Hypervariability of intronic simple (gt)n(ga)m repeats in HLA-DRB genes

We have investigated the extent of DNA variability in intronic simple (gt)_n(ga)_m repeat sequences and correlated this to sequence polymorphisms in the flanking exon 2 of HLA-DRB genes. The polymerase chain reaction (PCR) was used to amplify a DNA fragment containing exon 2 and the repeat region of intron 2. The PCR products were separated on sequencing gels in order to demonstrate length hypervariability of the (gt)_n(ga)_m repeats. In a parallel experiment, the PCR products were cloned and sequenced (each exon 2 plus adjacent simple repeats) to characterize the simple repeats in relation to the HLA-DRB sequences. In a panel of 25 DRB1, DRB4, and DRB5 alleles new sequences were not detected. Restriction fragment length polymorphism (RFLP) subtyping of serologically defined haplotypes corresponds to translated DNA sequences in 85% of the cases, the exceptions involving unusual DR/DQ combinations. Many identical DRB1 alleles can be distinguished on the basis of their adjacent simple repeats. We found group-specific organization of the repeats: the DRw52 supergroup repeats differ from those of DRB1*0101, DRB4*0101, and DRB5*0101 alleles and from those of pseudogenes. Finally, we amplified baboon DNA and found a DRB allele with extensive similarity to DRB1 sequences of the DRw52 supergroup. The simple repeat of the baboon gene, however, resembles that of human pseudogenes. In addition to further subtyping, the parallel study of polymorphic protein and hypervariable DNA alleles may allow conclusions to be drawn on the relationships between the DRB genes and perhaps also on the theory of trans-species evolution.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession number M 34258.     

Characterization and quantification of triple helix formation in chromosomal DNA

DNA-binding molecules that recognize specific sequences offer a high potential for the understanding of chromatin structure and associated biological processes in addition to their therapeutic potential, e.g. as positioning agents for validated anticancer drugs. A prerequisite for the development of DNA-binding molecules is the availability of appropriate methods to assess their binding properties quantitatively at the desired target sequence in the human genome. We have further developed a capture assay to assess triplex-forming oligonucleotide (TFO) binding efficiency quantitatively. This assay is based on bifunctional, psoralen and biotin-conjugated, TFOs and real-time PCR analysis. We have applied this novel quantification method to address two issues that are relevant for DNA-binding molecules. First, we have compared directly the extent of TFO-binding in three experimental settings with increasing similarity to the situation in vivo, i.e. naked genomic DNA, isolated cell nuclei, or whole cells. This comparison allows us to characterize factors that influence genomic triplex formation, e.g. chromosomal DNA organization or intracellular milieu. In isolated nuclei, the binding was threefold lower compared to naked DNA, consistent with a decreased target accessibility int he nucleosomal environment. Binding was detected in whole cells, indicating that the TFO enters the nucleus and binds to its target in intact cells in vivo, but the efficiency was decreased (tenfold) compared to nuclei. Secondly, we applied the method to characterize the binding properties of two different TFOs targeting the same sequence. We found that an antiparallel-binding GT-containing TFO bound more efficiently, but with less target sequence selectivity compared to a parallel-binding CU-containing TFO. Collectively, a sensitive method to characterize genomic triplex formation was described. This may be useful for the determination of factors driving TFO binding efficiency and, thus, may improve the usefulness of triplex-mediated gene targeting for studies of chromatin structure as well as for therapeutic antigene strategies.     

Dissecting (CAC)5/(GTG)5 multilocus fingerprints from man into individual locus-specific, hypervariable components.

Individual components of multilocus fingerprints from man produced by (CAC)5/(GTG)5 oligonucleotides have been scrutinized to characterize their peculiar properties. Successful cloning and changes occurring during the propagation of recombinant simple repetitive DNA in prokaryotic hosts are described. The isolated locus-specific probes were characterized with respect to their formal (and population genetic) properties and their usefulness for individualization and linkage studies. The localization was determined on chromosomes 8, 9, 11, and 22. Repeat flanking sequences were characterized and analyzed for their coding potential because of significant open reading frames and apparent evolutionary conservation among vertebrates. The organization of the repeats and their flanking regions in the human genome is discussed with respect to the sequence (fine) architecture that developed during evolution. Classical "minisatellite" sequences were not detected near hypervariable (cac)n/(gtg)n repeats. The single-copy probes described herein are a convenient complement to the oligonucleotides employed for multilocus fingerprinting. Many practical applications are apparent.     

Dissecting (CAC)5/(GTG)5 multilocus fingerprints from man into individual locus-specific, hypervariable components

Individual components of multilocus fingerprints from man produced by (CAC)₅/(GTG)₅ oligonucleotides have been scrutinized to characterize their peculiar properties. Successful cloning and changes occurring during the propagation of recombinant simple repetitive DNA in prokaryotic hosts are described. The isolated locus-specific probes were characterized with respect to their formal (and population genetic) properties and their usefulness for individualization and linkage studies. The localization was determined on chromosomes 8, 9, 11, and 22. Repeat flanking sequences were characterized and analyzed for their coding potential because of significant open reading frames and apparent evolutionary conservation among vertebrates. The organization of the repeats and their flanking regions in the human genome is discussed with respect to the sequence (fine) architecture that developed during evolution. Classical “minisatellite” sequences were not detected near hypervariable (cac)_n/(gtg)_n repeats. The singlecopy probes described herein are a convenient complement to the oligonucleotides employed for multilocus fingerprinting. Many practical applications are apparent.     

Exonic polymorphism vs intronic simple repeat hypervariability in MHC-DRB genes

Gene products encoded by the major histocompatibility complex often exhibit a high degree of polymorphism. In humans the HLA-DR polymorphism is due to more than 50 alleles with varying exon 2 sequences. Each group of DRB alleles contains a certain form of the basic simple repeat motif (gt)_n(ga)_m in intron 2. Identical alleles can be differentiated on the basis of the hypervariable repeat. In this study focused on cattle (Bos taurus) we identified different Bota-DRB alleles in a limited survey by amplification via polymerase chain reaction and sequencing. In addition DRB exon 2 sequences were also obtained from eight additional hoofed animal species (seven horned artiodactyls and one pig) revealing artiodactyl-specific polymorphic and nonpolymorphic substitutions. In the genus Bos the intronic simple repeat variability was compared with exonic DRB polymorphism. As in humans all Bota-DRB exons were always associated with specifically organized basic simple repeat structures. Yet the extent of simple repeat variability was lower in cattle compared to humans. Selective breeding in the process of domestication might be responsible for the diminished intronic hypervariability. Nevertheless, the hypermutable simple repeat sequences have been preserved in the same position and with the same principal structure for at least 70 × 10⁶ years of evolution. Unexpectedly, the rate of intronic simple repeat and exonic changes appear quite similar.     

Studies on ectomycorrhiza

Summary Plants ofPicea abies (L.) Karst were grown in mycorrhizal association withTelephora terrestris (Pers. ex Fr.) andPisolithus tinctorius (Mich. ex Pers.) Coker and Couch on sphagnum peat in petri dishes or Perspex chambers. After 1 yearT. terrestris had formed prominent rhizomorphs which were characterized by light microscopy and investigated for³²P-orthophosphate uptake. The absorbed phosphate was transported to sinks throughout the rhizomorphal system as well as into the plant. The calculated translocation velocity and flux rate in the rhizomorph were in the range of 1–3 cm/h and 0.5–4.0 × 10^-10 mol cm^-2 s^-1, respectively. Label was observed to accumulate in the needles 2–3 days after application. Feeding a non-mycorrhized root with³²P-orthophosphate led to an accumulation of label in needles within 1 h, but no radioactivity appeared in the associatedT. terrestris rhizomorphs. The rhizomorphs ofP. tinctorius revealed a higher structural differentiation than those ofT. terrestris. Translocation of labelled phosphorus through rhizomorphs ofP. tinctorius into spruce needles was also demonstrated.     

Inhibition of urokinase-type plasminogen activator receptor induces apoptosis in melanoma cells by activation of p53

The urokinase-type plasminogen activator receptor (uPAR) is involved in several biological processes, including proteolysis, adhesion, migration and inflammation. Increased expression of uPAR is associated with metastasis in several tumor types. We studied the biological role of uPAR in melanoma and found that inhibition of uPAR via RNA interference induced massive death in three different metastatic cell lines. Annexin-V staining and caspase activation analysis revealed induction of the mitochondrial apoptotic pathway. The expression of members of the Bcl-2 family (Bax, Bcl-2, Bak and Bcl-x(L)) was changed in a pro-apoptotic manner. uPAR inhibition induced the expression of the tumor suppressor p53 and of its downstream target gene p21. Inhibition of p53 rescued cells from apoptosis indicating that p53 was critical for apoptosis induction. Apoptosis was observed in melanoma cells carrying activating BRAF mutations and occurred in the presence of extracellular signal-regulated kinase (ERK) phosphorylation. uPAR can activate focal adhesion kinase (FAK), which is implicated in adhesion-dependent tumor cell survival. However, inhibition of FAK did not induce apoptosis. Our data suggest a new function of uPAR acting as a survival factor for melanoma by downregulating p53. Inhibition of uPAR induces a pro-apoptotic signalling pathway via p53 that is independent of ERK or FAK signalling. These findings may offer new treatment strategies for metastatic melanoma.     

Selective induction of cell death in melanoma cell lines through targeting of Mcl-1 and A1

Melanoma is an often fatal form of skin cancer which is remarkably resistant against radio- and chemotherapy. Even new strategies that target RAS/RAF signaling and display unprecedented efficacy are characterized by resistance mechanisms. The targeting of survival pathways would be an attractive alternative strategy, if tumor-specific cell death can be achieved. Bcl-2 proteins play a central role in regulating survival of tumor cells. In this study, we systematically investigated the relevance of antiapoptotic Bcl-2 proteins, i.e., Bcl-2, Bcl-xL, Bcl-w, Mcl-1, and A1, in melanoma cell lines and non-malignant cells using RNAi. We found that melanoma cells required the presence of specific antiapoptotic Bcl-2 proteins: Inhibition of Mcl-1 and A1 strongly induced cell death in some melanoma cell lines, whereas non-malignant cells, i.e., primary human fibroblasts or keratinocytes were not affected. This specific sensitivity of melanoma cells was further enhanced by the combined inhibition of Mcl-1 and A1 and resulted in 60% to 80% cell death in all melanoma cell lines tested. This treatment was successfully combined with chemotherapy, which killed a substantial proportion of cells that survived Mcl-1 and A1 inhibition. Together, these results identify antiapoptotic proteins on which specifically melanoma cells rely on and, thus, provide a basis for the development of new Bcl-2 protein-targeting therapies.