Minisatellite telomeres occur in the family Alliaceae but are lost in Allium.

Although telomere sequences are considered to be highly conserved, there are switch-points in plant telomere evolution that are congruent with species' phylogenies. When Asparagales diverged, the Arabidopsis-type telomeric minisatellite repeat (TTTAGGG)(n) was first replaced by a human-type (TTAGGG)(n) repeat, and both were lost in Allium cepa (Alliaceae). We aimed to discover (1) when this loss occurred during divergence of Alliaceae and, (2) if (TTAGGG)(n) repeats were replaced by other known telomeric minisatellites. Slot-blot hybridization, fluorescent in situ hybridization, BAL31 digestion, asymmetric PCR, and cloning were used to identify and localize candidate telomeric sequences in species of Nothoscordum, Miersia, Ipheion, Tulbaghia, Gethyum, Gilliesia, Leucocoryne, Tristagma, and representatives of the three major Allium clades. Alliaceae genera other than Allium have human (TTAGGG)-type telomeric repeats that form telomeres. In Allium, only Tetrahymena-type (TTGGGG) repeats were ubiquitous in the genome, but they were not localized to telomeres. Likewise, the consensus telomeric repeats in Arabidopsis, human, Bombyx (TTAGG), Chlamydomonas (TTTTAGGG), and Oxytricha (TTTTGGGG) are absent in Allium telomeres. Alliaceae with human-type telomeres share telomere structures with related Asparagales species. We demonstrate that in the Allium ancestor human-type telomeric repeats were lost from telomeres and were not replaced by any investigated alternative minisatellite repeats. However, human and other types of minisatellite telomeric repeats are interspersed in some Allium genomes and their genomic signatures coincide with Allium clades.

Comparison of different kinds of probes used for analysis of variant telomeric sequences.

In this work we aimed to compare and critically evaluate results obtained by different types of probes used for hybridisation to detect variant telomeric sequences with respect to their reliability and information value. Using slot-blot hybridisation we investigated three types of probes (oligonucleotides, cloned fragments and concatenated probes) under various conditions of hybridisation and washing. The concatenated probes exhibited the highest specificity although all three types are suitable for hybridisation of telomeric sequences under appropriate experimental conditions. We demonstrate how understanding generated from these data enables interpretation of hybridisation patterns of oligonucleotide probes to genomic DNAs.

A comparison of DNA binding profiles of dinuclear platinum compounds with polyamine linkers and the trinuclear platinum phase II clinical agent BBR3464.

The DNA binding profiles of three bis Pt(II) polyamine-linked compounds, [[ trans-PtCl(NH(3))(2)](2)[mu-spermine- N(1), N(12)]](4+), [[ trans-PtCl(NH(3))(2)](2)[mu-spermidine- N(1), N(8)]](3+), and [[ trans-PtCl(NH(3))(2)](2)[mu-BOC-spermidine]](2+), were compared with that of a novel trinuclear phase II clinical agent, [[ trans-PtCl(NH(3))(2)](2)[mu- trans-Pt(NH(3))(2)(H(2)N(CH(2))(6)NH(2))(2)]](4+). All of the compounds bind preferentially in a bifunctional manner, according to unwinding of supercoiled DNA circles. The kinetics of binding of these compounds corresponds to their relative charge (2+ to 4+). The preference for the formation of interstrand crosslinks, however, does not follow a charge-based pattern. By studying the results of DNA polymerase extension products on a DNA template modified by the compounds, and by incorporating the complementary method of RNA transcription mapping, it was possible to determine the nucleotide bases that are preferred sites of binding. The stop sites due to platinum adducts were determined, and some preliminary observations concerning the range and type of crosslinks were established. It can be concluded that dinuclear Pt compounds are similar to their trinuclear counterpart, and that charge differences do not contribute solely to the variances between the compounds.