AML1, AML2, and AML3, the human members of the runt domain gene-family: cDNA structure, expression, and chromosomal localization

cDNAs corresponding to three human runt domain containing genes, AML1, AML2, and AML3, were isolated and characterized. In addition to homology in the highly conserved runt domain, extensive sequence similarities were also observed in other parts of the proteins. All three carried an identical, putative ATP binding site -GRSGRGKS-, and their C-terminal halves were particularly rich in proline and serine residues. While AML1 cDNAs were cloned by others, AML2 represents a new member, not previously described, of the runt domain gene family, and AML3 was identified as the human homologue of mouse PEB-P2 alpha A. The chromosomal location of AML1 to chromosome 21q22 was confirmed, while AML2 and AML3 were mapped to chromosome regions 1p36 and 6p21, respectively. Analysis of AML1 and AML2 expression in hematopoietic cell lines revealed a distinct pattern of expression.

Arrangement of chromosomes in the interphase nucleus of plants

Chromosomal arrangement in the interphase nucleus has two main aspects: (1) arrangement of chromosomes with respect to nuclear polarity and to other nuclear components, and (2) arrangement of chromosomes with respect to one another. The latter aspect consists of two main types of spatial relationships; (1) relationships between different members of one chromosomal set, (b) relationships between different chromosomal sets. Data concerning various aspects of chromosomal arrangement in the interphase nucleus are presented and discussed and the genetic control as well as subcellular mechanisms which are involved in nuclear organization, are elucidated. Evidence is presented indicating that, in common wheat, the gene system that determines the specific pattern of chromosomal arrangement in the nucleus is operating via the microtubular elements of the spindle system. The significance of ordered arrangement of chromosomes in the nucleus for the regularity of genetic activity and chromosomal behavior, is pointed out.

Exposure of human peripheral blood lymphocytes to electromagnetic fields associated with cellular phones leads to chromosomal instability

Whether exposure to radiation emitted from cellular phones poses a health hazard is at the focus of current debate. We have examined whether in vitro exposure of human peripheral blood lymphocytes (PBL) to continuous 830 MHz electromagnetic fields causes losses and gains of chromosomes (aneuploidy), a major "somatic mutation" leading to genomic instability and thereby to cancer. PBL were irradiated at different average absorption rates (SAR) in the range of 1.6-8.8 W/kg for 72 hr in an exposure system based on a parallel plate resonator at temperatures ranging from 34.5-37.5 degrees C. The averaged SAR and its distribution in the exposed tissue culture flask were determined by combining measurements and numerical analysis based on a finite element simulation code. A linear increase in chromosome 17 aneuploidy was observed as a function of the SAR value, demonstrating that this radiation has a genotoxic effect. The SAR dependent aneuploidy was accompanied by an abnormal mode of replication of the chromosome 17 region engaged in segregation (repetitive DNA arrays associated with the centromere), suggesting that epigenetic alterations are involved in the SAR dependent genetic toxicity. Control experiments (i.e., without any RF radiation) carried out in the temperature range of 34.5-38.5 degrees C showed that elevated temperature is not associated with either the genetic or epigenetic alterations observed following RF radiation-the increased levels of aneuploidy and the modification in replication of the centromeric DNA arrays. These findings indicate that the genotoxic effect of the electromagnetic radiation is elicited via a non-thermal pathway. Moreover, the fact that aneuploidy is a phenomenon known to increase the risk for cancer, should be taken into consideration in future evaluation of exposure guidelines.

Granulocyte colony-stimulating factor generates epigenetic and genetic alterations in lymphocytes of normal volunteer donors of stem cells

OBJECTIVE

Because the effect of granulocyte colony-stimulating factor (G-CSF), which is widely used for allogeneic stem cell transplantation, on DNA function and stability has not yet been unequivocally elucidated, the aim of this study was to determine whether G-CSF leads to epigenetic and/or genetic modifications.

MATERIALS AND METHODS

Molecular cytogenetic techniques based on fluorescence in situ hybridization technology were used.

RESULTS

Lymphocytes of G-CSF mobilized donors displayed epigenetic (altered replication timing of alleles) and genetic (aneuploidy) alterations similar to those observed in lymphocytes of cancer patients. Specifically, in the donors' lymphocytes, biallelically expressed genes (TP53 and AML1) and a repetitive noncoding DNA sequence associated with chromosome segregation (CEN17) showed loss of synchrony in allelic replication timing (allele-specific replication). Each displayed a highly asynchronous pattern of allelic replication similar to that characterizing monoallelic expressed genes. This non-locus-specific epigenetic phenomenon, which also affects DNA sequences associated with chromosome segregation, was accompanied by aneuploidy. Although the loss of replication synchrony in the lymphocytes of G-CSF mobilized donors was a transient epigenetic modification, aneuploidy remained unchanged. The G-CSF effect also was observed after G-CSF administration in vitro. 5-Azacytidine, a DNA methylation blocking agent, inhibited G-CSF in vitro induction of allele-specific replication.

CONCLUSION

G-CSF, probably via changes in DNA methylation capacity, leads to cancer-characteristic DNA modifications in lymphocytes of normal mobilized donors.

hKCa3/KCNN3 potassium channel gene: association of longer CAG repeats with schizophrenia in Israeli Ashkenazi Jews, expression in human tissues and localization to chromosome 1q21

We demonstrate a significant association between longer CAG repeats in the hKCa3/KCNN3 calcium-activated potassium channel gene and schizophrenia in Israeli Ashkenazi Jews. We genotyped alleles from 84 Israeli Jewish patients with schizophrenia and from 102 matched controls. The overall allele frequency distribution is significantly different in patients vs controls (P = 0.00017, Wilcoxon Rank Sum test), with patients showing greater lengths of the CAG repeat. Northern blots reveal substantial levels of approximately 9 kb and approximately 13 kb hKCa3/KCNN3transcripts in brain, striated muscle, spleen and lymph nodes. Within the brain, hKCa3/KCNN3transcripts are most abundantly expressed in the substantia nigra, lesser amounts are detected in the basal ganglia, amygdala, hippocampus and subthalamic nuclei, while little is seen in the cerebral cortex, cerebellum and thalamus. In situ hybridization reveals abundant hKCa3/KCNN3 message localized within the substantia nigra and ventral tegmental area, and along the distributions of dopaminergic neurons from these regions into the nigrostriatal and mesolimbic pathways. FISH analysis shows that hKCa3/KCNN3 is located on chromosome 1q21.

Temporal differences in replication timing of homologous loci in malignant cells derived from CML and lymphoma patients

A close association usually exists between replication timing of a given locus and its transcriptional activity: expressed loci replicate early whereas silent ones replicate late. Accordingly, alleles that show concomitant expression replicate synchronously, while those displaying an allele-specific mode of expression show temporal differences in their replication timing, i.e., they replicate asynchronously. We aimed in our study to see whether the cancer phenotype is accompanied by a relaxation in the temporal control of allelic replication. Fluorescence in situ hybridization (FISH) was used to determine the level of synchronization in replication timing of four pairs of homologous loci in samples of malignant cells derived from patients with chronic myeloid leukemia (CML) and lymphoma and in samples from healthy individuals. Four loci, HER2 mapped to 17q11.2-q12, a locus at 21q22, TP53 mapped to 17q13.1, and MYC mapped to 8q24 were studied. In each sample we analyzed two chromosomal regions, either 17q11.2-q12 and 21q22 or 17p13.1 and 8q24. The results showed distinct differences between healthy individuals and CML/lymphoma patients: all samples derived from noncancerous subjects showed high levels of synchrony in replication timing of alleles, whereas those of cancer patients displayed a large temporal difference in replication timing, indicating early and late replicating alleles. Thus, as judged by four unrelated loci, malignancy is associated with changes in the replication pattern of homologous loci.

Asynchronous replication of homologous alpha-satellite DNA loci in man is associated with nondisjunction

We tested the hypothesis that loss of replication control of DNA loci associated with human centromeres affects the main centromere function, namely, ensuring proper sister chromatid separation and accurate chromosomal segregation during cell division. Applying one-color fluorescence in situ hybridization (FISH) to interphase nuclei, we studied the replication patterns of homologous DNA loci associated with human centromeres (alpha-satellite sequences) of chromosome pairs 10, 11, 17, and X in PHA-stimulated lymphocytes of female cancer patients with a familial predisposition to malignancy and normal, healthy women. Concomitantly, we measured the rates of aneuploidy for these chromosomes in the same cells. To elucidate the replication patterns of the various centromeric loci, we analyzed the replication-dependent configuration signals obtained following FISH with four chromosome-specific alpha-satellite probes. Our data showed an association between replication timing of alpha-satellite sequences and centromeric function. Chromosome pairs whose homologous alpha-satellite loci replicated highly synchronously revealed low rates of aneuploidy, whereas chromosome pairs with a slightly asynchronous replication pattern (i.e., short intervals between early- and late-replicating loci) revealed intermediate rates of aneuploidy, and chromosome pairs exhibiting asynchrony with long-time intervals between early- and late-replicating loci showed the highest rate of aneuploidy.

Increased rate of nondisjunction in sex cells derived from low-quality semen

The relationship between chromosomal nondisjunction and semen quality was studied in two groups of males who differ highly in their semen quality: 12 individuals with low-quality semen caused by varicocele, and 8 subjects with high-quality semen, selected from sperm donors for in vitro fertilization. Chromosomal nondisjunction was inferred from the rate of disomy found in mature sperm cells. To determine the rate of disomy, we applied fluorescence in situ hybridization using satellite-specific probes for chromosomes 1, 15, 18, X and Y. In sperm cells of males with low-quality semen, the mean rate of disomy for each of the autosomes and of hetero-disomy for the sex chromosomes (XY) was significantly higher than that observed in the high-quality semen samples: more than 15-fold higher for chromosomes 1 and 15, and 7-fold higher for chromosomes 18 and XY. Yet, the homo-disomy rate for each of the sex chromosomes (XX and YY) was almost the same in both types of semen. The large discrepancy between the low- and high-quality semen in the rate of sex chromosome hetero-disomy versus the similar rate of homo-disomy strongly suggests that the abnormal chromosomal segregation in meiocytes of males with low-quality semen resulted from chromosomal nondisjunction at the first meiotic division. The results indicate that men showing poor semen quality are at an increased risk for meiotic nondisjunction, similar to women at the end of their reproductive years.

THE EFFECT OF GENES CONTROLLING DIFFERENT DEGREES OF HOMOEOLOGOUS PAIRING ON QUADRIVALENT FREQUENCY IN INDUCED AUTOTETRAPLOID LINES OF TRITICUM LONGISSIMUM

Different genotypes of Triticum longissimum are known to either promote or suppress chromosome pairing in crosses with polyploid wheats. Lines that promote homoeologous pairing are here designated as intermediate pairing lines, while those which have no such effect or suppress pairing are known as low pairing lines. To determine a possible effect of these genotypes on homologous pairing, tetraploidy was induced in both lines and chromosomal pairing was studied at first metaphase of meiosis. While the two induced autotetraploids did not differ in chiasma frequency or in the number of paired chromosomal arms, they differed significantly in multivalent frequency; the intermediate-pairing autotetraploid exhibited the same multivalent frequency as that expected on the basis of two telomeric initiation sites, while the low pairing autotetraploid exhibited a significantly lower frequency. It is assumed that in the autotetraploid the low pairing genotype does not affect meiotic pairing per se, but modifies the pattern of homologous association in a similar manner to that known in polyploids and caused by diploidization genes. It is speculated that the tendency for bivalent pairing in the low pairing autotetraploid is due to spatial separation of the four homologous chromosomes in somatic and premeiotic cells into two groups of two.

Allele-specific replication associated with aneuploidy in blood cells of patients with hematologic malignancies

We hypothesize that coordination between the two DNA parental sets in somatic cells is essential for the stability of the diploid genome, and that its disruption is associated with the many alterations observed in the various cancerous phenotypes. As coordination between two allelic counterparts is well exemplified by synchrony in replication timing, we examined, in blood cells of patients suffering from various hematologic malignancies, replication patterns of five loci. These loci were three cancer-implicated genes (TP53, AML1, and RB1) and two nontranscribed sequences engaged in chromosome segregation. All five loci normally display synchrony in allelic replication timing. In addition, in order to exemplify an asynchronous mode of allelic replication, we followed the replication of allelic counterparts of an imprinted gene (SNRPN), which is distinguished by its asynchronous mode of allelic replication (allele-specific replication). Allelic replication patterns were studied by fluorescence in situ hybridization (FISH), which has been shown to distinguish between nonreplicated and replicated regions of the genome in interphase cells, based on the structure of the specific hybridization signals that are being detected. Using the FISH replication assay we observed, for all loci which normally exhibit synchrony in allelic replication, loss of synchrony when present in blood cells of patients with hematologic malignancies. The loss of synchrony in allelic replication in patients' cells was accompanied by aneuploidy (chromosome losses and gains), the hallmark of cancer. We were able to reinstate the normal pattern of replication in the patients' cells by introducing an inhibitor of DNA methylation. It thus appears loss of allelic coordination is an epigenetic alteration characterizing cancer, which is easily identified by simple cytogenetic means and has a potential use in both cancer investigation and detection.

Asynchronous replication of allelic loci in Down syndrome

We have used FISH to determine the level of synchronisation in replication timing of four pairs of alleles, unrelated to chromosome 21 (p53, HER2, RB1, and c-myc), in foetal (amniotic fluid) cell samples of Down syndrome and in normal foetuses. All samples derived from the Down syndrome subjects showed large temporal differences in replication timing, in contrast to the high level of synchrony shown in all samples of normal individuals. Thus, as judged by four independent loci which are not associated with chromosome 21, the additional chromosome in the Down syndrome genome induces changes in the replication pattern of an allelic pair: from a synchronous pattern characteristic to concomitantly expressed alleles to an unsynchronised one shown by alleles displaying an allele-specific mode of expression.

Asynchronous replication of p53 and 21q22 loci in chronic lymphocytic leukemia

In this study, in order to evaluate the replication pattern and the cell cycle dynamics of normal and malignant cells from patients with chronic lymphocytic leukemia, we applied the FISH technique with the p53 gene. Asynchrony was determined by the presence of one single and one set of double dots in the same cell. The rate of asynchronous replication was significantly higher in malignant cells than in normal cells (a mean of 28 vs 13, respectively, P = 0.023). There were proportionately more cells with two single dots among the normal cells (P = 0.0047). These results probably reflect the changes in gene replication and cell cycle progression that occur in malignant cells.

Asynchronous replication of alleles in genomes carrying an extra autosome

Transcriptional activity of genes appears to be highly related to their replication timing; alleles showing the common biallelic mode of expression replicate highly synchronously, whereas those with a monoallelic mode of expression replicate asynchronously. Here we used FISH to determine the level of synchronisation in replication timing of alleles in amniotic fluid cells derived from normal foetuses and from those with either of the trisomies for autosomes 21, 18 or 13, or for sex chromosomes (47,XXX and 47,XXY). Two pairs of alleles, not associated with the extra chromosome, were studied in subjects with each trisomy and three in normal subjects. In cells derived from normal foetuses and from foetuses with sex chromosome trisomies, each pair of alleles replicated synchronously; yet these very same alleles replicated asynchronously in cells derived from foetuses with trisomy for any of the three autosomes studied. The results suggest that the gross phenotypic abnormalities associated with an extra autosome are brought about not only by over-expression of genes present in three doses, but also by modifications in the expression of genes present in the normal two doses.

Altered mode of allelic replication accompanied by aneuploidy in peripheral blood lymphocytes of prostate cancer patients

Replication timing of the genetic material is a highly programmed process correlated with expression, stability and methylation capacity. An important aspect of that timing is the temporal order of allelic replication: a synchronous mode for biallelically expressed genes and an asynchronous for monoallelically expressed genes. Previous studies showed that malignancy is associated with changes in the inherent mode of allelic replication, and even normal cells of cancer patients display alterations in the replication of various genes. Using fluorescence in situ hybridization (FISH), we checked whether allelic-replication mode differentiates cancer patients from healthy individuals. We focused on prostate cancer (CAP), the most common diagnosed cancer and the second leading cause of cancer death in men over 50 years old. Five nonrelated genes and a nontranscribed DNA sequence associated with chromosomal segregation were used in our study. All 6 tested loci displayed in peripheral blood lymphocytes stimulated with phytohemagglutinin (PHA) of CAP patients loss of their inherent temporal order of allelic replication, coupled with aneuploidy, the outcome of chromosome malsegregation. The replication-timing modification is a reversible epigenetic alteration, evidenced by our ability to resurrect the normal pattern in all 6 tested loci by introducing an inhibitor of methyl transferase. On the other hand, the methylation-blocking agent failed to obliterate aneuploidy. The replication alteration accompanied by aneuploidy, detected in peripheral blood cells, distinguishes between CAP patients and individuals with benign prostate hyperplasia (BPH; a common disorder in elderly men) better than the routinely used blood marker, the prostate-specific antigen (PSA).

Detection of amplified DNA sequences in human tumor cell lines by fluorescence in situ hybridization

An unambiguous and rapid characterization of amplified DNA sequences in tumor cells is important for the understanding of neoplastic progression. This study was conducted to evaluate the potential of fluorescence in situ hybridization (FISH) to identify such amplified DNA sequences in human tumor cell lines. Applying this technique, we followed the metaphase location and interphase position of amplified DNA sequences corresponding to the SAMK, MYC, and MYCN genes in four cell lines derived from human tumors: two gastric carcinoma lines (KATO III and SNU-16), a neuroblastoma (NUB-7), and a neuroepithelioma (NUB-20) line. In metaphase cells of KATO III, NUB-7, and NUB-20 lines, the amplified regions were clearly visible and easily identified at an intrachromosomal location: in KATO III and NUB-7 at a terminal position and in NUB-20 at an interstitial position. In SNU-16, on the other hand, the amplified SAMK and MYC sequences were identified in extrachromosomal double minute chromosomes (DMs). In this line, the SAMK and MYC sequences were coamplified in the same cells and were colocated on the same DMs. FISH also allowed the identification of amplified DNA sequences in nondividing cells, enabling us to distinguish, at interphase, whether the amplification gave rise to intrachromosomal amplified regions (IARs) or to extrachromosomal DMs. The FISH technique also allowed us to determine at metaphase as well as at interphase the extent of amplification and the size of the IARs.

THE MECHANISM OF SOMATIC ASSOCIATION IN COMMON WHEAT, TRITICUM AESTIVUM L. IV. FURTHER EVIDENCE FOR MODIFICATION OF SPINDLE TUBULIN THROUGH THE SOMATIC-ASSOCIATION GENES AS MEASURED BY VINBLASTINE BINDING

Treatment with the antitubulin vinblastine was found to disrupt the spindle system in dividing root-tip cells of common wheat, Triticum aestivum L. Genotypes lacking the somatic association suppressor gene on 5BL, or containing the somatic-association promoter on 5BS, were found to be more sensitive to the treatment. In genetic lines carrying the somatic association suppressor, sensitivity to vinblastine was lower and there was a direct correlation between dosage of the suppressor gene (0, 2, and 4) and the decrease in spindle disruption on exposure to various concentrations of vinblastine. It is concluded that the somatic association genes affect binding ability of spindle tubulin to vinblastine. Since the same genes affect binding of colchicine to tubulin and since the two alkaloids attach to different sites it is assumed that the somatic association suppressor gene has a broad effect on the tubulin molecules which is not confined to a single site. The relevance of genetic control of antitubulin binding to somatic association is discussed.

Aberrant allele-specific replication, independent of parental origin, in blood cells of cancer patients

Background

Allelic counterparts of biallelically expressed genes display an epigenetic symmetry normally manifested by synchronous replication, different from genes subjected to monoallelic expression, which normally are characterized by an asynchronous mode of replication (well exemplified by the SNRPN imprinted locus). Malignancy was documented to be associated with gross modifications in the inherent replication-timing coordination between allelic counterparts of imprinted genes as well as of biallelically expressed loci. The cancer-related allelic replication timing aberrations are non-disease specific and appear in peripheral blood cells of cancer patients, including those with solid tumors. As such they offer potential blood markers for non-invasive cancer test. The present study was aimed to gain some insight into the mechanism leading to the replication timing alterations of genes in blood lymphocytes of cancer patients.

Methods

Peripheral blood samples derived from patients with prostate cancer were chosen to represent the cancerous status, and samples taken from patients with no cancer but with benign prostate hyperplasia were used to portray the normal status. Fluorescence In Situ Hybridization (FISH) replication assay, applied to phytohemagglutinin (PHA)-stimulated blood lymphocytes, was used to evaluate the temporal order (either synchronous or asynchronous) of genes in the patients' cells.

Results

We demonstrated that: (i) the aberrant epigenetic profile, as delineated by the cancer status, is a reversible modification, evidenced by our ability to restore the normal patterns of replication in three unrelated loci (CEN15, SNRPN and RB1) by introducing an archetypical demethylating agent, 5-azacytidine; (ii) following the rehabilitating effect of demethylation, an imprinted gene (SNRPN) retains its original parental imprint; and (iii) the choice of an allele between early or late replication in the aberrant asynchronous replication, delineated by the cancer status, is not random but is independent of the parental origin.

Conclusion

The non-disease specific aberrant epigenetic profile displayed in peripheral blood cells of patients with a solid tumour (unlike genetic aberrations) can be reversed, by an epigenetic drug applied in vitro, to the normal. It appears that the cancerous status differentiates between two allelic counterparts in a non-random manner, but independent of the parental origin

COLCHICINE INDUCED BIVALENT PAIRING OF TETRAPLOID MICROSPOROCYTES IN TRITICUM LONGISSIMUM AND T. SPELTOIDES

The low-pairing gene or genes of diploid Triticum longissimum (Schwinf. &Muschl.) Bowden predispose the induced autotetraploid towards bivalent pairing. In this work, bivalentization was phenocopied in intermediate- and low-pairing lines of T. longissimum and in a high-pairing line of T. speltoides (Tausch) Gren. ex Richter, by colchicine treatment during the last premeiotic mitosis. This treatment induced C-mitosis and tetraploid cells which are characterized by almost exclusive bivalent pairing instead of the expected multivalent pairing. Colchicine disrupted the association of homologous chromosomes in the premeiotic metaphase but left the sister chromatids located close to each other. As a result, rather than being all closely associated, the four homologues were arranged in pairs already prior to meiosis. The effect of colchicine in this respect is reminiscent of that of the "diploidizing genes" in many naturally occurring polyploids. This work demonstrates once again the significance which the pattern of premeiotic homologous association has for the manner of meiotic pairing.