In vivo CRISPR/Cas9 targeting of fusion oncogenes for selective elimination of cancer cells.

Fusion oncogenes (FOs) are common in many cancer types and are powerful drivers of tumor development. Because their expression is exclusive to cancer cells and their elimination induces cell apoptosis in FO-driven cancers, FOs are attractive therapeutic targets. However, specifically targeting the resulting chimeric products is challenging. Based on CRISPR/Cas9 technology, here we devise a simple, efficient and non-patient-specific gene-editing strategy through targeting of two introns of the genes involved in the rearrangement, allowing for robust disruption of the FO specifically in cancer cells. As a proof-of-concept of its potential, we demonstrate the efficacy of intron-based targeting of transcription factors or tyrosine kinase FOs in reducing tumor burden/mortality in in vivo models. The FO targeting approach presented here might open new horizons for the selective elimination of cancer cells.

Truncated RUNX1 protein generated by a novel t(1;21)(p32;q22) chromosomal translocation impairs the proliferation and differentiation of human hematopoietic progenitors.

We have identified a new t(1;21)(p32;q22) chromosomal translocation in a MDS/AML patient that results in expression of an aberrant C-terminally truncated RUNX1 protein lacking several regulatory domains. As similar truncated RUNX1 proteins are generated by genetic aberrations including chromosomal translocations and point mutations, we used the t(1;21)(p32;q22) chromosomal translocation as a model to explore whether C-terminally truncated RUNX1 proteins trigger effects similar to those induced by well-characterized leukemogenic RUNX1 fusion genes. In vitro analysis of transduced human hematopoietic/progenitor stem cells showed that truncated RUNX1 proteins increase proliferation and self-renewal and disrupt the differentiation program by interfering with RUNX1b. These effects are similar to but milder than those induced by the RUNX1/ETO fusion protein. GSEA analysis confirmed similar altered gene expression patterns in the truncated RUNX1 and RUNX1/ETO models, with both models showing alterations in genes involved in self-renewal and leukemogenesis, including homeobox genes, primitive erythroid genes and leukemogenic transcription factors. We propose that C-terminally truncated RUNX1 proteins can contribute to leukemogenesis in a similar way to RUNX1 fusion genes but through a milder phenotype.

The centromere1 (CEN1) region of Arabidopsis thaliana: architecture and functional impact of chromatin.

We have analysed the centromere 1 (CEN1) of Arabidopsis thaliana by integration of genetic, sequence and fluorescence in situ hybridisation (FISH) data. CEN1 is considered to include the centromeric core and the flanking left and right pericentromeric regions, which are distinct parts by structural and/or functional properties. CEN1 pericentromeres are composed of different dispersed repetitive elements, sometimes interrupted by functional genes. In contrast the CEN1 core is more uniformly structured harbouring only two different repeats. The presented analysis reveals aspects concerning distribution and effects of the uniformly shaped heterochromatin, which covers all CEN1 regions. A lethal mutation tightly linked to CEN1 enabled us to measure recombination frequencies within the heterochromatin in detail. In the left pericentromere, the change from eu- to heterochromatin is accompanied by a gradual change in sequence composition but by an extreme change in recombination frequency (from normal to 53-fold decrease) which takes place within a small region spanning 15 kb. Generally, heterochromatin is known to suppress recombination. However, the same analysis reveals that left and right pericentromere, though similar in sequence composition, differ markedly in suppression (53-fold versus 10-fold). The centromeric core exhibits at least 200-fold if not complete suppression. We discuss whether differences in (fine) composition reflect quantitative and qualitative differences in binding sites for heterochromatin proteins and in turn render different functional properties. Based on the presented data we estimate the sizes of Arabidopsis centromeres. These are typical for regional centromeres of higher eukaryotes and range from 4.4 Mb (CEN1) to 3.55 Mb (CEN4).

Cytogenetics for the model system Arabidopsis thaliana.

A detailed karyotype of Arabidopsis thaliana is presented using meiotic pachytene cells in combination with fluorescence in situ hybridization. The lengths of the five pachytene bivalents varied between 50 and 80 microns, which is 20-25 times longer than mitotic metaphase chromosomes. The analysis confirms that the two longest chromosomes (1 and 5) are metacentric and the two shortest chromosomes (2 and 4) are acrocentric and carry NORs subterminally in their short arms, while chromosome 3 is submetacentric and medium sized. Detailed mapping of the centromere position further revealed that the length variation between the pachytene bivalents comes from the short arms. Individual chromosomes were unambiguously identified by their combinations of relative lengths, arm-ratios, presence of NOR knobs and FISH signals with a 5S rDNA probe and chromosome specific DNA probes. Polymorphisms were found among six ecotypes with respect to the number and map positions of 5S rDNA loci. All ecotypes contain 5S rDNA in the short arms of chromosomes 4 and 5. Three different patterns were observed regarding the presence and position of a 5S rDNA locus on chromosome 3. Repetitive DNA clones enabled us to subdivide the pericentromeric heterochromatin into a central domain, characterized by pAL1 and 106B repeats, which accommodate the functional centromere and two flanking domains, characterized by the 17 A20 repeat sequences. The upper flanking domains of chromosomes 4 and 5, and in some ecotypes also chromosome 3, contain a 5S rDNA locus. The detection of unique cosmids and YAC sequences demonstrates that detailed physical mapping of Arabidopsis chromosomes by cytogenetic techniques is feasible. Together with the presented karyotype this makes Arabidopsis a model system for detailed cytogenetic mapping.

The GURKE gene is required for normal organization of the apical region in the Arabidopsis embryo.

Dicot plant embryos undergo a transition from radial to bilateral symmetry. In Arabidopsis, this change reflects patterning within the apical region, resulting in the formation of the cotyledon and shoot meristem primordia. Mutations in the GURKE gene give seedlings with highly reduced or no cotyledons. Both strong and weak gurke alleles confer this phenotypic variability although strong alleles often eliminate the entire apex and sometimes also part of the hypocotyl. The root and the root meristem as well as the radial pattern of concentric tissue layers are essentially normal. The mutant seedling phenotype can be traced back to the triangular/early-heart stage of embryogenesis when abnormal cell divisions occur within the apical region such that no or only rudimentary cotyledon primordia are established. The postembryonic development of gurke seedlings was examined in culture. In weak alleles, apical growth gave rise to abnormal leaves and stem-like structures and, eventually, abnormal flowers. In strong alleles, the apical region often failed to grow but occasionally produced fused leaf-like structures with no dorso-ventral polarity and a totally unorganized vascular system while no stems developed. The observations suggest that the GURKE gene is involved primarily in the organization of the apical region in the embryo and may also play a role during postembryonic development.

Mapping of the nucleolus organizer region on chromosome 4 in Arabidopsis thaliana.

In Arabidopsis thaliana the ribosomal RNA genes (rRNA genes or rDNA) are clustered in tandemly repeated blocks in two nucleolus organizer regions (NORs). Cytogenetic analysis has shown that the NORs are localized on chromosome 2 (NOR 2) and 4 (NOR 4). Recently the map position of NOR 2 was determined using a RFLP which was larger than 100 kb. In the course of a fingerprint analysis of different Arabidopsis ecotypes we have detected four rDNA polymorphisms between the ecotypes Landsberg (La) and Niederzenz (Nd). Mapping of these polymorphisms using established segregating F2 populations reveals that all polymorphisms detected are dominant. Three of them map to the locus on the second chromosome that has been shown to harbour the NOR 2. The fourth polymorphism can be unambiguously assigned to the upper arm of the fourth chromosome. This is the first polymorphism found which originates in the second rDNA cluster of Arabidopsis thaliana. It enables localization of NOR 4 and thus completes the mapping of rDNA genes in the NORs of Arabidopsis.

Pattern and degree of methylation in ribosomal RNA genes of Cucurbita pepo L.

Methylation with respect to its degree and distribution throughout the 18S, 5.8S and 25S rRNA gene clusters (rDNA) and within single rDNA repeats in seedlings of the higher plant Cucurbita pepo L. (zucchini) was investigated. In this plant, which is characterized by several thousand repeats, at least 70% are completely or nearly completely methylated in CpGs and to a lower degree in CpNpGs. Detailed methylation analysis revealed that a fraction of about 3-4% of all repeats is hypomethylated near the transcription initiation site (TIS) which may indicate the fraction of active repeats in C. pepo. However, a different fraction (3-4% of all repeats) which is not methylated in all sites tested (including those at the TIS) is present in C. pepo and may thus represent active but differentially methylated rDNA. The results are discussed in context of recent models on methylation and gene activity.

Mutations in the FASS gene uncouple pattern formation and morphogenesis in Arabidopsis development.

The pattern of cell division is very regular in Arabidopsis embryogenesis, enabling seedling structures to be traced back to groups of cells in the early embryo. Recessive mutations in the FASS gene alter the pattern of cell division from the zygote, without interfering with embryonic pattern formation: although no primordia of seedling structures can be recognised by morphological criteria at the early-heart stage, all elements of the body pattern are differentiated in the seedling. fass seedlings are strongly compressed in the apical-basal axis and enlarged circumferentially, notably in the hypocotyl. Depending on the width of the hypocotyl, fass seedlings may have up to three supernumerary cotyledons. fass mutants can develop into tiny adult plants with all parts, including floral organs, strongly compressed in their longitudinal axis. At the cellular level, fass mutations affect cell elongation and orientation of cell walls but do not interfere with cell polarity as evidenced by the unequal division of the zygote. The results suggest that the FASS gene is required for morphogenesis, i.e., oriented cell divisions and position-dependent cell shape changes generating body shape, but not for cell polarity which seems essential for pattern formation.