Translocation t(11;14) and trisomy 11q13----qter in multiple myeloma

A 14q+ marker with extra material derived from chromosome 11 long arm, i.e. segment q13----qter, has been found in cells from a pleural effusion in a patient with highly malignant multiple myeloma. The segment 11q13----qter was trisomic because of the presence of both apparently normal homologous chromosomes 11.     

Double autosomal trisomy (1q21.2----qter and 14pter----q13) in a female fetus with nuchal oedema

In this report we describe the prenatal diagnosis of a double autosomal trisomy (1q21.2----qter and 14pter----q13) in a female fetus with nuchal oedema, microphthalmia of the left eye and craniofacial dysmorphism. Cytogenetic examination of the parents revealed an autosomal reciprocal 1q/14q translocation with karyotype: 46,XX,t(1;14)(q21.2;q13) in the mother.     

Localization of 11q13 loci with respect to regional chromosomal breakpoints

We have employed two strategies to map 13 markers located at 11q13. First, we used pulsed-field gel electrophoresis of DNA fragments obtained with methylation-sensitive restriction enzymes. The markers used in this study were scattered over 8.4 Mb and, for most of them, could not be linked one to another. A second mapping strategy employed hybridization to either DNA of somatic hybrids containing various parts of the long arm of chromosome 11 or metaphase chromosomes of a B-cell line containing the t(11;14)(q13;q32) translocation. We were able to sort out the centromeric from the telomeric probes with respect to translocation breakpoints taken as reference chromosomal landmarks by this approach. BCL1, which corresponds to the region where the t(11;14)(q13;q32) translocation breakpoints are clustered, appears as a boundary between two areas of human/mouse homology present in conserved syntenic regions on mouse chromosomes 7 and 19.     

Interstitial deletion of long arm of chromosome 13

The case is presented of a patient with the karyotype 46,XX,del(13q)(pter----q22::q32----qter) confirmed by densitometry and a phenotype of mental and growth deficiency, hypotonia, hypertelorism, ptosis, broad nasal bridge, protruding upper incisors, short neck, dislocation of the hip, hypoplasia of the thumbs, fusion of fourth and fifth metacarpal bones and syndactyly of toes. The findings are compared with those of well documented cases with a similar deleted segment of the long arm of chromosome 13. Although it seems obvious that a clinical syndrome for the distal deletion 13q appears to exist more studies with banded chromosomes are needed.     

Partial trisomy 13q22----qter. A new case

A newborn male patient with a partial trisomy 13q22----qter, derived from a maternal translocation (13;15)(q22;p11) is reported. This non-frequent chromosomal anomaly leads to a characteristic phenotype easily recognizable from other craniosynostosis syndromes, in which the cranial malformation is often associated with auricular and limb defects. This phenotype includes: cranial malformation, characteristic facies, mental and developmental retardation, urologic and genital anomalies, polydactily, abnormal muscular tonicity and convulsive status. Our patient, a "pure" partial trisomy, without other associated chromosomal anomaly, is compared with the published cases.     

Partial trisomy 18(q11 leads to qter) in an infant and aborted fetus resulting from a balanced paternal translocation t(13;18)(q32:q11).

Partial trisomy 18 is described in a two month old female with severe mental, motor and growth retardation, associated with multiple congenital anomalies characteristic of complete trisomy 18. Trisomy for almost all of 18q resulted from adjacent I segregation of a paternally inherited translocation t(13; 18)(q32:q11). The balanced translocation was observed in three generations of the family. Partial trisomy 18q identical to that observed in the proband was found in a subsequent miscarriage.     

TPA stimulation culture for improved detection of t(11;14)(q13;q32) in mantle cell lymphoma

Cytogenetic analysis of mantle cell lymphoma (MCL), characterized by the presence of t(11;14)(q13;q32) translocation, is often difficult because of the low proliferating rate of MCL cells and the presence of normal cells in bone marrow which may interfere with growth of MCL cells. We describe herein a TPA (12-O-tetradecanoylphorbol 13-acetate) stimulated culture to improve detection of t(11;14)(q13;q32) in 20 MCL patients regardless of the samples used.     

Inherited pericentric inversion of chromosome no. 2 with Robertsonian translocation (13q 14q) resulting in trisomy for chromosome 13q

This report includes a patient with an inherited pericentric inversion of chromosome No. 2 in addition to a Robertsonian translocation resulting in trisomy for chromosome 13q. The chromosomal constitution of the proband was 46,XX,inv(2) (pter leads to p11 : : q14 leads to p11 : : q14 leads to qter); t(13,14) (13qter leads to 13p11 : : 14q11 leads to 14qter). Sequential QFQ, RFA and GTG banding techniques were employed on the chromosomes of all family members. The chromosomal constitutions of the father and his first child were normal while the mother had an inversion of chromosome No. 2 [46,XX,inv(2) (pter leads to p11 : : q14 leads to p11 : : q14 leads to qter)]. The proband inherited this abnormal chromosome. In addition, she had a de novo Robertsonian translocation involving chromosomes 13q and 14q resulting in trisomy of chromosome 13q.     

Duplication 11 (q22----qter) in an infant. A case report with review

A male infant with partial duplication of the long arm of chromosome 11 (11q22----qter) is described with a hitherto unreported translocation. In most cases 11q trisomy is associated with 11q/22q translocation and a 3:1 meiotic disjunction with 47 chromosomes. In a few cases the 11q translocation is associated with a partial deletion of other autosomes and a total of 46 chromosomes. In the present case, translocation to 9p is involved and no apparent deletion of 9p was noted, providing an opportunity to delineate the phenotypic features due to duplication of 11q. A comparison is made between the findings of partial 11q trisomy and 11q/22q translocation.     

Mesomelic form of chondrodysplasia and congenital glaucoma associated with de novo translocation (13;18)(q14;q23)

Mesomelic form of chondrodysplasia and congenital glaucoma associated with de novo translocation (13;18)(q14:q23): Mesomelic dysplasias are characterized by limb shortening most prominent of the middle segment of the extremities (forearm and lower leg). In addition to several syndromic forms a few patients with sporadic or familial forms and without precise nosological classification have been reported so far. In this report we present a young female with disproportionate mesomelic dwarfism, dysmorphic facial features, bilateral glaucoma, patent ductus arteriosus, low and hoarse voice, and generalized muscular hypotonia. At the age of 2.5 years mental development is normal. High resolution G-banded chromosome studies revealed a de novo reciprocal translocation with karyotype 46,XX t (13;18)(q14;q23). The concurrence of this de novo autosomal translocation with this distinct phenotype supports the hypothesis that disruption of (a) gene(s) at the translocation breakpoints causes this unusual, apparently new form of skeletal chondrodysplasia.     

The gene for clotting factor 10 is mapped to 13q32----qter

The structural gene for the human clotting factor 10 (F10) has been mapped to chromosome 13 with a cDNA probe hybridized to DNAs from a panel of human X hamster hybrids. In situ hybridization was used to assign F10 to region 13q32----qter of chromosomes from normal human lymphocytes.     

Molecular cytogenetic characterization of 17 rob(13q14q) Robertsonian translocations by FISH, narrowing the region containing the breakpoints.

We have characterized 17 rob(13q14q) Robertsonian translocations, using six molecular probes that hybridize to the repetitive sequences of the centromeric and shortarm regions of the five acrocentric chromosomes by FISH. The rearrangements include six de novo rearrangements and the chromosomally normal parents, five maternally and three paternally inherited translocations, and three translocations of unknown origin. The D21Z1/D13Z1 and D14Z1/D22Z1 centromeric alpha-satellite DNA probes showed all rob(13q14q) chromosomes to be dicentric. The rDNA probes did not show hybridization on any of the 17 cases studied. The pTRS-47 satellite III DNA probe specific for chromosomes 14 and 22 was retained around the breakpoints in all cases. However, the pTRS-63 satellite III DNA probe specific for chromosome 14 did not show any signals on the translocation chromosomes examined. In 16 of 17 translocations studied, strong hybridization signals on the translocations were detected with the pTRI-6 satellite I DNA probe specific for chromosome 13. All parents of the six de novo rob(13q14q), including one whose pTRI-6 sequence was lost, showed strong positive hybridization signals on each pair of chromosomes 14 and 13, with pTRS-47, pTRS-63, and pTRI-6. Therefore, the translocation breakpoints in the majority of rob(13q14q) are between the pTRS-47 and pTRS-63 sequences in the p11 region of chromosome 14 and between the pTRI-6 and rDNA sequences within the p11 region of chromosome 13.     

Uniparental heterodisomy for chromosome 14 in a phenotypically abnormal familial balanced 13/14 Robertsonian translocation carrier.

A 9-year-old mentally retarded girl with multiple congenital anomalies was found to carry a balanced 13/14 Robertsonian translocation [45,XX,t(13q14q)] which was also present in her father. Her mother carried a balanced reciprocal translocation between chromosomes 1 and 14 [46,XX,t(1;14) (q32;q32)]. Both of her parents were phenotypically normal. Molecular studies were carried out to determine the parental origin of chromosomes 1, 13, and 14 in the patient. Using probes for D14S13 and D14S22, we could show that the patient inherited both chromosomes 14 from her father and none from her mother. Similar studies using probes for chromosomes 1 (D1S76) and 13 (D13S37) loci showed the presence of both maternal and paternal alleles in the patient. Our findings indicate that paternal uniparental heterodisomy for chromosome 14 most likely accounts for the phenotypic abnormalities observed in our patient. It is suggested that uniparental disomy may be the basis for abnormal development in at least some phenotypically abnormal familial balanced-translocation carriers.     

Trisomy 15q23----qter due to a de novo t(11;15)(q25;q23) and assignment of the critical segment

A 10 10/12-year-old boy with a de novo t(11;15)(q25;q23) leading to trisomy 15q23----qter was studied. The clinical features were compatible with other cases of distal trisomy 15q. The critical segment for this trisomy is tentatively assigned to bands 15q25----qter.     

T-lymphocytes with 7;14 translocations: frequency of occurrence, breakpoints, and clinical and biological significance.

Among 11,915 consecutive patients and 37 normal controls who had chromosome analysis at the Mayo Clinic between 1978 and 1984, 83 had a single sporadic metaphase with a 7;14 translocation. In 81 of the translocations, the breakpoints were at 14q11 and either 7q34 (type I) or 7p13 (type II): type I translocations occurred in 42 patients, and type II, in 39. The two other translocations had different breakpoints: one was t(7;14)(q11;q32), and the other was t(7;14)(p13;q32). All type I and type II translocations occurred in phytohemagglutinin-stimulated lymphocyte cultures; their combined incidence was 4.88 X 10(-4) per metaphase (81 of 165,991 metaphases) in such cultures. No type I or II translocation was found among 6,713 fibroblast metaphases, 33,463 amniocyte metaphases, or 68,972 bone marrow and unstimulated peripheral blood metaphases. One variant 7;14 translocation occurred in a phytohemagglutinin-stimulated culture, and the other occurred in a fibroblast culture. We did not find a correlation of sporadic 7;14 translocations with any month or season of the year or with patient age or sex. Of the 83 patients, 78 had various clinical disorders, three had ataxia-telangiectasia, one was a normal control, and one was an artificial insemination donor. Follow-up studies on 64 (77%) patients indicate that, to date, none have developed any malignant process subsequent to chromosome analysis. Except for ataxia-telangiectasia, the occurrence of types I and II translocations in lymphocyte cultures may have little, if any, clinical significance. The biological significance of these translocations may be the association of genes in chromosome bands 14q11, 7p13, and 7q34 with the normal physiology of lymphocytes such as the alpha- and beta-chains for T-cell antigen receptor.     

A paternal balanced translocation [t(7;22)(q32;q13.3)] leading to reciprocal unbalanced karyotypes in two consecutive pregnancies

A family is reported in which a man with a balanced reciprocal translocation [46,XY,t(7;22)(q32;q13.3)] fathered a daughter who was trisomic for the region 7q32----7qter and monosomic for 22q13.3----22qter, and a male fetus who was monosomic for 7q32----qter and trisomic for 22q13.3----22qter. The meiotic segregation of this translocation, as well as the phenotypes of the unbalanced offspring, are discussed.     

Mosaic 13 trisomy due to de novo 13/13 translocation with subsequent fission karyotype: 46,XX,-13,+t(13;13)(p11;q11)/46,XX,del(13)(p11)

Summary A severely retarded child with multiple malformations was found to present a mosaic karyotype 46,XX,-13,+t(13;13)(p11;q11)/46,XX,del (13)(p11), which probably originated as the result of a de novo 13/13 translocation in a parental gamete, followed by postzygotic fission of the translocation chromosomse.     

A t(X;15)(q23;q25) with Xq reactivation in a lymphoblastoid cell line from Fanconi anemia.

A t(X:15)(q23;q25) was detected during cytogenetic investigation of a lymphoblastoid cell line established from a female patient with Fanconi anemia. The translocation was apparently balanced at passage 300 and unbalanced at passage 13. A chromatid exchange between both the normal and the der(15), between the centromere and band 15q25, may explain these results. Replication studies, following BrdU incorporation, indicate that the segment Xq23----qter from the der(15) is early replicating whereas segment Xpter----q23 from the der(X) is late replicating. Since the normal X was early replicating, it is concluded that the segment of the long arm of chromosome X, separated from its inactivation center by the translocation, was reactivated. This interpretation is confirmed by the methylation patterns of the hypoxanthine phosphoribosyltransferase gene (HPRT), mapped on Xq26, which corresponds to that of an active gene, whereas that of phosphoglycerate kinase (PGK1), which remained on the der(X), corresponds to that of an inactive gene. This is the first example of reactivation of a segment of the X chromosome following a structural rearrangement in somatic cells.     

Retinoblastoma in a boy with a de novo mutation of a 13/18 translocation: The assumption that the retinoblastoma locus is at 13q141, particularly at the distal portion of it

Summary In serial cytogenetic examinations of peripheral lymphocytes from retinoblastoma patients, we found a patient with sporadic bilateral retinoblastoma with a de novo mutation of a 13/18 translocation, with their respective breakpoints at 13q141 and 18q122. The simultaneous de novo occurrence of retinoblastoma and the chromosomal rearrangement involving 13q14 in the proband suggests that the gene locus for retinoblastoma is at 13q141, particularly at the distal portion of it. Deletion mapping data are compatible with this suggestion.     

Mapping of Aldose Reductase Gene Sequences to Human Chromosomes 1, 3, 7, 9, 11, and 13

Aldose reductase (alditol:NAD(P)+ 1-oxidoreductase; EC 1.1.1.21) (AR) catalyzes the reduction of several aldehydes, including that of glucose, to the corresponding sugar alcohol. Using a complementary DNA clone encoding human AR, we mapped the gene sequences to human chromosomes 1, 3, 7, 9, 11, 13, 14, and 18 by somatic cell hybridization. By in situ hybridization analysis, sequences were localized to human chromosomes 1q32-q42, 3p12, 7q31-q35, 9q22, 11p14-p15, and 13q14-q21. As a putative functional AR gene has been mapped to chromosome 7 and a putative pseudogene to chromosome 3, the sequences on the other seven chromosomes may represent other active genes, non-aldose reductase homologous sequences, or pseudogenes.