severity. Duplication of the p11.2p13 region on chromosome 7 was reported in association with Silver-Russell syndrome (SRS), and an overlapping dup(7)(p11.2p14.1)dn was described in an individual with autistic disorder. Furthermore, a potentially overlapping maternally transmitted inverted duplication, dup(7)(p13p12.2), was reported in patients with cognitive delay. These observations and the phenotype of our duplication carriers suggest that partial trisomy of the proximal 7p region causes cognitive deficiency. The maternal origin of the duplication is of special interest in light of genomic imprinting and implication of the 7p11-p13 region in the SRS etiology. Locus-specific FISH targeting a growth factor receptor binding protein 10 (GRB10), the strong candidate for SRS residing at 7p12.2, showed that it is not duplicated in our patients. Our study helps refine the SRS critical region on 7p and extends our understanding of the clinical manifestations associated with 7p duplications.     

DNA copy number amplifications in human neoplasms: review of comparative genomic hybridization studies.

This review summarizes reports of recurrent DNA sequence copy number amplifications in human neoplasms detected by comparative genomic hybridization. Some of the chromosomal areas with recurrent DNA copy number amplifications (amplicons) of 1p22-p31, 1p32-p36, 1q, 2p13-p16, 2p23-p25, 2q31-q33, 3q, 5p, 6p12-pter, 7p12-p13, 7q11.2, 7q21-q22, 8p11-p12, 8q, 11q13-q14, 12p, 12q13-q21, 13q14, 13q22-qter, 14q13-q21, 15q24-qter, 17p11.2-p12, 17q12-q21, 17q22-qter, 18q, 19p13.2-pter, 19cen-q13.3, 20p11.2-p12, 20q, Xp11.2-p21, and Xp11-q13 and genes therein are presented in more detail. The paper with more than 150 references and two tables can be accessed from our web site http://www.helsinki.fi/lglvwww/CMG.html. The data will be updated biannually until the year 2001.     

Mosaic maternal uniparental disomy of chromosome 11 in a patient with Silver-Russell syndrome

Silver-Russell syndrome (SRS) is a clinically heterogeneous disorder characterised mainly by intrauterine and postnatal growth retardation. While maternal uniparental disomy of chromosome 7 is found in 5-10% of SRS patients, recently genetic and epigenetic mutations affecting the imprinting centres on chromosome 11p15 have been reported in up to 64% of patients. Chromosome 11p15 abnormalities reported in SRS include methylation defects in the imprinting centre 1 (ICR1) and maternally inherited duplications involving all or part of the imprinted region of 11p15. Here we report the first published case of SRS with mosaic maternal uniparental disomy of chromosome 11.     

Two sisters with Silver-Russell phenotype

Silver-Russell syndrome (SRS) is a well recognizable syndrome, but the etiology of SRS seems to be heterogeneous. SRS is listed in Mendelian Inheritance in Man as an autosomal dominant disorder because most described cases have been of sporadic occurrence, and most likely were caused by de novo autosomal dominant mutation, and because families with apparent dominant transmission of a SRS phenotype have been described. Still, in a few families, autosomal recessive inheritance has been suggested. We describe two sisters who meet the criteria for SRS proposed by Price et al. [1999]. The parents had normal facial features, normal height, and normal post-natal growth. This is the second well-documented case of familial recurrence of SRS that resembles an autosomal recessive inheritance pattern. Since sib recurrence is so rare in SRS, other modes of inheritance should be considered. The finding of maternal uniparental disomy 7 (mUPD7) in 10% of SRS cases suggests that lack of paternally expressed imprinted gene(s) or overexpression of maternal imprinted gene(s) on chromosome 7 cause SRS. The recurrence in sibs could be caused by a mutation in the imprinted gene or imprinting center carried by one parent. Alternatively, recurrence in sibs could represent germ line mosaicism for a dominant mutation in one of the parents.     

Myoclonus‐dystonia and Silver–Russell syndrome resulting from maternal uniparental disomy of chromosome 7

Myoclonus‐dystonia (M‐D) is a movement disorder that is often associated with mutations in epsilon‐sarcoglycan (SGCE), a maternally imprinted gene at 7q21.3. We report a 24‐year‐old male with short stature (<5th percentile) and a movement disorder clinically consistent with M‐D. Single nucleotide polymorphism (SNP) array did not identify significant copy number changes, but revealed three long continuous stretches of homozygosity on chromosome 7 suggestive of uniparental disomy. Parental SNP arrays confirmed that the proband had maternal uniparental disomy of chromosome 7 (mUPD7) with regions of heterodisomy and isodisomy. mUPD7 is the cause of approximately 5–10% of Silver–Russell syndrome (SRS), a disorder characterized by prenatal and postnatal growth retardation. Although SRS was not suspected in our patient, these findings explain his short stature. SGCE methylation testing showed loss of the unmethylated paternal allele. Our findings provide a unifying diagnosis for his short stature and M‐D and help to optimize his medication regimen. In conclusion, we show that M‐D is a clinical feature that may be associated with SRS due to mUPD7. Individuals with mUPD7 should be monitored for the development of movement disorders. Conversely, individuals with M‐D and short stature should be evaluated for SRS.     

Conserved methylation imprints in the human and mouse GRB10 genes with divergent allelic expression suggests differential reading of the same mark

Grb10/GRB10 encodes a cytoplasmic adapter protein which modulates coupling of a number of cell surface receptor tyrosine kinases with specific signalling pathways. Mouse Grb10 is an imprinted gene with maternal-specific expression. In contrast, human GRB10 is expressed biallelically in most tissues, except for maternal-specific expression of one isoform in muscle and paternal expression in fetal brain. Owing to its location in 7p11.2-p12, GRB10 has been considered a candidate gene for the imprinted growth disorder, the Silver-Russell syndrome (SRS), but its predominantly biallelic expression argues against involvement in the syndrome. To investigate the discrepant imprinting between mouse and human, we compared the sequence organization of their upstream regions, and examined their allelic methylation patterns and the splice variant organization of the mouse locus. Contrary to expectation, we detected both maternal and paternal expression of mouse Grb10. Expression of the paternal allele arises from a different promoter region than the maternal and, as in human, is restricted to the brain. The upstream regions are well conserved, especially the presence of two CpG islands. Surprisingly, both genes have a similar imprinted methylation pattern, the second CpG island is a differentially methylated region (DMR) with maternal methylation in both species. Analysis of 24 SRS patients did not reveal methylation anomalies in the DMR. In the mouse this DMR is a gametic methylation mark. Our results suggest that the difference in imprinted expression in mouse and human is not due to acquisition of an imprint mark but in differences in the reading of this mark.     

No evidence for isolated imprinting mutations in the PEG1/MEST locus in Silver-Russell patients

Imprinting defects have meanwhile been described in nearly all human imprinting disorders among them Silver-Russell syndrome (SRS). In this disorder, 11p15 epimutations and maternal Uniparental Disomy of chromosome 7 (UPD7) are detectable in approximately 50% of patients. To find out whether isolated imprinting defects on chromosome 7 play a role in the aetiology of SRS we screened a cohort of 54 SRS patients without 11p15 epimutations. Methylation-specific PCR was carried out for the PEG1/MEST locus in 7q31. This test detects all known segmental and complete UPD7 cases. The exclusion of isolated imprinting defects in our study population shows that this type of epimutation at the PEG1/MEST locus in 7q31 does not play a relevant role in SRS. However, the role of imprinting disturbances in other genes cannot be excluded.     

Severe Silver-Russell syndrome and translocation (17;20) (q25;q13)

An 8-year-8-month-old girl with Silver-Russell syndrome (SRS) and a paternally inherited balanced t(17;20)(q25;q13) is described. This observation suggests that an SRS gene(s) maps on chromosome 17 or 20 and that the patient phenotype resulted from either unmasking of heterozygosity or genomic imprinting via paternal disomy.     

Cytogenetic analysis of myxoid liposarcoma and myxofibrosarcoma by array-based comparative genomic hybridisation

AIM: To investigate overall chromosomal alterations using array-based comparative genomic hybridisation (CGH) of myxoid liposarcomas (MLSs) and myxofibrosarcomas (MFSs). Materials and methods: Genomic DNA extracted from fresh-frozen tumour tissues was labelled with fluorochromes and then hybridised on to an array consisting of 1440 bacterial artificial chromosome clones representing regions throughout the entire human genome important in cytogenetics and oncology. RESULTS: DNA copy number aberrations (CNAs) were found in all the 8 MFSs, but no alterations were found in 7 (70%) of 10 MLSs. In MFSs, the most frequent CNAs were gains at 7p21.1-p22.1 and 12q15-q21.1 and a loss at 13q14.3-q34. The second most frequent CNAs were gains at 7q33-q35, 9q22.31-q22.33, 12p13.32-pter, 17q22-q23, Xp11.2 and Xq12 and losses at 10p13-p14, 10q25, 11p11-p14, 11q23.3-q25, 20p11-p12 and 21q22.13-q22.2, which were detected in 38% of the MFSs examined. In MLSs, only a few CNAs were found in two sarcomas with gains at 8p21.2-p23.3, 8q11.22-q12.2 and 8q23.1-q24.3, and in one with gains at 5p13.2-p14.3 and 5q11.2-5q35.2 and a loss at 21q22.2-qter. CONCLUSIONS: MFS has more frequent and diverse CNAs than MLS, which reinforces the hypothesis that MFS is genetically different from MLS. Out-array CGH analysis may also provide several entry points for the identification of candidate genes associated with oncogenesis and progression in MFS.     

Comparative genomic hybridization analysis of nasopharygeal carcinoma: consistent patterns of genetic aberrations and clinicopathological correlations

To define the patterns of genetic imbalances in nasopharyngeal carcinoma (NPC), we studied 30 primary NPC tumors with comparative genomic hybridization (CGH). The common sites of chromosomal gains were found in descending order of frequency in 12p11.2-p12 (36%), 12q14-q21 (33%), 2q24-q31 (23%), 1q31-qter (20%), 3q13 (20%), 1q13.3 (20%), 5q21 (17%), 6q14-q22 (13%), 7q21 (13%), 8q11.2-q23 (13%) and 18q12-qter (13%). The common sites of chromosomal loss were at 3p14-p21 (20%), 11q23-qter (20%), 16q21-qter (17%) and 14q24-qter (13%). Correlation with clinicopathologic features showed that 3p loss was associated with a significantly higher risk of death related to recurrence as compared with patients without 3p loss (50% vs. 9%, P=.029). The presence of 16q loss was associated with more advanced stage tumors (stages I & II: 6% vs. stages III & IV: 33%, P=.046). We conclude that consistent patterns of genetic imbalances can be observed in NPC. Deletion of 3p and 16q were associated with higher risk of tumor recurrence and advanced stage cancer.     

Trisomy 7 mosaicism, maternal uniparental heterodisomy 7 and Hirschsprung's disease in a child with Silver-Russell syndrome

Prenatal trisomy 7 is usually a cell culture artifact in amniocytes with normal diploid karyotype at birth and normal fetal outcome. In the same way, true prenatal trisomy 7 mosaicism usually results in a normal child except when trisomic cells persist after birth or when trisomy rescue leads to maternal uniparental disomy, which is responsible for 5.5-7% of patients with Silver-Russell syndrome (SRS). We report here on the unusual association of SRS and Hirschsprung's disease (HSCR) in a patient with maternal uniparental heterodisomy 7 and trisomy 7 mosaicism in intestine and skin fibroblasts. HSCR may be fortuitous given its frequency, multifactorial inheritance and genetic heterogeneity. However, the presence of the trisomy 7 mosaicism in intestine as well as in skin fibroblasts suggests that SRS and HSCR might possibly be related. Such an association might result from either an increased dosage of a nonimprinted gene due to trisomy 7 mosaicism in skin fibroblasts (leading to SRS) and in intestine (leading to HSCR), or from an overexpression, through genomic imprinting, of maternally expressed imprinted allele(s) in skin fibroblasts and intestine or from a combination of trisomy 7 mosaicism and genomic imprinting. This report suggests that the SRS phenotype observed in maternal uniparental disomy 7 (mUPD(7)) patients might also result from an undetected low level of trisomy 7 mosaicism. In order to validate this hypothesis, we propose to perform a conventional and molecular cytogenetic analysis in different tissues every time mUPD7 is displayed.     

Comparative genomic hybridization analysis of a pleuropulmonary blastoma

Pleuropulmonary blastoma (PPB) is a rare, aggressive dysontogenetic tumor of childhood. We report the comparative genomic hybridization (CGH) study performed on a case of PPB in a 3-year-old-boy. The tumor was characterized by several chromosomal imbalances. Gains observed affected regions: 1q12-q23, 3q23-qter, 8pter-q24.1, 9p13-q21, 17p12-p11, 17q11-q22, 17q23-q25, 19pter-p11, and 19q11-q13.3. Whole chromosome gains were detected at 2 and 7. Loss of genetic material was found at regions: 6q13-qter, 10pter-p13, 10q22-qter, and 20p13. To our knowledge, there have been no CGH reports on PPB, but it is interesting to note that 1) the alterations found confirm previous cytogenetic reports describing gains of chromosomes 2 and 8 as recurrent abnormalities in this type of tumor, suggesting that a gene or genes of putative relevance in PPB pathogenesis are mapped at 8p11-p12, and 2) the CGH profile of this case is very similar to those observed in embryonal rhabdomyosarcomas, in which gains of 2 or 2q, 7 or 7q, and 8 or 8p and loss of 10q22-qter are consistently found. This finding supports the hypothesis that PPB may be tumorigenetically related with embryonal rhabdomyosarcoma.     

No evidence of PEG1/MEST gene mutations in Silver-Russell syndrome patients.

Silver-Russell syndrome (SRS) is characterized by prenatal and postnatal growth retardation with morphologic anomalies. Maternal uniparental disomy 7 has been reported in some SRS patients. PEG1/MEST is an imprinted gene on chromosome 7q32 that is expressed only from the paternal allele and is a candidate gene for SRS. To clarify its biological function and role in SRS, we screened PEG1/MEST abnormalities in 15 SRS patients from various standpoints. In the lymphocytes of SRS patients, no aberrant expression patterns of two splice variants (alpha and beta) of PEG1/MEST were detected when they were compared with normal samples. Direct sequence analysis failed to detect any mutations in the PEG1/MEST alpha coding region, and there were no significant mutations in the 5'-flanking upstream region containing the predicted promoter and the highly conserved human/mouse genomic region. Differential methylation patterns of the CpG island for PEG1/MEST alpha were normally maintained and resulted in the same pattern as in the normal control, suggesting that there was no loss of imprinting. These findings suggest that PEG1/MEST can be excluded as a major determinant of SRS.     

Comparative analysis of isodisomic and heterodisomic segments in cases with maternal uniparental disomy 14 suggests more than one imprinted region

The results of molecular investigations of 21 cases with complete or segmental maternal uniparental disomy (UPD) 14 published in the literature were compared with respect to isodisomic and heterodisomic segments. The aim of the study was to find hints toward imprinted regions other than the recently defined imprinted segment 14q32. Three regions with no isodisomic molecular marker were found. The most distal of these regions located on 14q32.12 and 14q32.13 supports the hypothesis of genomic imprinting as the cause of the maternal UPD 14 phenotype by synteny to the maternally imprinted region on mouse distal chromosome 12 and correlation with the recently defined imprinting cluster on human chromosome 14q32. The other two heterodisomic areas located on 14q11.2-->14q12 and 14q21.1-->14q31.2 are hints toward one or more additional regions of genomic imprinting on human chromosome 14.