Inheritance of rDNA spacer length variants in man

Summary We studied the rDNA spacer length polymorphism in a sample of 121 individuals belonging to families of 2–3 generations. Our data, obtained by restriction pattern analysis of genomic DNA, confirmed the limited and discrete nature of this polymorphism. Using the pattern as a genetic marker, we analyzed the segregation of length variants in the different families and we investigated the possible occurrence of unequal crossing-over events among homologous and nonhomologous rDNA clusters. No direct evidence of recombination in the spacer region that we analyzed emeged from our study. All the differences in the restriction patterns observed among individuals from the same family could be explained as resulting from meiotic segregation. Family data showed a multichromosomal distribution of NTS length variants and demonstrated a direct correspondence between the frequency of a variant in the population and its degree of spreading on the different rDNA clusters.     

Sister chromatid exchange and the evolution of rDNA spacer length

The structures of rDNA spacers from several species have been characterized and virtually all have internally repeated sequences. Different numbers of these internal repeats are responsible for most spacer length variation. Because unequal recombination between these internal repeats will cause new length variation, while unequal exchange between rDNA copies will homogenize the variants, we modeled the interaction of these two processes. Two models were used to simulate both types of unequal exchange at the sister chromatid level. Both models indicate that a narrow range of relative recombination frequencies is required to produce levels of variability comparable to those published. One model puts a lower limit on the number of internal repeats, and the other puts both a lower and upper limit on the number of repeats. The model with both maximum and minimum constraints produces a distribution closer to actual spacer distributions. These results imply that small changes in recombination rates can generate the differences in numbers of length variants observed in different species.     

Polyelectrolyte contribution to the persistence length of DNA

The difference between the theories of Manning, on the one hand, and of Odijk and Skolnick and Fixman, on the other, for the polyelectrolyte contribution to the persistence length of DNA is shown to arise entirely from a subtle geometrical error in the theory of Manning. The corrected theory of Manning predicts a negligible polyelectrolyte contribution in 1.0M NaCl and only 33 Å in 0.01M NaCl, thus giving a change in total persistence length by a factor of only 1.07 over that range, in agreement with Odijk. Pertinent data in the literature indicate that the persistence length must change by a factor of ≤ 1.6 between 1.0 and 0.01M NaCl, and very likely by less than a factor of 1.4. Evidently, the intrinsic rigidity of the uncharged double-strand filament dominates the bending rigidity at NaCl concentrations above 0.01M.     

Intergenic spacer length variants in Old Portuguese bread wheat cultivars

The intergenic spacer of the ribosomal DNA is highly variable, but is location specific in the nucleolar organizer region of the chromosomes. This study provides an event of high level of polymorphism / size variation and occurrence of 14 unique phenotypes in 48 landraces of Portuguese bread wheat cultivars for IGS-amplified products obtained by PCR-RFLP technique performed with TaqI. The attendant IGS polymorphism has been used to deduce affinities between landraces. Some of the high molecular weight IGS allelic variants were also probed for their chromosomal localization by sequential silver nitrate staining and fluorescence in situ hybridization. However, only the intergenic spacer allelic variant of 3.1 kb could be successfully hybridized, and was observed to be physically located on the chromosome pair 1B in the NOR loci of the cultivar ‘Magueija’.     

E. coli promoter spacer regions contain nonrandom sequences which correlate to spacer length.

The -10 and -35 regions of E. coli promoter sequences are separated by a spacer region which has a consensus length of 17 base-pairs. This region is thought to contribute to promoter function by correctly positioning the two conserved regions. We have performed a statistical evaluation of 224 spacer sequences and found that spacers which deviate from the 17 base-pair consensus length have nonrandom sequences in their upstream ends. Spacer regions which are shorter than 17 base-pairs in length have a significantly higher than expected frequency of purine-purine and pyrimidine-pyrimidine homo-dinucleotides at the six upstream positions. Spacer regions which are longer than 17 base-pairs in length have a significantly higher than expected frequency of purine-pyrimidine and pyrimidine-purine hetero-dinucleotides at these positions. This suggests that the nature of the purine-pyrimidine sequence at the upstream end of spacer regions affect promoter function in a manner which is related to the spacer length. We examine the spacer sequences as a function of spacer length and discuss some possible explanations for the observed relationship between sequence and length.     

Ribosomal gene spacer length variability in cultivated and wild rice species

Summary Restriction fragment length polymorphism of the rDNA spacer was studied in the genus Oryza using a cloned rice rDNA probe. One-hundred-five accessions, including 58 cultivated rice and 47 wild species with various genome types, were analysed. Seven size classes differing from one another by an increment of ca. 300 bp were observed amongst the Asiatic cultivated rice of the species O. sativa. A general tendency from a smaller spacer in the Japonica subtypes to longer ones in Indica is observed. Classification as Japonica or Indica on the basis of rDNA pattern generally agrees with classification based on isozyme patterns. In contrast, African rice of the species O. glaberrima does not display any rDNA size variation. When wild species are considered, extensive variation is observed, but the fragment sizes do not fall into regularly increasing size classes except for O. rufipogon and O. longistaminata. The variation is greater in these species than in the cultivated ones.     

Extreme length and length variation in the first ribosomal internal transcribed spacer of ladybird beetles (Coleoptera: Coccinellidae)

DNA sequences of the first ribosomal internal transcribed spacer (ITS1) were isolated from 10 ladybird beetle species (Coleoptera: Coccinellidae) representing four subfamilies (Coccinellinae, Chilocorinae, Scymninae, and Coccidulinae). The spacers ranged in length from 791 to 2,572 bp, thereby including one of the longest ITS1s and exhibiting one of the most extreme cases of ITS1 size variation in eukaryotes recorded to date. The causes of length variation were therefore analyzed. Almost no putatively homologous sequence similarities were identified for the taxa included. The only exception was for the subfamily Coccinellinae, which yielded sequence similarities in six regions of approximately 550 nucleotide positions, primarily at the 5' and 3' ends of ITS1. The majority of differences in ITS1 length between taxa could be attributed to the presence of repetitive elements with comparatively long repeat units. Repetition arose several times independently and was confined to the middle of the spacer which, in contrast to the 5' and 3' ends, had not been inferred in previous studies to be subject to functional constraints. These elements were characterized by high rates of evolutionary change, most likely as a result of high substitution rates in combination with inefficient homogenization across repeats. The repeated origin and subsequent divergence of "long" repetitive elements should thus be assumed to be an important factor in the evolution of coccinellid ITS1.     

Prophage contribution to bacterial population dynamics

Cocultures of Salmonella strains carrying or lacking specific prophages undergo swift composition changes as a result of phage-mediated killing of sensitive bacteria and lysogenic conversion of survivors. Thus, spontaneous prophage induction in a few lysogenic cells enhances the competitive fitness of the lysogen population as a whole, setting a selection regime that forces maintenance and spread of viral DNA. This is likely to account for the profusion of prophage sequences in bacterial genomes and may contribute to the evolutionary success of certain phylogenetic lineages.     

Bivalent inhibitors of glutathione S-transferase: the effect of spacer length on isozyme selectivity

Glutathione S-transferases (GSTs) are cytosolic enzymes that catalyze the conjugation of glutathione with a variety of exogenous and endogenous electrophiles. High affinity, isozyme-specific inhibitors of GST are required for use as pharmacological tools as well as potential therapeutics. The design of selective inhibitors is hindered due to the broad substrate binding capabilities of the GST enzymes. GSTs are dimeric enzymes, and therefore offer a unique discriminator for achieving inhibitor selectivity: the distance between binding sites on each monomer unit as a function of its quaternary organization. Bivalent analogs of the non-selective GST inhibitor ethacrynic acid were prepared, and selectivity for the GST A1-1 isozyme over GST P1-1 (IC50 values of 13.7 vs 1022 nM, respectively) was achieved through the optimization of the spacer length between the ethacrynic acid ligand domains.     

Restriction fragment length polymorphism of the 5'-region of the bovine ribosomal spacer repeat]

The restriction map of bovine 28S rRNA gene and adjacent 5'-spacer region was determined. The high level of intragenomic and population length polymorphism of EcoRI-BamHI restriction fragment was demonstrated to originated from the 3'-end of 28S rDNA and 5'-spacer of rDNA repeat. This polymorphism is more pronounced than the ones revealed in human and murine rDNA repeats and could be compared with genomic fingerprints obtained by M13 or minisatellite DNA hybridization probes. From family blot-panel analysis we concluded that in progeny only parental sets of length variants were inherited and that the copy number of definite variants does not change in the progeny as well. From these results it was proposed that the definite sets of linked in genome length variants are inherited independently from each other.