Translocations of Chromosome End-Segments and Facultative Heterochromatin Promote Meiotic Ring Formation in Evening Primroses

Due to reciprocal chromosomal translocations, many species of Oenothera (evening primrose) form permanent multichromosomal meiotic rings. However, regular bivalent pairing is also observed. Chiasmata are restricted to chromosomal ends, which makes homologous recombination virtually undetectable. Genetic diversity is achieved by changing linkage relations of chromosomes in rings and bivalents via hybridization and reciprocal translocations. Although the structural prerequisite for this system is enigmatic, whole-arm translocations are widely assumed to be the mechanistic driving force. We demonstrate that this prerequisite is genome compartmentation into two epigenetically defined chromatin fractions. The first one facultatively condenses in cycling cells into chromocenters negative both for histone H3 dimethylated at lysine 4 and for C-banding, and forms huge condensed middle chromosome regions on prophase chromosomes. Remarkably, it decondenses in differentiating cells. The second fraction is euchromatin confined to distal chromosome segments, positive for histone H3 lysine 4 dimethylation and for histone H3 lysine 27 trimethylation. The end-segments are deprived of canonical telomeres but capped with constitutive heterochromatin. This genomic organization promotes translocation breakpoints between the two chromatin fractions, thus facilitating exchanges of end-segments. We challenge the whole-arm translocation hypothesis by demonstrating why reciprocal translocations of chromosomal end-segments should strongly promote meiotic rings and evolution toward permanent translocation heterozygosity. Reshuffled end-segments, each possessing a major crossover hot spot, can furthermore explain meiotic compatibility between genomes with different translocation histories.     

Structural alterations of the BCR and ABL genes in Ph1 positive acute leukemias with rearrangements in the BCR gene first intron: further evidence implicating Alu sequences in the chromosome translocation.

In the Philadelphia positive bcr negative acute leukemias (Ph1+bcr- AL), the chromosomal breakpoints on chromosome 22 have been shown clustered within 10.8kb (bcr2) and 5kb (bcr3) fragments of the first intron of the BCR gene. We previously reported that the breakpoints were localized in Alu repeats on chromosomes 9 and 22 in a Ph1+bcr- acute lymphoblastic leukemia with a rearrangement involving bcr2. Molecular data of two other Ph1 translocations, one a Ph1+bcr- acute myeloblastic leukemia in the bcr2 region, and the other an acute lymphoblastic leukemia in the bcr3 region are presented. In the former, the breakpoints on chromosomes 9 and 22 are localized in Alu repeats, in regions with two inverted Alu sequences, as in our previously reported case. In the second leukemia, the breakpoints are not located in Alu sequences, but such repeats are found in their vicinity. The implications of these findings are discussed.     

A novel translocation,t(9;21)(q13;q22) rearranging the RUNX1 gene in acute myelomonocytic leukemia

A novel translocation t(9;21)(q13;q22) associated with trisomy 4 has been detected in a patient with acute myelomonocytic leukemia (AML,M4) in relapse. The chromosomal translocation results in rearrangement of the RUNX1 gene at 21q22. The DNA sequence rearranged on chromosome 9 remains unidentified. The diversity of the partners involved in translocations implicating RUNX1 suggests that the functional consequences of the abnormality are more due to the truncation of RUNX1 than to the identity of its partner in the rearrangement.     

In this issue of Epigenetics

The pathogenesis of acute myeloid leukemias involves complex molecular events triggered by diverse alterations of genomic DNA. A limited number of initiating lesions, such as chromosomal translocations generating fusion genes, are constantly identified in specific forms of leukemia and are critical to leukemogenesis. Leukemia fusion proteins derived from chromosomal translocations can mediate epigenetic silencing of gene expression. Epigenetic deregulation of the DNA methylation status and of the chromatin “histone code” at specific gene sites cooperate in the pathogenesis of leukemias. The neutralization of these crucial oncogenic events can revert the leukemia phenotype. Thus, their identification and the study of their molecular and biological consequences is essential for the development of novel and specific therapeutic strategies. In this context, we recently reported a link between the differentiation block of leukemia and the epigenetic silencing of the microRNA-223 gene by the AML1/ETO oncoprotein, the product of the t(8;21) the commonest AML-associated chromosomal translocation. This finding indicates microRNAs as additional epigenetic targets for leukemogenesis and for therapeutic intervention in leukemias.     

Mapping of four translocation breakpoints within the Duchenne muscular dystrophy gene

There are over 20 females with Duchenne or Becker muscular dystrophy (DMD or BMD) who have X-autosome translocations that break the X chromosome within band Xp21. Several of these translocations have been mapped with genomic probes to regions throughout the large (approximately 2000 kb) DMD gene. In this report, a cDNA clone from the 5' end of the gene was used to further map the breakpoints in four X-autosome translocations. A t(X;21) translocation in a patient with BMD and a t(X;1) translocation in a patient with DMD were found to break within a large 110-kb intron between exons 7 and 8. Two other DMD translocations, t(X;5) and t(X;11), were found to break between the first and the second exon of the gene within a presumably large intron (greater than 100 kb). These results demonstrate that all four translocations have disrupted the DMD gene and make it possible to clone and sequence the breakpoints. This will in turn determine whether these translocations occur by chance in these large introns or whether there are sequences that predispose to translocations.     

Chromatin structural elements and chromosomal translocations in leukemia

Recurring chromosome abnormalities are strongly associated with certain subtypes of leukemia, lymphoma and sarcomas. More recently, their potential involvement in carcinomas, i.e. prostate cancer, has been recognized. They are among the most important factors in determining disease prognosis, and in many cases, identification of these chromosome abnormalities is crucial in selecting appropriate treatment protocols. Chromosome translocations are frequently observed in both de novo and therapy-related acute myeloid leukemia (AML) and myelodysplastic syndromes (MDS). The mechanisms that result in such chromosome translocations in leukemia and other cancers are largely unknown. Genomic breakpoints in all the common chromosome translocations in leukemia, including t(4;11), t(9;11), t(8;21), inv(16), t(15;17), t(12;21), t(1;19) and t(9;22), have been cloned. Genomic breakpoints tend to cluster in certain intronic regions of the relevant genes including MLL, AF4, AF9, AML1, ETO, CBFB, MYHI1, PML, RARA, TEL, E2A, PBX1, BCR and ABL. However, whereas the genomic breakpoints in MLL tend to cluster in the 5' portion of the 8.3 kb breakpoint cluster region (BCR) in de novo and adult patients and in the 3' portion in infant leukemia patients and t-AML patients, those in both the AML1 and ETO genes occur in the same clustered regions in both de novo and t-AML patients. These differences may reflect differences in the mechanisms involved in the formation of the translocations. Specific chromatin structural elements, such as in vivo topoisomerase II (topo II) cleavage sites, DNase I hypersensitive sites and scaffold attachment regions (SARs) have been mapped in the breakpoint regions of the relevant genes. Strong in vivo topo II cleavage sites and DNase I hypersensitive sites often co-localize with each other and also with many of the BCRs in most of these genes, whereas SARs are associated with BCRs in MLL, AF4, AF9, AML1, ETO and ABL, but not in the BCR gene. In addition, the BCRs in MLL, AML1 and ETO have the lowest free energy level for unwinding double strand DNA. Virtually all chromosome translocations in leukemia that have been analyzed to date show no consistent homologous sequences at the breakpoints, whereas a strong non-homologous end joining (NHEJ) repair signature exists at all of these chromosome translocation breakpoint junctions; this includes small deletions and duplications in each breakpoint, and micro-homologies and non-template insertions at genomic junctions of each chromosome translocation. Surprisingly, the size of these deletions and duplications in the same translocation is much larger in de novo leukemia than in therapy-related leukemia. We propose a non-homologous chromosome recombination model as one of the mechanisms that results in chromosome translocations in leukemia. The topo II cleavage sites at open chromatin regions (DNase I hypersensitive sites), SARs or the regions with low energy level are vulnerable to certain genotoxic or other agents and become the initial breakage sites, which are followed by an excision end joining repair process.     

High-resolution profiling of histone methylations in the human genome

Histone modifications are implicated in influencing gene expression. We have generated high-resolution maps for the genome-wide distribution of 20 histone lysine and arginine methylations as well as histone variant H2A.Z, RNA polymerase II, and the insulator binding protein CTCF across the human genome using the Solexa 1G sequencing technology. Typical patterns of histone methylations exhibited at promoters, insulators, enhancers, and transcribed regions are identified. The monomethylations of H3K27, H3K9, H4K20, H3K79, and H2BK5 are all linked to gene activation, whereas trimethylations of H3K27, H3K9, and H3K79 are linked to repression. H2A.Z associates with functional regulatory elements, and CTCF marks boundaries of histone methylation domains. Chromosome banding patterns are correlated with unique patterns of histone modifications. Chromosome breakpoints detected in T cell cancers frequently reside in chromatin regions associated with H3K4 methylations. Our data provide new insights into the function of histone methylation and chromatin organization in genome function.     

Molecular analysis of X-autosome translocations in females with Duchenne muscular dystrophy.

To further an understanding of the mechanism of constitutional chromosomal rearrangement, the translocation breakpoints of two X-autosome translocations carried by females with Duchenne or Becker muscular dystrophy have been mapped, cloned and sequenced. Breakpoints were mapped to specific introns within the dystrophin gene and intron sequences spanning the two breakpoints were cloned and used as probes to identify DNA fragments containing the translocation junctions. The junction-containing fragments were cloned after amplification by inverse PCR or single-specific-primer PCR. Sequence through the junctions and the autosomal regions spanning the breakpoints identified the mechanism of rearrangement as non-homologous exchange with minor additions or deletions (0-8 nucleotides) at the breakpoints. Paternal origin of these X-autosome translocations, coupled with evidence for non-transmission of X-autosome translocations through male meiosis suggested that the translocations were the result of a post-meiotic rearrangement in spermiogenesis.     

Large-scale chromatin fibers of living cells display a discontinuous functional organization

We investigated the chromatin organization of living cells with a combination of recently developed approaches for histone and DNA labeling. Nucleosomal DNA was labeled with a histone H2B-GFP (green fluorescent protein) fusion protein and the chromatin organization of living HeLa cells was analyzed by high resolution confocal microscopy. Within the perinuclear and perinucleolar regions chromatin was organized into large-scale fibers of 2 to 8 microm in length and 300 to 500 nm in diameter. Within the nuclear interior we observed similar large-scale fibers, but in addition focal as well as diffuse forms of organization. Comparison with standard labeling and detection procedures revealed major differences in the chromatin organization observed. Chromatin organization revealed by the distribution of histone H2B-GFP was directly compared with the functional organization of chromatin by Cy3-dUTP labeling of DNA replicating at a specific time. DNA regions replicating at a specific time display characteristic physical and functional properties. Analysis of Cy3-labeled foci revealed that they are associated with all three forms of chromatin organization (fibrillar, focal and diffuse). In particular, Cy3-labeled foci appeared as discontinuous regions of large-scale fibers. These results demonstrate that large-scale chromatin fibers have discontinuous functional characteristics.     

RUNX‐mediated growth arrest and senescence are attenuated by diverse mechanisms in cells expressing RUNX1 fusion oncoproteins

RUNX gene over‐expression inhibits growth of primary cells but transforms cells with tumor suppressor defects, consistent with reported associations with tumor progression. In contrast, chromosomal translocations involving RUNX1 are detectable in utero, suggesting an initiating role in leukemias. How do cells expressing RUNX1 fusion oncoproteins evade RUNX‐mediated growth suppression? Previous studies showed that the TEL‐RUNX1 fusion from t(12;21) B‐ALLs is unable to induce senescence‐like growth arrest (SLGA) in primary fibroblasts while potent activity is displayed by the RUNX1‐ETO fusion found in t(8;21) AMLs. We now show that SLGA potential is suppressed in TEL‐RUNX1 but reactivated by deletion of the TEL HLH domain or mutation of a key residue (K99R). Attenuation of SLGA activity is also a feature of RUNX1‐ETO9a, a minor product of t(8;21) translocations with increased leukemogenicity. Finally, while RUNX1‐ETO induces SLGA it also drives a potent senescence‐associated secretory phenotype (SASP), and promotes the immortalization of rare cells that escape SLGA. Moreover, the RUNX1‐ETO SASP is not strictly linked to growth arrest as it is largely suppressed by RUNX1 and partially activated by RUNX1‐ETO9a. These findings underline the heterogeneous nature of premature senescence and the multiple mechanisms by which this failsafe process is subverted in cells expressing RUNX1 oncoproteins.

     

Deletion of the unique gene encoding a typical histone H1 has no apparent phenotype in Aspergillus nidulans

We have cloned the H1 histone gene (hhoA) of Aspergillus nidulans. This single-copy gene codes for a typical linker histone with one central globular domain. The open reading frame is interrupted by six introns. The position of the first intron is identical to that of introns found in some plant histones. An H1-GFP fusion shows exclusive nuclear localization, whereas chromosomal localization can be observed during condensation at mitosis. Surprisingly, the deletion of hhoA results in no obvious phenotype. The nucleosomal repeat length and susceptibility to micrococcal nuclease digestion of A. nidulans chromatin are unchanged in the deleted strain. The nucleosomal organization of a number of promoters, including in particular the strictly regulated niiA-niaD bidirectional promoter is not affected.