A girl with 1p36 deletion syndrome and congenital fiber type disproportion myopathy

Chromosome 1p36 deletion syndrome is characterized by hypotonia, moderate to severe developmental and growth retardation, and characteristic craniofacial dysmorphism. Muscle hypotonia and delayed motor development are almost constant features of the syndrome. We report a 4-year-old Japanese girl with 1p36 deletion syndrome whose muscle pathology showed congenital fiber type disproportion (CFTD) myopathy. This is the first case report of 1p36 deletion associated with CFTD. This association may indicate that one of the CFTD loci is located at 1p36. Ski proto-oncogene −/− mice have phenotypes that resemble some of the features observed in patients with 1p36 deletion syndrome. Because fluorescent in situ hybridization analysis revealed that the human SKI gene is deleted in our patient, some genes in 1p36, including SKI proto-oncogene, may be involved in muscle hypotonia and delayed motor development in this syndrome. Received: March 4, 2002 / Accepted: July 7, 2002     

A 137‐kb deletion within the Potocki–Shaffer syndrome interval on chromosome 11p11.2 associated with developmental delay and hypotonia

Potocki–Shaffer syndrome (PSS) is a rare disorder caused by haploinsufficiency of genes located on the proximal short arm of chromosome 11 (11p11.2p12). Classic features include biparietal foramina, multiple exostoses, profound hypotonia, dysmorphic features, and developmental delay/intellectual disability. Fewer than 40 individuals with PSS have been reported, with variable clinical presentations due in part to disparity in deletion sizes. We report on a boy who presented for initial evaluation at age 13 months because of a history of developmental delay, hypotonia, subtle dysmorphic features, and neurobehavioral abnormalities. SNP microarray analysis identified a 137 kb deletion at 11p11.2, which maps within the classically defined PSS interval. This deletion results in haploinsufficiency for all or portions of six OMIM genes: SLC35C1, CRY2, MAPK8IP1, PEX16, GYLTL1B, and PHF21A. Recently, translocations interrupting PHF21A have been associated with intellectual disability and craniofacial anomalies similar to those seen in PSS. The identification of this small deletion in a child with developmental delay and hypotonia provides further evidence for the genetic basis of developmental disability and identifies a critical region sufficient to cause hypotonia in this syndrome. Additionally, this case illustrates the utility of high resolution genomic approaches in correlating clinical phenotypes with specific genes in contiguous gene deletion syndromes. © 2012 Wiley Periodicals, Inc.     

Confirmation of BRD4 haploinsufficiency role in Cornelia de Lange–like phenotype and delineation of a 19p13.12p13.11 gene contiguous syndrome

Cornelia de Lange syndrome (CdLS) is a genetically and clinical heterogeneous condition characterized by congenital malformation, intellectual disability, and peculiar dysmorphic features. Recently, BRD4 (19p13.12) was proposed as a new critical gene associated with a mild CdLS because of a similar presentation of the patients carrying point mutations and of its involvement in the NIPBL pathway. Patients harboring a 19p interstitial deletion shared some physical features with BRD4 mutation carriers, which results in a more complex phenotype because of the involvement of several neighboring genes. We report a new 19p deletion in a patient clinically diagnosed as CdLS, partially overlapping with previously published cases with the aim to support the role of BRD4 haploinsufficiency in a CdL‐like phenotype and to improve the delineation of 19p13.12p13.11 deletion as a new nonrecurrent gene contiguous syndrome, spanning GIPC1, NOTCH3, BRD4, AKAP8, AKAP8L, CASP14, and EPS15L1 genes. Previously described cases are reviewed, attempting to delineate a genotype–phenotype correlation.     

A patient with de novo 0.45 Mb deletion of 2p16.1: The role of BCL11A,PAPOLG, REL,and FLJ16341 in the 2p15‐p16.1 microdeletion syndrome

The 2p15‐p16.1 microdeletion syndrome is a novel, rare disorder characterized by developmental delay, intellectual disability, microcephaly, growth retardation, facial abnormalities, and other medical problems. We report here on an 11‐year‐old female showing clinical features consistent with the syndrome and carrying a de novo 0.45 Mb long deletion of the paternally derived 2p16.1 allele. The deleted region contains only three protein‐coding RefSeq genes, BCL11A, PAPOLG, and REL, and one long non‐coding RNA gene FLJ16341. Based on close phenotypic similarities with six reported patients showing typical clinical features of the syndrome, we propose that the critical region can be narrowed down further, and that these brain expressed genes can be considered candidates for the features seen in this microdeletion syndrome. © 2013 Wiley Periodicals, Inc.     

Multiple exostoses,mental retardation,hypertrichosis, and brain abnormalities in a boy with a de novo 8q24 submicroscopic interstitial deletion

Multiple exostoses represent a genetically heterogeneous disorder that may occur isolated or as part of a complex contiguous gene syndrome such as Langer‐Giedion syndrome on chromosome 8 and the proximal 11p deletion syndrome on chromosome 11. Here we describe a boy with multiple exostoses, hypertrichosis, mental retardation, and epilepsy due to a de novo deletion on chromosome 8q24. Molecular analysis revealed that the deletion interval overlaps with the Langer‐Giedion syndrome and involves the EXT1 gene and additional genes located distal to EXT1, but probably not encompassing the TRPS1 gene located proximal to EXT1. © 2002 Wiley‐Liss, Inc.     

Xq22.3q23 microdeletion harboring TMEM164 and AMMECR1 genes: Two case reports confirming a recognizable phenotype with short stature,midface hypoplasia,intellectual delay,and elliptocytosis

The AMME syndrome defined as the combination of Alport syndrome, intellectual disability, midface hypoplasia, and elliptocytosis (AMME) is known to be a contiguous gene syndrome associated with microdeletions in the region Xq22.3q23. Recently, using exome sequencing, missense pathogenic variants in AMMECR1 have been associated with intellectual disability, midface hypoplasia, and elliptocytosis. In these cases, AMMECR1 gene appears to be responsible for most of the clinical features of the AMME syndrome except for Alport syndrome. In this article, we present two unrelated male patients with short stature, mild intellectual disability or neurodevelopmental delay, sensorineural hearing loss, and elliptocytosis harboring small microdeletions identified by array‐CGH involving TMEM164 and AMMECR1 genes and SNORD96B small nucleolar RNA for one patient, inherited from their mothers. These original cases further confirm that most specific AMME features are ascribed to AMMECR1 haploinsufficiency. These cases reporting the smallest microdeletions encompassing AMMECR1 gene provide new evidence for involvement of AMMECR1 in the AMME phenotype and permit to discuss a phenotype related to AMMECR1 haploinsufficiency: developmental delay/intellectual deficiency, midface hypoplasia, midline defect, deafness, and short stature.     

Microdeletion and microduplication of 1p36.11p35.3 involving AHDC1 contribute to neurodevelopmental disorder

Xia-Gibbs syndrome is a rare genetic condition characterized by intellectual disability, growth retardation, delayed psychomotor development with absent or poor expressive language, distinctive facial features, hypotonia, laryngomalacia and obstructive sleep apnea. At present, Xia-Gibbs syndrome has been reported to be mainly caused by truncating mutations in AHDC1 gene located on chromosome 1p36.11. However, the evidence supporting AHDC1 deletion as a cause of this syndrome is still limited. Here we report an 8-year-old boy carrying a de novo 575 Kb microdeletion at 1p36.11 including AHDC1 gene. The boy is characterized by intellectual disability, developmental delay, short stature, expressive language delay, facial dysmorphism, obstructive sleep apnea and multiple congenital anomalies, which are mostly consistent with the characteristics of Xia-Gibbs syndrome. Therefore, we provide further supporting evidence that AHDC1 deletion causes Xia-Gibbs syndrome through a haploinsufficiency mechanism. Currently, clinical consequences of AHDC1 gene duplication has never been reported. Here, we identify a de novo 480 Kb duplication at 1p36.11p35.3 spanning the entire AHDC1 gene in a 2-year-8-month boy, who displays similar clinical features with that of Xia-Gibbs syndrome, in particular, expressive language delay, hypotonia, laryngomalacia and obstructive sleep apnea, as well as mirrored phenotypes such as overgrowth and advanced bone age. WES test excludes to the degree possible other known genetic causes. This case suggests that AHDC1 gene duplication may be clinical significance.     

Complex constitutional subtelomeric 1p36.3 deletion/duplication in a mentally retarded child with neonatal neuroblastoma

Monosomy 1p36 is one of the most frequent subtelomeric microdeletion syndromes characterized by distinct craniofacial features and developmental delay/mental retardation. Other common symptoms include hypotonia, seizures, brain abnormalities, visual, auditory and heart defects. Neuroblastoma is a rare feature since to our knowledge only two patients with “pure” 1p36 deletion have been described. We report on a child with developmental delay and facial dysmorphy who developed neuroblastoma at 1 month of age. No primary site outside of the liver could be demonstrated and the tumour regressed spontaneously. Standard karyotyping was normal while subtelomeric screening using Multiplex Ligation-dependent Probe Amplification (MLPA) method revealed a constitutional de novo subtelomeric 1p36 deletion. Subsequent Agilent 244K oligonucleotide array-based comparative genomic hybridization (CGH) and fluorescence in situ hybridization (FISH) analysis showed a complex 1p36.3 deletion/duplication rearrangement. Among the best candidate genes predisposing to the development of neuroblastoma located in 1p36, the AJAP1 gene is the only gene present in the duplication while CHD5, TNFRSF25 and CAMTA1 are located outside of the rearrangement. Therefore, a gene-dosage effect involving a gene located in the duplication including AJAP1 might explain the neuroblastoma observed in our patient. The rearrangement might equally interfere with the expression of a gene located outside of it (including CHD5 located 1 Mb away from the rearrangement) playing a role in the tumorigenesis. In conclusion, this study illustrates the complexity of such rearrangement characterized by array CGH and strengthens that constitutional 1p36.3 rearrangement predisposes to the development of neuroblastoma.     

Detection and delineation of an unusual 17p11.2 deletion by array-CGH and refinement of the Smith–Magenis syndrome minimum deletion to 650 kb

Smith–Magenis syndrome (SMS) is a multiple congenital anomaly/mental retardation syndrome and it is characterized by an interstitial deletion of chromosome 17p11.2. SMS patients have a distinct phenotype which is believed to be caused by haploinsufficiency of one or more genes in the associated deleted region. Five non-deletion patients with classical phenotypic features of SMS have been reported with mutations in the retinoic acid induced 1 (RAI1) gene, located within the SMS critical interval. Happloinsufficiency of the RAI1 gene is likely to be the responsible gene for the majority of the SMS features, but other deleted genes in the SMS region may modify the overall phenotype in the patients with 17p11.2 deletions. SMS is usually diagnosed in the clinical genetic setting by FISH analysis using commercially available probes. We detected a submicroscopic deletion in 17p11.2 using array-CGH with a resolution of approximately 1 Mb in a patient with the SMS phenotype, who was not deleted for the commercially available SMS microdeletion FISH probe. Delineation of the deletion was performed using a 32K tiling BAC-array, containing 32,500 BAC clones. The deletion in this patient was size mapped to 2.7 Mb and covered the RAI1 gene. This case enabled the refinement of the SMS minimum deletion to 650 kb containing eight putative genes and one predicted gene. In addition, it demonstrates the importance to investigate deletion of RAI1 in SMS patients.     

Molecular refinement of the 1p36 deletion syndrome reveals size diversity and a preponderance of maternally derived deletions

The deletion of chromosome 1p36 is a newly recognized, relatively common contiguous gene deletion syndrome with a variable phenotype. The clinical features have recently been delineated and molecular analysis indicates that the prevalence of certain phenotypic features appears to correlate with deletion size. Phenotype/genotype comparisons have allowed the assignment of certain clinical features to specific deletion intervals, significantly narrowing the regions within which to search for candidate genes. We have extensively characterized the deletion regions in 30 cases using microsatellite markers and fluorescence in situ hybridization analyses. The map order of 28 microsatellite markers spanning the deletion region was obtained by a combination of genotypic analysis and physical mapping. The deletion region was divided into six intervals and breakpoints were found to cluster in mainly two regions. Molecular analysis of the deletions showed that two patients had complex re-arrangements; these cases shared their distal and proximal breakpoints in the two common breakpoint regions. Of the de novo deletions ( n = 28) in whichparental samples were available and the analysis was informative ( n = 27), there were significantly morematernally derived deletions ( n = 21) than paternally derived deletions ( n = 6) (chi1(2) = 8.35, P < 0.0001). Phenotype/genotype correlations and refinements of critical regions in our naturally occurring deletion panel have delineated specific areas in which to focus the search for the causative genes for the features of this syndrome.      

Microduplication of Xp11.23p11.3 with effects on cognition,behavior, and craniofacial development

El‐Hattab AW, Bournat J, Eng PA, Wu JBS, Walker BA, Stankiewicz P, Cheung SW, Brown CW. Microduplication of Xp11.23p11.3 with effects on cognition, behavior, and craniofacial development. We report an ～1.3 Mb tandem duplication at Xp11.23p11.3 in an 11‐year‐old boy with pleasant personality, hyperactivity, learning and visual‐spatial difficulties, relative microcephaly, long face, stellate iris pattern, and periorbital fullness. This clinical presentation is milder and distinct from that of patients with partially overlapping Xp11.22p11.23 duplications which have been described in males and females with intellectual disability, language delay, autistic behaviors, and seizures. The duplicated region harbors three known X‐linked mental retardation genes: FTSJ1, ZNF81, and SYN1. Quantitative polymerase chain reaction from whole blood total RNA showed increased expression of three genes located in the duplicated region: EBP, WDR13, and ZNF81. Thus, over‐expression of genes in the interval may contribute to the observed phenotype. Many of the features seen in this patient are present in individuals with Williams‐Beuren syndrome (WBS). Interestingly, the SYN1 gene within the duplicated interval, as well as the STX1A gene, within the WBS critical region, co‐localize to presynaptic active zones, and play important roles in neurotransmitter release.     

Refined FISH characterization of a de novo 1p22–p36.2 paracentric inversion and associated 1p21–22 deletion in a patient with signs of 1p36 microdeletion syndrome

We report on a 10‐year‐old boy presenting with obesity, moderate mental retardation, large anterior fontanelle at birth, mild physical anomalies including mid‐face hypoplasia, deep‐set eyes, long philtrum, and small mouth. He was found to carry a paracentric inversion inv(1)(p22p36.2) associated with a 10 cM deletion at the proximal breakpoint. By YAC FISH, the boundaries of the deletion were established at IB1028 (1p21) and WI‐5166 (1p22) STSs contained in YACs 781E8 and 954F6, respectively. This large region, covering about 10 cM, contains the COL11A1 and AMY2B genes, whose haploinsufficiency does not seem to contribute significantly to the clinical phenotype. On the other hand, the patient's clinical manifestations, also including visual problems and moderate mental retardation, are those typically observed in the 1p36 deletion syndrome. Refined mapping of the telomeric 1p36.2 inversion breakpoint was obtained by FISH of a PAC contig constructed to encompass this subinterval of the 1p36 microdeletion syndrome region. PACs 1024B10 and 884E7 were found to span the breakpoint, suggesting that the clinical signs of the 1p36 microdeletion syndrome might be due to disruption of a sequence lying at 1p36.2. © 2001 Wiley‐Liss, Inc.     

Ebstein anomaly: Genetic heterogeneity and association with microdeletions 1p36 and 8p23.1

Ebstein anomaly is an uncommon congenital heart defect (CHD), characterized by downward displacement of the tricuspid valve into the right ventricle. To uncover the genetic associations with Ebstein anomaly, we have searched chromosomal imbalances using standard cytogenetic and array‐CGH analysis, and single gene conditions associated with syndromic Ebstein anomaly (with extracardiac anomalies), and screened GATA4 and NKX2.5 mutations in nonsyndromic patients (without extracardiac anomalies). Between January 1997 and September 2009, 44 consecutive patients with Ebstein anomaly were evaluated in two centers of Pediatric Cardiology. Ebstein anomaly was syndromic in 12 (27%) patients, and nonsyndromic in 32 (73%). A recognizable syndrome or complex was diagnosed by clinical criteria in seven patients. In one syndromic patient an 18q deletion was diagnosed by standard cytogenetic analysis. Array‐CGH analysis performed in 10 of the 12 syndromic patients detected an interstitial deletion of about 4 Mb at 8p23.1 in one patient, and a deletion 1pter > 1p36.32/dup Xpter‐ > Xp22.32 in another patient. In the 28 of 32 nonsyndromic patients who underwent molecular testing, no mutation in GATA4 and NKX2.5 genes were detected. We conclude that Ebstein anomaly is a genetically heterogeneous defect, and that deletion 1p36 and deletion 8p23.1 are the most frequent chromosomal imbalances associated with Ebstein anomaly. Candidate genes include the GATA4 gene (in patients with del 8p23.1), NKX2.5 (based on published patients with isolated Ebstein anomaly) and a hypothetical gene in patients with del 1p36). © 2011 Wiley‐Liss, Inc.     

Significance of the small subtelomeric area of chromosome 1 (1p36.3) in the progression of malignant melanoma: FISH deletion screening with YAC DNA probes

The short arm of chromosome 1 (1p), especially the subtelomeric region of 1p36, is a common site for abnormalities in malignant melanoma of the skin. In a recent study nodular melanomas displayed deletions of 1p36 in an augmented percentage of cases. To evaluate the dimension of these deletions and to study their significance for the progression of malignant melanoma we analyzed seven melanoma cell lines, 32 primary tumors, and 32 metastatic tumors by fluorescence in situ hybridization with the DNA probe D1Z2 in 1p36.3 and eight YAC DNA probes hybridizing to 1p36, 1p32, 1p31, and 1p21. All cell lines, 91% of the metastatic tumors and 63% of nodular melanomas showed a deletion of 1p36.3. In the YAC hybridization experiments, the most frequent deletions were found in 1p36 in all cell lines, in 13% of nodular melanoma, and in 44% of metastatic tumors. Deletions in 1p36 were mostly confined to a rather small area near the locus D1Z2. The frequent occurrence of this deletion in melanomas with a high metastatic potential and the abundant accumulation of this deletion in metastasis point to genes located on 1p36, which might be of significance for the metastatic capability of malignant melanoma. Received: 8 February 1999 / Accepted: 15 April 1999     

Molecular characterization of a 1p36 chromosomal duplication and in utero interference define ENO1 as a candidate gene for polymicrogyria

While chromosome 1p36 deletion syndrome is one of the most common terminal subtelomeric microdeletion syndrome, 1p36 microduplications are rare events. Polymicrogyria (PMG) is a brain malformation phenotype frequently present in patients with 1p36 monosomy. The gene whose haploinsufficiency could cause this phenotype remains to be identified. We used high-resolution arrayCGH in patients with various forms of PMG in order to identify chromosomal variants associated to the malformation and characterized the genes included in these regions in vitro and in vivo. We identified the smallest case of 1p36 duplication reported to date in a patient presenting intellectual disability, microcephaly, epilepsy, and perisylvian polymicrogyria. The duplicated segment is intrachromosomal, duplicated in mirror and contains two genes: enolase 1 (ENO1) and RERE, both disrupted by the rearrangement. Gene expression analysis performed using the patient cells revealed a reduced expression, mimicking haploinsufficiency. We performed in situ hybridization to describe the developmental expression profile of the two genes in mouse development. In addition, we used in utero electroporation of shRNAs to show that Eno1 inactivation in the rat causes a brain development defect. These experiments allowed us to define the ENO1 gene as the most likely candidate to contribute to the brain malformation phenotype of the studied patient and consequently a candidate to contribute to the malformations of the cerebral cortex observed in patients with 1p36 monosomy.Subject terms: Gene regulation, Genetics research     

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.     

A new microdeletion syndrome involving TBC1D24, ATP6V0C,and PDPK1 causes epilepsy,microcephaly, and developmental delay

PurposeContiguous gene deletions are known to cause several neurodevelopmental syndromes, many of which are caused by recurrent events on chromosome 16. However, chromosomal microarray studies (CMA) still yield copy-number variants (CNVs) of unknown clinical significance. We sought to characterize eight individuals with overlapping 205-kb to 504-kb 16p13.3 microdeletions that are distinct from previously published deletion syndromes.MethodsClinical information on the patients and bioinformatic scores for the deleted genes were analyzed.ResultsAll individuals in our cohort displayed developmental delay, intellectual disability, and various forms of seizures. Six individuals were microcephalic and two had strabismus. The deletion was absent in all 13 parents who were available for testing. The area of overlap encompasses seven genes including TBC1D24, ATP6V0C, and PDPK1 (also known as PDK1). Bi-allelic TBC1D24 pathogenic variants are known to cause nonsyndromic deafness, epileptic disorders, or DOORS syndrome (deafness, onychodystrophy, osteodystrophy, mental retardation, seizures). Sanger sequencing of the nondeleted TBC1D24 allele did not yield any additional pathogenic variants.ConclusionsWe propose that 16p13.3 microdeletions resulting in simultaneous haploinsufficiencies of TBC1D24, ATP6V0C, and PDPK1 cause a novel rare contiguous gene deletion syndrome of microcephaly, developmental delay, intellectual disability, and epilepsy.     

A germline deletion of p14(ARF) but not CDKN2A in a melanoma-neural system tumour syndrome family

The melanoma-astrocytoma syndrome is characterized by a dual predisposition to melanoma and neural system tumours, commonly astrocytoma. Germline deletions of the region on 9p21 containing the CDKN2A and CDKN2B genes and CDKN2A exon 1beta have been reported in kindreds, implicating contiguous tumour suppressor gene deletion as a cause of this syndrome. We describe a family characterized by multiple melanoma and neural cell tumours segregating with a germline deletion of the p14(ARF)-specific exon 1beta of the CDKN2A gene. This deletion does not affect the coding or minimal promoter sequences of either the CDKN2A or CDKN2B genes. Our results are consistent with either: (i) loss of p14(ARF) function being the critical abnormality associated with this syndrome, rather than contiguous loss of both the CDKN2A and CDKN2B genes as suggested previously; or (ii) disruption of expression of p16 by mechanisms as yet unknown.     

A fine-structure deletion map of human chromosome 11p: Analysis of J1 series hybrids

Deletion analysis offers a powerful alternative to linkage and karyotypic approaches for human chromosome mapping. A panel of deletion hybrids has been derived by mutagenizing J1, a hamster cell line that stably retains chromosome 11 as its only human DNA, and selecting for loss of MIC1,a surface antigen encoded by a gene in band 11p13. A unique, self-consistent map was constructed by analyzing the pattern of marker segregation in 22 derivative cells lines; these carry overlapping deletions of 11p13, but selectively retain a segment near the 11p telomere. The map orders 35 breakpoints and 36 genetic markers, including 3 antigens, 2 isozymes, 12 cloned genes, and 19 anonymous DNA probes. The deletions span the entire short arm, dividing it into more than 20 segments and define a set of reagents that can be used to rapidly locate any newly identified marker on 11p, with greatest resolution in the region surrounding MIC1.The approach we demonstrate can be applied to map any mammalian chromosome. To test the gene order, we examined somatic cell hybrids from five patients, whose reciprocal translocations bisect band 11p13; these include two translocations associated with familial aniridia and two with acute T-cell leukemia. In each patient, the markers segregate in telomeric and centromeric groups as predicted by the deletion map. These data locate the aniridia gene (AN2)and a recurrent T-cell leukemia breakpoint (TCL2)in the marker sequence, on opposite sides of MIC1.To provide additional support, we have characterized the dosage of DNA markers in a patient with Beckwith-Wiedemann syndrome and an 11p15-11pter duplication. Our findings suggest the following gene order: TEL-(HRAS1, MER2, CTSD, TH/INS/IGF2, H19, D11S32)-(RRM1, D11S1, D11S25, D11S26)-D11S12-(HBBC, D11S30)-D11S20-(PTH, CALC)-(LDHA, SAA, TRPH, D11S18, D11S21)-D11S31-D11S17-HBVS1-(FSHB, D11S16)-AN2-MIC1-TCL2-J-CAT-MIC4-D11S9-D11S14-ACP2-(D11S33, 14L)-CEN.We have used the deletion map to show the distribution on 11p of two centromeric repetitive elements and the low-order interspersed repeat A36Fc.Finally, we provide evidence for an allelic segregation event in the hamster genome that underlies the stability of chromosome 11 in J1. The deletion map provides a basis to position hereditary disease loci on 11p, to distinguish the pattern of recessive mutations in different forms of cancer and, since many of these genes have been mapped in other mammalian species, to study the evolution of a conserved syntenic group.Deceased.