Excellent translational research in oncology: A journey towards novel and more effective anti-cancer therapies.

Comprehensive Cancer Centres (CCCs) serve as critical drivers for improving cancer survival. In Europe, we have developed an Excellence Designation System (EDS) consisting of criteria to assess "excellence" of CCCs in translational research (bench to bedside and back), with the expectation that many European CCCs will aspire to this status.

Single nucleotide polymorphisms in wild isolates of Caenorhabditis elegans.

Caenorhabditis elegans (isolate N2 from Bristol, UK) is the first animal of which the complete genome sequence was available. We sampled genomic DNA of natural isolates of C. elegans from four different locations (Australia, Germany, California, and Wisconsin) and found single nucleotide polymorphisms (SNPs) by comparing with the Bristol strain. SNPs are under-represented in coding regions, and many were found to be third base silent codon mutations. We tested 19 additional natural isolates for the presence and distribution of SNPs originally found in one of the four strains. Most SNPs are present in isolates from around the globe and thus are older than the latest contact between these strains. An exception is formed by an isolate from an island (Hawaii) that contains many unique SNPs, absent in the tested isolates from the rest of the world. It has been noticed previously that conserved genes (as defined by homology to genes in Saccharomyces cerevisiae) cluster in the chromosome centers. We found that the SNP frequency outside these regions is 4.5 times higher, supporting the notion of a higher rate of evolution of genes on the chromosome arms.

CHE-3, a cytosolic dynein heavy chain, is required for sensory cilia structure and function in Caenorhabditis elegans.

Forward genetic screens using novel assays of nematode chemotaxis to soluble compounds identified three independent transposon-insertion mutations in the gene encoding the Caenorhabditis elegans dynein heavy chain (DHC) 1b isoform. These disruptions were mapped and cloned using a newly developed PCR-based transposon display. The mutations were demonstrated to be allelic to the che-3 genetic locus. This isoform of dynein shows temporally and spatially restricted expression in ciliated sensory neurons, and mutants show progressive developmental defects of the chemosensory cilia. These results are consistent with a role for this motor protein in the process of intraflagellar transport; DHC 1b acts in concert with a number of other proteins to establish and maintain the structural integrity of the ciliated sensory endings in C. elegans.

Cis requirements for transposition of Tc1-like transposons in C. elegans.

The Caenorhabditis elegans transposons Tc1 and Tc3 are able to transpose in heterologous systems such as human cell lines and zebrafish. Because these transposons might be useful vectors for transgenesis and mutagenesis of diverse species, we determined the minimal cis requirements for transposition. Deletion mapping of the transposon ends shows that fewer than 100 bp are sufficient for transposition of Tc3. Unlike Tc1, Tc3 has a second, internal transposase binding site at each transposon end. We found that these binding sites play no major role in the transposition reaction, since they can be deleted without reduction of the transposition frequency. Site-directed mutagenesis was performed on the conserved terminal base pairs at the Tc3 ends. The four terminal base pairs at the ends of the Tc3 inverted repeats were shown to be required for efficient transposition. Finally, increasing the length of the transposon from 1.9 kb to 12.5 kb reduced the transposition frequency by 20-fold, both in vivo and in vitro.

Mut-7 of C. elegans, required for transposon silencing and RNA interference, is a homolog of Werner syndrome helicase and RNaseD.

While all known natural isolates of C. elegans contain multiple copies of the Tc1 transposon, which are active in the soma, Tc1 transposition is fully silenced in the germline of many strains. We mutagenized one such silenced strain and isolated mutants in which Tc1 had been activated in the germline ("mutators"). Interestingly, many other transposons of unrelated sequence had also become active. Most of these mutants are resistant to RNA interference (RNAi). We found one of the mutated genes, mut-7, to encode a protein with homology to RNaseD. This provides support for the notion that RNAi works by dsRNA-directed, enzymatic RNA degradation. We propose a model in which MUT-7, guided by transposon-derived dsRNA, represses transposition by degrading transposon-specific messengers, thus preventing transposase production and transposition.

Transposon Tc1 of the nematode Caenorhabditis elegans jumps in human cells.

The transposon Tc1 of the nematode Caenorhabditis elegans is a member of the widespread family of Tc1/mariner transposons. The distribution pattern of virtually identical transposons among insect species that diverged 200 million years ago suggested horizontal transfer of the elements between species. Thishypothesis gained experimental support when it was shown that Tc1 and later also mariner transposons could be made to jump in vitro , with their transposase as the only protein required. Later it was shown that mariner transposons from one fruit fly species can jump in other fruit fly species and in a protozoan and, recently, that a Tc1-like transposon from the nematode jumps in fish cells and that a fish Tc1-like transposon jumps in human cells. Here we show that the Tc1 element from the nematode jumps in human cells. This provides further support for the horizontal spread hypothesis. Furthermore, it suggests that Tc1 can be used as vehicle for DNA integration in human gene therapy.

Transposition of the nematode Caenorhabditis elegans Tc3 element in the zebrafish Danio rerio.

BACKGROUND: Transposable elements of the Tc1/mariner family are found in many species of the animal kingdom. It has been suggested that the widespread distribution of this transposon family resulted from horizontal transmission among different species. RESULTS: To test the ability of Tc1/mariner to cross species barriers, as well as to develop molecular genetic tools for studying zebrafish development, we determined the ability of the Tc3 transposon, a member of the Tc1/mariner family, to function in zebrafish. Tc3 transposons carrying sequences encoding the green fluorescent protein (GFP) were able to integrate in the fish genome by transposition. Integrated transposons expressed the GFP marker after germline transmission, and were capable of being mobilized upon introduction of transposase protein in trans. CONCLUSIONS: Our findings support models of horizontal transmission of Tc1/mariner elements between species. The work also establishes the basis for a novel method of transposon-mediated genetic transformation and for transposon-mediated genetic screens in zebrafish and other organisms.

Tc7, a Tc1-hitch hiking transposon in Caenorhabditis elegans.

We have found a novel transposon in the genome of Caenorhabditis elegans. Tc7 is a 921 bp element, made up of two 345 bp inverted repeats separated by a unique, internal sequence. Tc7 does not contain an open reading frame. The outer 38 bp of the inverted repeat show 36 matches with the outer 38 bp of Tc1. This region of Tc1 contains the Tc1-transposase binding site. Furthermore, Tc7 is flanked by TA dinucleotides, just like Tc1, which presumably correspond to the target duplication generated upon integration. Since Tc7 does not encode its own transposase but contains the Tc1-transposase binding site at its extremities, we tested the ability of Tc7 to jump upon forced expression of Tc1 transposase in somatic cells. Under these conditions Tc7 jumps at a frequency similar to Tc1. The target site choice of Tc7 is identical to that of Tc1. These data suggest that Tc7 shares with Tc1 all the sequences minimally required to parasitize upon the Tc1 transposition machinery. The genomic distribution of Tc7 shows a striking clustering on the X chromosome where two thirds of the elements (20 out of 33) are located. Related transposons in C. elegans do not show this asymmetric distribution.

G proteins are required for spatial orientation of early cell cleavages in C. elegans embryos.

Heterotrimeric G proteins are signal-transducing molecules activated by seven transmembrane domain receptors. In C. elegans, gpb-1 encodes the sole Gbeta subunit; therefore, its inactivation should affect all heterotrimeric G protein signaling. When maternal but no zygotic gpb-1 protein (GPB-1) is present, development proceeds until the first larval stage, but these larvae show little muscle activity and die soon after hatching. When, however, the maternal contribution of GPB-1 is also reduced, spindle orientations in early cell divisions are randomized. Cell positions in these embryos are consequently abnormal, and the embryos die with the normal number of cells and well-differentiated but abnormally distributed tissues. These results indicate that maternal G proteins are important for orientation of early cell division axes, possibly by coupling a membrane signal to centrosome position.

Rte-1, a retrotransposon-like element in Caenorhabditis elegans.

We have characterized a retrotransposon-like element (Rte-1) in C. elegans. It was identified while we were sequencing the pim related kinase-1 (prk-1) gene. The element is 3,298 bp long and flanked by a 200 bp direct repeat. 95 bp of the direct repeat are present in the coding region of prk-1. Rte-1 contains an open reading frame, in the opposite orientation of prk-1, potentially encoding 625 amino acids, with similarity to reverse transcriptases. The element is most similar to members of the non-LTR group of retrotransposable elements. There is weak homology of the predicted amino acid sequence of Rte-1 to several reverse transcriptase-like genes identified by the C. elegans genome sequencing consortium, suggesting that there may be a large family of these elements. Southern blots indicate that there are approximately 10-15 additional Rte-1 elements in the C. elegans Bristol N2 genome and a similar number is found in the genomes of two other geographically distinct strains. The insertion pattern of Rte-1 is polymorphic between these strains.

DNA binding activities of the Caenorhabditis elegans Tc3 transposase.

Tc3 is a member of the Tc1/mariner family of transposable elements. All these elements have terminal inverted repeats, encode related transposases and insert exclusively into TA dinucleotides. We have studied the DNA binding properties of Tc3 transposase and found that an N-terminal domain of 65 amino acids binds specifically to two regions within the 462 bp Tc3 inverted repeat; one region is located at the end of the inverted repeat, the other is located approximately 180 bp from the end. Methylation interference experiments indicate that this N-terminal DNA binding domain of the Tc3 transposase interacts with nucleotides on one face of the DNA helix over adjacent major and minor grooves.

The mechanism of transposition of Tc3 in C. elegans.

The Tc3 transposon of C. elegans belongs to a family of inverted repeat DNA transposons, found in many different phyla. We studied the mechanism of Tc3 transposition by expression of Tc3 transposase from a heat-shock promoter in transgenic nematodes. Transposition is accompanied by the appearance of linear extrachromosomal Tc3 DNA. Analysis of the ends of this presumed transposition intermediate shows that the transposon is excised incompletely: the 5' ends of the transposon lack two nucleotides. The 3' ends coincide with the last nucleotide of the integrated element and carry 3' hydroxyls. The nucleotides that are not coexcised with the transposon remain at the donor site and result in a characteristic footprint. A model is derived for the mechanism of Tc3 jumping that probably applies to the entire family of Tc1/mariner transposable elements.

Target site choice of the related transposable elements Tc1 and Tc3 of Caenorhabditis elegans.

We have investigated the target choice of the related transposable elements Tc1 and Tc3 of the nematode C. elegans. The exact locations of 204 independent Tc1 insertions and 166 Tc3 insertions in an 1 kbp region of the genome were determined. There was no phenotypic selection for the insertions. All insertions were into the sequence TA. Both elements have a strong preference for certain positions in the 1 kbp region. Hot sites for integration are not clustered or regularly spaced. The orientation of the integrated transposon has no effect on the distribution pattern. We tested several explanations for the target site preference. If simple structural features of the DNA (e.g. bends) would mark hot sites, we would expect the patterns of the two related transposons Tc1 and Tc3 to be similar; however we found them to be completely different. Furthermore we found that the sequence at the donor site has no effect on the choice of the new insertion site, because the insertion pattern of a transposon that jumps from a transgenic donor site is identical to the insertion pattern of transposons jumping from endogenous genomic donor sites. The most likely explanation for the target choice is therefore that the primary sequence of the target site is recognized by the transposase. However, alignment of the Tc1 and Tc3 integration sites does not reveal a strong consensus sequence for either transposon.

Characterization of the Caenorhabditis elegans Tc1 transposase in vivo and in vitro.

We have investigated the function of the Tc1A gene of the mobile element Tc1 of Caenorhabditis elegans. Tc1 is a member of a family of transposons found in several animal phyla, such as nematodes, insects, and vertebrates. Two lines of evidence show that Tc1A encodes the transposase of Tc1. First, forced expression of the Tc1A protein in transgenic nematodes results in an enhanced level of transposition of endogenous Tc1 elements. Second, DNase I footprinting and gel retardation assays show that Tc1A binds specifically to the inverted repeats at the ends of the element and that the Tc1A recognition site is located between base pairs 5 and 26 from the ends of Tc1. Functional dissection of the transposase shows the presence of two distinct DNA-binding domains. A site-specific DNA-binding domain is contained within the amino-terminal 63 residues of Tc1A; this region shows sequence similarity to the prokaryotic IS30 transposase. A second, general DNA-binding domain is located between amino acids 71 and 207. Our results suggest that Tc1 is more similar to prokaryotic insertion elements than to eukaryotic transposons such as P elements in Drosophila or Ac and En-1 in plants.

Mobilization of quiet, endogenous Tc3 transposons of Caenorhabditis elegans by forced expression of Tc3 transposase.

The commonly studied Caenorhabditis elegans strain Bristol N2 contains approximately 15 copies per genome of the transposon Tc3. However, Tc3 is not active in Bristol N2. Tc3 contains one major open reading frame (Tc3A). We have fused this open reading frame to an inducible promoter and expressed it in a transgenic Bristol N2 line. Tc3A expression resulted in frequent excision and transposition of endogenous Tc3 elements. This shows that the Bristol N2 genome contains Tc3 transposons that are cis proficient for transposition, but are immobile because Tc3A is absent. We demonstrate that recombinant Tc3A binds specifically to the terminal nucleotides of the Tc3 inverted repeat, indicating that Tc3A is the Tc3 transposase. Activation of Tc3 transposition in vivo was accompanied by the appearance of extrachromosomal, linear copies of Tc3. These may be intermediates in Tc3 transposition.

The H circles of Leishmania tarentolae are a unique amplifiable system of oligomeric DNAs associated with drug resistance.

We have induced drug resistance against methotrexate, an inhibitor of dihydrofolate reductase, and CB3717, an inhibitor of thymidylate synthetase in a strain of Leishmania tarentolae. The drug-resistant strains contain extrachromosomal DNA circles of 68 kilobases with a 30-kilobase inverted duplication flanked by 4- and 5 kilobase unique segments. We show that these circles are highly homologous to the drug-induced H circles of L. tropica (1). All three L. tarentolae strains analyzed contain a chromosomal copy of the H region without duplication, but two of the three strains contain extrachromosomal H circles as well, predominantly present as H circle dimers in one strain and as tetramers in the other. After induction of methotrexate resistance, monomeric circles, presumably derived from the oligomers, become the major type of circle. Our results indicate that the H region represents a genomic region that can be copied at very low frequency to yield circles by a precise, but unusual mechanism under natural conditions in wild-type cells. Although superficially analogous to the episomes of bacteria, the system is without precedent in nature.