Detection of genetically divergent clone mates in apomictic dandelions.

This study aims to identify genetically diverged clone mates in apomictic dandelions. Clone mates are defined as individuals that may have diverged as a result of mutation accumulation and that have undergone only clonal reproduction since their most recent common ancestor. Based on distinctive morphology and an aberrant and rare chloroplast haplotype, northwest European individuals of Taraxacum section Naevosa are well suited for the detection of clonal lineages in which mutation has occurred. In the case of strictly clonal reproduction, nuclear genetic variability was expected to be hierarchically organized. Nucleotide polymorphisms in internal transcribed spacer (ITS) sequences, however, were incompatible with a clonal structure of the Norwegian individuals, probably due to persistent ancestral polymorphisms that pre-date the origin of the Naevosa clone. This interpretation is supported by the presence of ITS variants in section Naevosa that were also found in distantly related dandelions. In contrast to the ITS sequence data, amplified fragment length polymorphisms (AFLPs), isozymes and microsatellites strongly supported the contention of prolonged clonal reproduction and mutation accumulation in Norwegian Naevosa. Because these markers are generally considered to be more variable and more rapidly evolving than ITS sequences, mutations in these markers probably evolved after the origin of the clone. Within the Norwegian clone, a surprising number of markers distinguished the clone mates. As a consequence, incorporation of mutation in the detection of clone mates is anticipated to have a big impact on estimates of size, geographical range and age of clones as well as on experimental designs of studies of clonal plants.

Hairpins involving both inverted and direct repeats are associated with homoplasious indels in non-coding chloroplast DNA of Taraxacum (Lactuceae: Asteraceae).

Sequence variation in 2.2 kb of non-coding regions of the chloroplast genome of eight dandelions (Taraxacum: Lactuceae) from Asia and Europe is interpreted in the light of the phylogenetic signal of base substitutions vs. indels (insertions-deletions). The four non-coding regions displayed a total of approximately 30 structural mutations of which 9 are potentially phylogenetically informative. Insertions, deletions, and an inversion were found that involved consecutive stretches of up to 172 bases. When compared to phylogenetic relationships of the chloroplast genomes based on nucleotide substitutions only, many homoplasious indels (33%) were detected that differed considerably in length and did not comprise simple sequence repeats typically associated with replication slippage. Though many indels in the intergenic spacers were associated with direct repeats, frequently, the variable stretches participated in inverted repeat stabilized hairpins. In each intergenic spacer or intron examined, nucleotide stretches ranging from 30 to 60 bp were able to fold into stabilized secondary structures. When these indels were homoplasious, they always ranked among the most stabilized hairpins in the non-coding regions. The association of higher order structures that involve both classes of repeats and parallel structural mutations in hot spot regions of the chloroplast genome can be used to differentiate among mutations that differ in phylogenetic reliability.

Correlation of physical maps and some genetic functions in the genomes of the kappa-theta phage family of Bacillus licheniformis.

Natural recombinant genomes between several, phenotypically distinct forms of phages kappa and theta were isolated and characterized by DNA restriction fragment mapping and electron microscopic heteroduplex analysis. The phenotypes of the recombinants were correlated with the physical maps of the genomes, and several genetic functions were therefore defined and mapped. All genes necessary for the assembly of infectious virus particles map in a contiguous tract of DNA comprising about 20 kb, or nearly one third of the genome length. No DNA homology occurs within these domains of the two genomes, so that homologous recombination does not take place here and phenotypic mixing of the phages is eo ipso excluded. Other regions of heterology contain regulatory genes responsible for the lytic or temperature character of the phages, and for exclusion of phage kappa by 9.

Physical mapping of LP51 and LP52 prophages of lysogenic strains of Bacillus licheniformis.

The physical maps of the LP51 and LP52 prophages in lysogenic strains of Bacillus licheniformis were constructed on the basis of data obtained by hybridization of phage DNA probes with Southern blots of restricted DNA of the lysogens. The data were compatible with the Campbell model for chromosomal integration; the attP site was mapped at 58.7-61.8 map units of the genomes of both phages. Identification of prophage-host DNA junction fragments indicated the presence of a unique attB site on the bacterial chromosome; the set of junction fragments in the strain B. licheniformis ATCC 10716 was identical to that of ATCC 11946, but different from ATCC 8187. Both the LP51 and LP52 phages used the same integration sites. Upon reinfection with either phage, the cured strains UM12 and UM18 (i.e. 10716 and 11946 cured of LP52 or LP51, respectively) turned out to be integration deficient. In surface cultures the reinfected bacteria could be maintained in the lysogenic state without, however, integrating the phage genome; when these bacteria were passaged in submerged cultures, several modes of anomalous integration were observed, and the phage segregated into a variety of forms, discernible by virulence and plaque morphology. In liquid cultures of UM12(LP51) or UM12(LP52) lytic forms finally predominated, while most lysogenized UM18 were converted into defective lysogens which contained a defective prophage in a stably integrated form.

Denaturation maps of Bacillus licheniformis phages LP52 and theta DNAs.

Employing electron microscopy (EM) of partially denatured DNAs of phages LP52 and theta, distinct denaturation maps were determined and correlated with published restriction and heteroduplex maps. The pattern of early melting regions is similar although the two phages share only 50% nucleotide sequence homology.

An electron microscopic heteroduplex study of the sequence relations between the bacteriophages LP52 and theta.

The genomes of the phylogenetically related but morphologically distinct bacteriophages LP52 and theta (theta) were compared by electron microscopic heteroduplex analysis. The heteroduplex maps were aligned with known restriction maps. In the heteroduplices of LP52 DNA (63.8 kb) with the DNA of the lytic phage theta c (65.9 kb) the tracts of homologous DNA cover about 50% of the genome length and are interspaced by four large and ten smaller non-base-paired regions. The largest block of non-homologous DNA (18.9 kb), represents the right-hand end and there is an unmatched piece of DNA at the left-hand end as well. Most of the heterology is due to substitution resulting in the conservation of the total length of DNA; the three insertions/deletions amount to less than 3.2% of the genome length. Heteroduplices between the DNAs of phage LP52 and the temperate phage theta 1 (65.0 kb) resembled those of LP52:theta c except for the absence of minor loops. Heteroduplex theta c:theta 1 displayed about 9% heterology in seven separate loops which coincided with sections of diversity on the restriction maps; 4.8% of theta 1 DNA did not hybridize with either theta c or LP52 DNA.