Phenomenon of selective staining of pericentromeric heterochromatin regions in chromosomes from spontaneously dividing cells by the acridine orange fluorochrome

A novel phenomenon of unusual selective acridine orange (AO) staining of pericentromeric heterochromatin regions (HRs) in chromosomal preparations from tissue with known spontaneous mitotic activity (chorionic villi, placenta, embryonic tissues, bone marrow, and testes), as well as embryonic stem cells, is described. Staining with 0.01% AO in a citric-phosphate (pH 5.5) or sodium phosphate (pH 7.0) buffer solution allows the HRs of human chromosomes (1q12, 9q12, 13p11.2, 14p11.2, 15p11.2, 16q11.2, 21p11.2, 22p11.2, and Yq12) and pericentromeric HRs of mouse chromosomes to be reliably detected by the red fluorescence of AO. This method of AO staining does not require any pretreatment. Explanations for metachromatic AO staining of polymorphic pericentromeric HRs in chromosomes of spontaneously dividing cells are suggested. A high reproducibility of the specific AO staining makes it possible to suggest its using as a reliable quick method for detection of polymorphic HRs of human chromosomes in cytogenetic prenatal diagnosis and oncohematology.     

Genetic mapping of autosomal dominant Charcot-Marie-Tooth disease in a large French-Acadian kindred: identification of new linked markers on chromosome 17.

We have performed linkage analysis in a large French-Acadian kindred segregating one form of autosomal dominant Charcot-Marie-Tooth disease (CMTD) (type IA) using 17 polymorphic DNA markers spanning human chromosome 17 and demonstrate linkage to several markers in the pericentromeric region, including DNA probes pA10-41, EW301, S12-30, pTH17.19, c11-2B, and p11-2c11.5. Linkage of markers pA10-41 and EW301 to CMTD type IA has been reported elsewhere. Four new markers, 1516, 1517, 1541, and LL101, which map to chromosome 17 have been identified. The marker 1516 appears to be closely linked to the CMTD locus on chromosome 17 as demonstrated by a maximum lod score of 3.42 at theta (recombination fraction) = 0. This marker has been mapped to 17p11.2 using a somatic cell hybrid constructed from a patient with Smith-Magenis syndrome [46,XY, del(17)(p11.2p11.2)]. A lod score of 6.16 has been obtained by multipoint linkage analysis with 1516 and two markers from 17q11.2, pTH17.19, and c11-2B. The markers 1517 and 1541 have been mapped to 17p12-17q11.2 and demonstrate maximum lod scores of 2.35 and 0.63 at recombination values of .1 and .2, respectively. The marker LL101 has been mapped to 17p13.105-17p13.100 and demonstrates a maximum lod score of 1.56 at a recombination value of .1. Our study confirms the localization of CMTD type IA to the pericentromeric region of chromosome 17.     

Spatial topography of a pericentromeric region (1q12) in hemopoietic cells studied by in situ hybridization and confocal microscopy

A fluorescent in situ hybridization procedure with a chromosome 1-specific (1q12) repetitive satellite DNA probe was used to label the 1q12 regions of the chromosomes 1 in spherical and polymorphic hemopoietic cell nuclei. The entire procedure was performed in suspension to preserve nuclear morphology. The result was studied by three-dimensional analysis, as provided by a scanning laser confocal microscope. The 1q12 regions of chromosome 1 were measured to be closely associated with the nuclear envelope in isolated nuclei of unstimulated diploid human lymphocytes. The relative positions to each other in the periphery of these spherical nuclei could not be distinguished from a random distribution pattern. In the diploid and tetraploid polymorphic nuclei of cells of the promyelocytic leukemia cell line HL60 these pericentromeric sequences were also associated with the nuclear surface.     

Molecular characterization of "inverted" pericentromeric heterochromatin of chromosome 3.

Inversion of the pericentromeric region of human chromosome 3 [inv (3) (p11q11.2)] is a rare event. Initially, this inversion was identified with staining for Q-bands by fluorescence using quinacrine (QFQ) and later characterized with staining for C-bands by CBG technique. The molecular methods of fluorescence in situ hybridization (FISH) and AluI/Giemsa and TaqI/Giemsa techniques were utilized. The findings suggest that the variable band q11.2 on chromosome 3 contains alphoid DNA sequences, which appear to be similar to those identified by conventional methods in the centromeric region (band p11).     

Molecular characterization of “inverted” pericentromeric heterochromatin of chromosome 3

Summary Inversion of the pericentromeric region of human chromosome 3 [inv (3) (p11q11.2)] is a rare event. Initially, this inversion was identified with staining for Q-bands by fluorescence using quinacrine (QFQ) and later characterized with staining for C-bands by CBG technique. The molecular methods of fluorescence in situ hybridization (FISH) and AluI/Giemsa and TaqI/Giemsa techniques were utilized. The findings suggest that the variable band q11.2 on chromosome 3 contains alphoid DNA sequences, which appear to be similar to those identified by conventional methods in the centromeric region (band p11).     

A cluster of expressed zinc finger protein genes in the pericentromeric region of human chromosome 10.

Three members of the human zinc finger Krüppel family, ZNF11/KOX2, ZNF22/KOX15, and ZNF25/KOX19, have been regionally localized to the pericentromeric region of chromosome 10 by in situ chromosomal hybridization and somatic cell hybrid analysis. ZNF25/KOX19 is located centromeric to a breakpoint in chromosome band 10q11.2 in the chromosome region 10p11.2-q11.2, whereas ZNF22/KOX15 maps distal to it in band 10q11.2. Sequences hybridizing to the KOX2 probe are found at two loci, ZNF11A and ZNF11B, that map proximal and distal to the 10q11.2 breakpoint, respectively. The two ZNF11 loci probably represent two related sequences in 10p11.2-q11.2. This cluster of ZNF/KOX genes is of particular interest since the loci for multiple endocrine neoplasia type 2A and 2B (MEN2A and MEN2B) syndromes have been assigned to this region by linkage analysis.     

Prenatal diagnosis and molecular cytogenetic characterization of an unusual complex structural rearrangement in a pregnancy following intracytoplasmic sperm injection (ICSI).

We report on a balanced complex chromosomal aberration detected in a fetus after amniocentesis. The pregnancy was achieved after intracytoplasmic sperm injection. GTG-banding revealed a complex structurally rearranged karyotype with a translocation between chromosomes 5 and 15 and an additional paracentric inversion in the der(15) between bands 5q11.2 and 5q15. Ag-NOR staining showed an interstitial active nuclear organizer region in the der(15). Molecular cytogenetic analyses using whole-chromosome-painting probes, comparative genomic hybridization, and multicolor banding did not point to further structural aberrations or imbalances. Therefore, a complex rearrangement with three breakpoints has occurred, and the karyotype can be described as 46,XX,der(5)t(5;15) (q11.2;p12),der(15)t(5;15)(q11.2;p12)inv(5)(q11.2q15).     

Regional mapping panel for human chromosome 17: Application to neurofibromatosis type 1

A somatic cell hybrid mapping panel was constructed to localize cloned DNA sequences to any of 15 potentially different regions of human chromosome 17. Relatively high-resolution mapping is possible for 50% of the chromosome length in which 12 breakpoints are distributed over approximately 45 megabases, with an average spacing estimated at 1 breakpoint every 2-7 megabases. This high-resolution capability includes the pericentromeric region of 17 to which von Recklinghausen neurofibromatosis (NF1) has recently been mapped. Using 20 cloned genes and anonymous probes, we have tested the expected order and location of panel breakpoints and confirmed, refined, or corrected the regional assignment of several cloned genes and anonymous probes. Four markers with varying degrees of linkage to NF1 have been physically localized and ordered by the panel: the loosely linked markers myosin heavy chain 2 (25 cM) to p12----13.105 and nerve growth factor receptor (14 cM) to q21.1----q23; the more closely linked pABL10-41 (D17S71, 5 cM) to p11.2; and the tightly linked pHHH202 (D17S33) to q11.2-q12. Thus, physical mapping of linked markers confirms a pericentromeric location of NF1 and, along with other data, suggests the most likely localization is proximal 17q.     

A third neurofibromatosis type 1 (NF1) pseudogene at chromosome 15q11.2

Sequences related to the neurofibromatosis type 1 (NF1) gene have been identified on several human chromosomes. In the centromeric region of chromosomes 14 and 15, two NF1 pseudogenes have been described. Sequence comparison between NF1-related exons amplified from two yeast artificial chromosome clones hybridizing to chromosomal region 15q11.2 and published NF1-related sequences localized at 15q11.2 suggested that a third NF1 pseudogene resides in this chromosomal region. The previous localization of an NF1-related locus to the telomeric part of chromosome 15 could not be confirmed by us. Our findings further support pericentromeric spreading of partial NF1 gene copies at chromosome 15q11.2 during evolution. Received: 27 January 1996 / Accepted: 26 May 1997     

Human chromosomes 9, 12, and 15 contain the nucleation sites of stress-induced nuclear bodies

We previously reported the identification of a novel nuclear compartment detectable in heat-shocked HeLa cells that we termed stress-induced Src-activated during mitosis nuclear body (SNB). This structure is the recruitment center for heat shock factor 1 and for a number of RNA processing factors, among a subset of Serine-Arginine splicing factors. In this article, we show that stress-induced SNBs are detectable in human but not in hamster cells. By means of hamster>human cell hybrids, we have identified three human chromosomes (9, 12, and 15) that are individually able to direct the formation of stress bodies in hamster cells. Similarly to stress-induced SNB, these bodies are sites of accumulation of hnRNP A1-interacting protein and heat shock factor 1, are usually associated to nucleoli, and consist of clusters of perichromatin granules. We show that the p13-q13 region of human chromosome 9 is sufficient to direct the formation of stress bodies in hamster>human cell hybrids. Fluorescence in situ hybridization experiments demonstrate that the pericentromeric heterochromatic q12 band of chromosome 9 and the centromeric regions of chromosomes 12 and 15 colocalize with stress-induced SNBs in human cells. Our data indicate that human chromosomes 9, 12, and 15 contain the nucleation sites of stress bodies in heat-shocked HeLa cells.     

A refined linkage map for DNA markers around the pericentromeric region of chromosome 10

A refined genetic linkage map for the pericentromeric region of human chromosome 10 has been constructed from data on 12 distinct polymorphic DNA loci as well as the locus for multiple endocrine neoplasia type 2A (MEN 2A), a dominantly inherited cancer syndrome. The map extends from D10S24 (at 10p13-p12.2) to D10S3 (at 10q21-q23) and is about 70 cM long. Overall, higher female than male recombination frequencies were observed for this region, with the most remarkable female excess in the immediate vicinity of the centromere, as previously reported. Most of the DNA markers in this map are highly informative for linkage and the majority of the interlocus intervals are no more than 6 cM apart. Thus this map should provide a fine framework for future efforts in more detailed mapping studies around the centromeric area. A set of ordered cross-overs identified in this work is a valuable resource for rapidly and accurately localizing new DNA clones isolated from the pericentromeric region.     

Peculiarities of metaphase chromosome methylation pattern in preimplantation human embryos

Methylation pattern peculiarities revealed by immunocytochemical analysis of metaphase chromosomes from preimplanted human embryos with monoclonal antibodies against 5-methylcytosine are described. Chromosomes of 2-8-cell triploid human embryos are undermethylated, if compared to those from PHA-stimulated fetal cord blood lymphocytes. Hemimethylation (asymmetric labeling of sister chromatids) is typical for the most of embryonic chromosomes at 2-cell--blastocyst stages due most probably to a passive loss of methylation during initial cleavages. Diffuse labeling and sister chromatid exchanges are two other cytogenetic peculiarities revealed by immunofluorescent staining of early human embryos. Hypomethylation of pericentromeric heterochromatin of chromosomes 1, 9, 16 and different methylation status of some homologous chromosomes may distinguish them from metaphase chromosomes of lymphocytes. M-banding pattern typical for chromosomes from adult and cord blood lymphocytes initially appears in embryonic metaphase chromosomes as early as at a 8-cell stage to be established for most part of chromosomes of the karyotype at the morula-blastocyst stage only.     

The genetic defect in multiple endocrine neoplasia type 2A maps next to the centromere of chromosome 10

Multiple endocrine neoplasia type 2A (MEN2A) is a rare cancer syndrome that is inherited in an apparently autosomal dominant fashion. Previous linkage studies had assigned the MEN2A locus to chromosome 10 in the pericentromeric region. We recently have described several new easily scorable RFLPs for the chromosome 10-specific alpha satellite DNA (the D10Z1) locus that is known, on the basis of previous in situ hybridization experiments, to lie at the centromere. We report here tight linkage between MEN2A and D10Z1, as demonstrated by a maximum lod score of 12.02 at the recombination frequency of zero (1-lod-unit support interval 0-4 cM), indicating that the genetic defect in MEN2A lies in the immediate vicinity of the centromere. By means of a set of ordered polymorphic DNA markers from the pericentromeric region, multipoint as well as pairwise linkage analyses place the MEN2A locus at the middle of a small region (approximately 11 cM) bracketing the centromere with FNRB (at 10p11.2) and RBP3 (at 10q11.2) on either side, providing further support for the centromeric location of the MEN2A locus. Marked sex difference in recombination frequencies exists in this pericentromeric region: significantly (P less than .01) more female than male crossovers were observed across all of the adjacent intervals D10S24-FNRB, FNRB-D10Z1, and D10Z1-RBP3. However, a sex difference was not seen in the 7-cM interval from RBP3 to D10S5, suggesting that large variation in the sex difference in recombination can occur over small chromosomal regions.(ABSTRACT TRUNCATED AT 250 WORDS)     

Conservation of pericentromeric duplications of a 200-kb part of the human 21q22.1 region in primates

We analyzed the conservation of large paralogous regions (more than 200 kb) on human chromosome regions 21q22.1 and 21q11.2 and on pericentromeric regions of chromosomes 2, 13, and 18 in three nonhuman primate species. Orthologous regions were found by FISH analysis of metaphase chromosomes from Gorilla gorilla, Pan troglodytes, and Pongo pygmaeus. Only one orthologous region was detected in chromosomes of P. pygmaeus, showing that the original locus was at 21q22.1 and that the duplication arose after the separation of Asian orangutans from the other hominoids. Surprisingly, the paralogous regions were more highly conserved in gorilla than in chimpanzee. PCR amplification of STSs derived from sequences of the chromosome 21 loci and low-stringency FISH analysis showed that this duplication occurred recently in the evolution of the genome. Different rates of sequence evolution through substitutions or deletions, after the duplication, may have resulted in diversity between closely related primates.     

Unique sequence homology in the pericentromeric regions of the long arms of chromosomes 13 and 21.

We previously isolated two polymorphic chromosome 21q probes, pVC1.21c (D21S190) and pVC1.34a (D21S149), localized in 21qcen-21q21.2. In addition, pVC1.21c recognized a sequence in 21q22.1-q22.2 and both probes cross-hybridized with non-chromosome-21 sequences. In this study we refined the proximal 21q locations of probes pVC1.21c and pVC1.34a to 21q11.1 and demonstrated that they recognize sequences on chromosome 13 but not on chromosomes 14, 15, and 22. Furthermore, the polymorphisms associated with the two loci were assigned to pericentromeric 13q for pVC1.34a and distal 21q for pVC1.21c. Our results are indicative of a region of unique sequence homology in the pericentromeric region of the long arms of chromosomes 13 and 21.     

Possible mapping of the gene for transient myeloproliferative syndrome at 21q11.2

Summary The parental origin of the extra chromosome 21 was studied in 20 patients with trisomy 21-associated transient myeloproliferative syndrome (TMS) using chromosomal heteromorphisms as markers; this was combined with a study of DNA polymorphisms in 5 patients. Of these, 10 were shown to result from duplication of a parental chromosome 21, viz., maternal in 8 and paternal in 2. A patient with Down syndrome-associated TMS had a paracentric inversion in two of his three chromosomes 21 [47,XY,-21, +inv(21)(q11.2q22.13)mat, +inv(21)(q11.2 q22.13)mat). These findings support our hypothesis of disomic homozygosity of a mutant gene on chromosome 21 in 21-trisomic cells as being a mechanism responsible for the occurrence of TMS. The finding also suggests that the putative TMS gene locus is at either 21q11.2 or 21q22.13, assuming that the gene is interrupted at either site because of the inversion. The study of 5 TMS patients using DNA polymorphic markers detected a cross-over site on the duplicated chromosomes 21 between 21q11.2 (or q21.2) and 21q21.3 in one patient, and a site between 21q21.3 and q22.3 in another patient, evidence that confined the gene locus to the 21cen-q21.3 segment. These findings suggest that the putative TMS gene is located at 21q11.2. The extra chromosome 21 in the latter two TMS patients probably resulted from maternal second meiotic non-disjunction, in view of the presence of recombinant heterozygous segments on their duplicated chromosomes 21.     

Using a pericentromeric interspersed repeat to recapitulate the phylogeny and expansion of human centromeric segmental duplications

Despite considerable advances in sequencing of the human genome over the past few years, the organization and evolution of human pericentromeric regions have been difficult to resolve. This is due, in part, to the presence of large, complex blocks of duplicated genomic sequence at the boundary between centromeric satellite and unique euchromatic DNA. Here, we report the identification and characterization of an approximately 49-kb repeat sequence that exists in more than 40 copies within the human genome. This repeat is specific to highly duplicated pericentromeric regions with multiple copies distributed in an interspersed fashion among a subset of human chromosomes. Using this interspersed repeat (termed PIR4) as a marker of pericentromeric DNA, we recovered and sequence-tagged 3 Mb of pericentromeric DNA from a variety of human chromosomes as well as nonhuman primate genomes. A global evolutionary reconstruction of the dispersal of PIR4 sequence and analysis of flanking sequence supports a model in which pericentromeric duplications initiated before the separation of the great ape species (>12 MYA). Further, analyses of this duplication and associated flanking duplications narrow the major burst of pericentromeric duplication activity to a time just before the divergence of the African great ape and human species (5 to 7 MYA). These recent duplication exchange events substantially restructured the pericentromeric regions of hominoid chromosomes and created an architecture where large blocks of sequence are shared among nonhomologous chromosomes. This report provides the first global view of the series of historical events that have reshaped human pericentromeric regions over recent evolutionary time.     

Plasticity of human chromosome 3 during primate evolution

Comparative mapping of more than 100 region-specific clones from human chromosome 3 in Bornean and Sumatran orangutans, siamang gibbon, and Old and New World monkeys allowed us to reconstruct ancestral simian and hominoid chromosomes. A single paracentric inversion derives chromosome 1 of the Old World monkey Presbytis cristata from the simian ancestor. In the New World monkey Callithrix geoffroyi and siamang, the ancestor diverged on multiple chromosomes, through utilizing different breakpoints. One shared and two independent inversions derive Bornean orangutan 2 and human 3, implying that neither Bornean orangutans nor humans have conserved the ancestral chromosome form. The inversions, fissions, and translocations in the five species analyzed involve at least 14 different evolutionary breakpoints along the entire length of human 3; however, particular regions appear to be more susceptible to chromosome reshuffling. The ancestral pericentromeric region has promoted both large-scale and micro-rearrangements. Small segments homologous to human 3q11.2 and 3q21.2 were repositioned intrachromosomally independent of the surrounding markers in the orangutan lineage. Breakage and rearrangement of the human 3p12.3 region were associated with extensive intragenomic duplications at multiple orangutan and gibbon subtelomeric sites. We propose that new chromosomes and genomes arise through large-scale rearrangements of evolutionarily conserved genomic building blocks and additional duplication, amplification, and/or repositioning of inherently unstable smaller DNA segments contained within them.     

Genomic organization and chromosomal localization of the mouse protein kinase C alpha gene

In Chinese hamster extended blocks of telomeric-like repeats were previously detected by in situ hybridization at the pericentromeric region of most chromosomes and short arrays were localized at several interstitial sites. In this work, we analyzed the molecular organization of internal telomeric sequences (ITs) in the Chinese hamster genome. In genomic transfers hybridized with a telomeric probe, multiple Bal31 insensitive fragments were detected. Most of the fragments ranged in size between less than 1 kb and more than 100 kb and some were polymorphic. Fluorescence in situ hybridization experiments on DNA fibers and on elongated chromosomes showed that the pericentromeric ITs are composed of extensive and essentially continuous arrays of telomeric-like sequences. We then isolated three genomic regions which contain short ITs. These ITs are localized at interstitial sites (3q13-15, 3q21-26, 1p26) and are composed of 29-126 bp of (TTAGGG)(n) repeats. A peculiar feature of all the three ITs is the AT richness of the flanking sequences. Since AT-rich DNA is known to be unstable and characteristic of several mammalian fragile sites, we propose that the three ITs were inserted at these sites during the repair of double strand breaks.