Theodor Dingermann

The MLL recombinome of acute leukemias

Chromosomal rearrangements of the human MLL gene are a hallmark for aggressive (high-risk) pediatric, adult and therapy-associated acute leukemias. These patients need to be identified in order to subject these patients to appropriate therapy regimen. A recently developed long-distance inverse PCR method was applied to genomic DNA isolated from individual acute leukemia patients in order to identify chromosomal rearrangements of the human MLL gene. We present data of the molecular characterization of 414 samples obtained from 272 pediatric and 142 adult leukemia patients. The precise localization of genomic breakpoints within the MLL gene and the involved translocation partner genes (TPGs) was determined and several new TPGs were identified. The combined data of our study and published data revealed a total of 87 different MLL rearrangements of which 51 TPGs are now characterized at the molecular level. Interestingly, the four most frequently found TPGs (AF4, AF9, ENL and AF10) encode nuclear proteins that are part of a protein network involved in histone H3K79 methylation. Thus, translocations of the MLL gene, by itself coding for a histone H3K4 methyltransferase, are presumably not randomly chosen, rather functionally selected.

Sequence and analysis of chromosome 2 of Dictyostelium discoideum

The genome of the lower eukaryote Dictyostelium discoideum comprises six chromosomes. Here we report the sequence of the largest, chromosome 2, which at 8 megabases (Mb) represents about 25% of the genome. Despite an A + T content of nearly 80%, the chromosome codes for 2,799 predicted protein coding genes and 73 transfer RNA genes. This gene density, about 1 gene per 2.6 kilobases (kb), is surpassed only by Saccharomyces cerevisiae (one per 2 kb) and is similar to that of Schizosaccharomyces pombe (one per 2.5 kb). If we assume that the other chromosomes have a similar gene density, we can expect around 11,000 genes in the D. discoideum genome. A significant number of the genes show higher similarities to genes of vertebrates than to those of other fully sequenced eukaryotes. This analysis strengthens the view that the evolutionary position of D. discoideum is located before the branching of metazoa and fungi but after the divergence of the plant kingdom, placing it close to the base of metazoan evolution.

The leukemogenic AF4–MLL fusion protein causes P-TEFb kinase activation and altered epigenetic signatures

Expression of the AF4–MLL fusion protein in murine hematopoietic progenitor/stem cells results in the development of proB acute lymphoblastic leukemia. In this study, we affinity purified the AF4–MLL and AF4 protein complexes to elucidate their function. We observed that the AF4 complex consists of 11 binding partners and exhibits positive transcription elongation factor b (P-TEFb)-mediated activation of promoter-arrested RNA polymerase (pol) II in conjunction with several chromatin-modifying activities. In contrast, the AF4–MLL complex consists of at least 16 constituents including P-TEFb kinase, H3K4me3 and H3K79me3 histone methyltransferases (HMT), a protein arginine N-methyltransferase and a histone acetyltransferase. These findings suggest that the AF4-MLL protein disturbs the fine-tuned activation cycle of promoter-arrested RNA Pol II and causes altered histone methylation signatures. Thus, we propose that these two processes are key to trigger cellular reprogramming that leads to the onset of acute leukemia.

RNA polymerase III catalysed transcription can be regulated in Saccharomyces cerevisiae by the bacterial tetracycline repressor-operator system.

We have investigated whether the RNA polymerase III‐driven transcription of eukaryotic tRNA genes can be regulated by the prokaryotic tetracycline operator‐repressor system. The bacterial tet operator (tetO) was inserted at two different positions (−7 and −46) upstream of a tRNA(Glu) (amber) suppressor gene. Both constructs are transcribed in Saccharomyces cerevisiae and yield functional tRNAs as scored by suppression of an amber nonsense mutation in the met8‐1 allele. Controlled expression of Tet repressor was achieved by fusing the bacterial tetR gene to the yeast gal1 promoter. This leads to expression of Tet repressor in yeast on galactose‐‐but not on glucose‐‐containing media. Regulation of the su‐tRNA gene with the tetO fragment inserted at position −7 has been demonstrated. Under conditions which allow tetR expression, cells exhibit a met‐ phenotype. This methionine auxotrophy can be conditionally reverted to prototrophy by adding tetracycline. However, a su‐tRNA gene with the tetO fragment inserted at position −46 cannot be repressed. Our results demonstrate clearly that the bacterial repressor protein binds to its operator in the yeast genome. Formation of this complex in the vicinity of the pol III transcription initiation site reduces the level of su‐tRNA at least 50‐fold as concluded from quantitative primer extension analyses. This indicates for the first time that class III gene expression can be regulated by a DNA binding protein with its target site in the 5′‐flanking region and that a prokaryotic repressor can confer regulation of a suitably engineered tRNA gene.

Transfer RNA genes: landmarks for integration of mobile genetic elements in Dictyostelium discoideum.

In prokaryotes and eukaryotes mobile genetic elements frequently disrupt the highly conservative structures of chromosomes, which are responsible for storage of genetic information. The factors determining the site for integration of such elements are still unknown. Transfer RNA (tRNA) genes are associated in a highly significant manner with different putative mobile genetic elements in the cellular slime mold Dictyostelium discoideum. These results suggest that tRNA genes in D. discoideum, and probably tRNA genes generally in lower eukaryotes, may function as genomic landmarks for the integration of different transposable elements in a strictly position-specific manner.

Establishment of a system for conditional gene expression using an inducible tRNA suppressor gene.

We investigated the use of the prokaryotic tetracycline operator-repressor system as a regulatory device to control the expression of Dictyostelium discoideum tRNA genes. The tetO1 operator fragment was inserted at three different positions in front of a tRNA(Glu) (Am) suppressor gene from D. discoideum, and the tetracycline repressor gene was expressed under the control of a constitutive actin 6 promoter. The effectiveness of this approach was determined by monitoring the expression of a beta-galactosidase gene engineered to contain a stop codon that could be suppressed by the tRNA. When these constructs were introduced into Dictyostelium cells, the repressor bound to the operator in front of the tRNA gene and prevented expression of the suppressor tRNA. Addition of tetracycline (30 micrograms/ml) to the growth medium prevented repressor binding, allowed expression of the suppressor tRNA, and resulted in beta-galactosidase synthesis. The operator-repressor complex interfered with tRNA gene transcription when the operator was inserted immediately upstream (position +1 or -7) of the mature tRNA coding region. Expression of a tRNA gene carrying the operator at position -46 did not respond to repressor binding. This system could be used to control the synthesis of any protein, provided the gene contained a translational stop signal.

Structure of DRE, a retrotransposable element which integrates with position specificity upstream of Dictyostelium discoideum tRNA genes.

Different Dictyostelium discoideum strains contain between 2 and 200 copies of a retrotransposable element termed DRE (Dictyostelium repetitive element). From the analysis of more than 50 elements, it can be concluded that DRE elements always occur 50 +/- 3 nucleotides upstream of tRNA genes. All analyzed clones contain DRE in a constant orientation relative to the tRNA gene, implying orientation specificity as well as position specificity. DRE contains two open reading frames which are flanked by nonidentical terminal repeats. Long terminal repeats (LTRs) are composed of three distinct modules, called A, B, and C. The tRNA gene-proximal LTR is characterized by one or multiple A modules followed by a single B module (AnB). With respect to the distal LTR, two different subforms of DRE have been isolated. The majority of isolated clones contains a distal LTR composed of a B module followed by a C module (BC), whereas the distal LTR of the other subform contains a consecutive array of a B module, a C module, a slightly altered A module, another B module, and another C module (BC.ABC). Full-length as well as smaller transcripts from DRE elements have been detected, but in comparison with the high copy number in D. discoideum strains derived from the wild-type strain NC4, transcription is rather poor.

Combined effects of the two reciprocal t(4;11) fusion proteins MLL. AF4 and AF4. MLL confer resistance to apoptosis, cell cycling capacity and growth transformation

The reciprocal chromosomal translocation t(4;11) is correlated with infant, childhood, adult and therapy-related high-risk acute leukemia. Here, we investigated the biological effects of MLL·AF4, AF4·MLL or the combination of both reciprocal fusion proteins in a conditional in vitro cell culture model system. Several parameters like cell growth, cell cycling capacity, apoptotic behavior and growth transformation were investigated under physiological and stress conditions. Co-transfected cells displayed the highest resistance against apoptotic triggers, cell cycling capacity and loss-of-contact inhibition. These analyses were complemented by gene expression profiling experiments and specific gene signatures were established for each of the three cell lines. Interestingly, co-transfected cells strongly upregulate the homeobox gene Nanog. In combination with Oct4, the Nanog homeoprotein is steering maintenance of pluripotency and self-renewal in embryonic stem cells. Transcription of Nanog and other stem cell factors, like Oct4 and Bmi1, was verified in biopsy material of t(4;11) patient cells which express both reciprocal t(4;11) fusion genes. In conclusion, the presence of both reciprocal MLL fusion proteins confers biological properties known from t(4;11) leukemia, suggesting that each of the two fusion proteins contribute specific properties and, in combination, also synergistic effects to the leukemic phenotype.

Complex MLL rearrangements in t(4;11) leukemia patients with absent AF4.MLL fusion allele.

The human mixed lineage leukemia (MLL) gene is frequently involved in genetic rearrangements with more than 55 different translocation partner genes, all associated with acute leukemia. Reciprocal chromosomal translocations generate two MLL fusion alleles, where 5′- and 3′-portions of MLL are fused to gene segments of given fusion partners. In case of t(4;11) patients, about 80% of all patients exhibit both reciprocal fusion alleles, MLL·AF4 and AF4·MLL, respectively. By contrast, 20% of all t(4;11) patients seem to encode only the MLL·AF4 fusion allele. Here, we analyzed these ’MLL·AF4+/AF4·MLL−’ patients at the genomic DNA level to unravel their genetic situation. Cryptic translocations and three-way translocations were found in this group of t(4;11) patients. Reciprocal MLL fusions with novel translocation partner genes, for example NF-KB1 and RABGAP1L, were identified and actively transcribed in leukemic cells. In other patients, the reciprocal 3′-MLL gene segment was fused out-of-frame to PBX1, ELF2, DSCAML1 and FXYD6. The latter rearrangements caused haploinsufficiency of genes that are normally expressed in hematopoietic cells. Finally, patients were identified that encode only solitary 3′-MLL gene segments on the reciprocal allele. Based on these data, we propose that all t(4;11) patients exhibit reciprocal MLL alleles, but due to the individual recombination events, provide different pathological disease mechanisms.

Analysis of gene function inDictyostelium

Over the past ten years, powerful molecular genetic techniques have been developed to analyze gene function inDictyostelium. DNA-mediated transformation using a variety of selections and vectors has allowed the introduction of wild-type or modified genes that are under various forms of transcriptional control. Homologous recombination is efficient and can be used to modify the genome in precise ways. In addition, it is now possible to clone genes based on their mutant phenotype alone, either by insertional mutagenesis, or by screening antisense expression cDNA libraries. Finally, a nearly complete physical map of the genome is available and so genes are easily mapped by physical techniques. We discuss many of these advances within the context of major research problems presently under study.