tRNA intergenic spacers reveal polymorphisms diagnostic for Xanthomonas albilineans.

A PCR-based detection system was developed for Xanthomonas albilineans, a pathogen of sugarcane, and other related xanthomonads, using the conserved sequence of two adjacent tRNA genes and the variable length and sequence of the spacer region between them. An appropriate region was identified as follows: tRNA genes with the same anticodon from a wide variety of bacteria were aligned and the most frequent base at each position was chosen to derive primers that would anneal to the gene in either orientation. Pairs of such primers were screened against various Xanthomonas species and members of related genera using PCR at low to moderate annealing stringency. A subset of these pairs of tRNA consensus primers gave one or more PCR products which generally displayed interspecific length variability. The primer pair 5'-3' tRNA(ala) and 3'-5' tRNA(ile) showed interspecific length polymorphisms between X. albilineans and all other Xanthomonas species examined. These PCR products were cloned and sequenced from four isolates of X. albilineans and four isolates from different pathovars of X. campestris, and the spacer length variation confirmed. Specific tRNA gene primers were derived from the tRNA gene sequences. These primers yielded a PCR product of a characteristic length within most Xanthomonas species and pathovars tested. When a primer that projected from tRNA(ala) into the 3' end of the variable intergenic spacer was used with a tRNA(ile)-specific primer, PCR was a very sensitive diagnostic test for X. albilineans-infected sugarcane and gave no product or only a faint product with other species of bacteria. The specificity of this PCR-based detection system was further enhanced by a nested PCR reaction that took advantage of the fact that the tRNA(ala)-tRNA(ile) region was found to be embedded in a 16S rRNA-23S rRNA gene spacer. By amplifying the region between the 16S rRNA gene and tRNA(ile) or between the tRNA(ala) and the 23S rRNA gene, the subsequent nested PCR product was shown to be X. albilineans-specific.

Genetic variability of Paecilomyces fumosoroseus isolates revealed by molecular markers.

Paecilomyces fumosoroseus (Deuteromycotina:Hyphomycetes) is a fungus that is potentially useful for the bio-control of economically important agricultural pests, such as whitefly (Bemisia tabaci). Arbitrarily primed PCR and PCR with tRNA consensus primers were used to analyze genetic variability among 27 P. fumosoroseus isolates, 15 of which came from the same host, B. tabaci, one P. lilacinus isolate, used as an outgroup, 9 previously unidentified Paecilomyces isolates. Fifteen 10-mer oligonucleotide primers of arbitrary sequence revealed 322 scorable binary characters. Principal coordinates and cluster analysis of characters showed that most of the P. fumosoroseus and Paecilomyces sp. isolates were in three phenetic groups with > 65% internal similarity. Two of the three arbitrary phenetic groups were closely related (76% similarity) with the third group quite different (only 14% similarity) from the first two. The phenetic groups did not correlate with geographical origin or host species. Genetic variability of isolates infecting whitefly in Florida was detected. Isolates from B. tabaci were represented in two of the three groups, and different genotypes were identified even when they were isolated from an epizootic population in India and Pakistan. There was no evidence of host-specific selection of genotypes, as has been shown in other entomopathogenic fungi. Three isolates morphologically classified as P. fumosoroseus were clustered in a phenetic group which displayed only 14% similarity to the other isolates of this species. Seven isolated that presented problems for morphological classification were found to be similar or, in three cases, identical to other P. fumosoroseus isolates that dit not present problems for morphological classification.(ABSTRACT TRUNCATED AT 250 WORDS)

Chromosome assortment in Saccharum.

Recent work has revealed random chromosome pairing and assortment in Saccharum spontaneum L., the most widely distributed, and morphologically and cytologically variable of the species of Saccharum. This conclusion was based on the analysis of a segregating population from across between S. spontaneum 'SES 208' and a spontaneously-doubled haploid of itself, derived from anther culture. To determine whether polysomic inheritance is common in Saccharum and whether it is observed in a typical biparental cross, we studied chromosome pairing and assortment in 44 progeny of a cross between euploid, meiotically regular, 2n=80 forms of Saccharum officinarum 'LA Purple' and Saccharum robustum ' Mol 5829'. Papuan 2n=80 forms of S. robustum have been suggested as the immediate progenitor species for cultivated sugarcane (S. officinarum). A total of 738 loci in LA Purple and 720 loci in Mol 5829 were amplified and typed in the progeny by arbitrarily primed PCR using 45 primers. Fifty and 33 single-dose polymorphisms were identified in the S. officinarum and S. robustum genomes, respectively (χ 2 at 98%). Linkage analysis of single-dose polymorphisms in both genomes revealed linkages in repulsion and coupling phases. In the S. officinarum genome, a map hypothesis gave 7 linkage groups with 17 linked and 33 unlinked markers. Four of 13 pairwise linkages were in repulsion phase and 9 were in coupling phase. In the S. robustum genome, a map hypothesis gave 5 linkage groups, defined by 12 markers, with 21 markers unlinked, and 2 of 9 pairwise linkages were in repulsion phase. Therefore, complete polysomic inheritance was not observed in either species, suggesting that chromosomal behavior is different from that observed by linkage analysis of over 500 markers in the S. spontaneum map. Implications of this finding for evolution and breeding are discussed.

Physical map of the genome of Rhizobium meliloti 1021.

A physical map of the genome of Rhizobium meliloti 1021 is presented. The physical sizes of the three replicons in this genome had previously been determined and are as follows: the chromosome, 3.4 Mb; pSym-b, 1.7 Mb; and pSym-a, 1.4 Mb. The physical maps for this GC-rich genome contain AT-rich restriction sites for SwaI (5'-TAAATTTA-3'), PacI (5'-TTAATTAA-3'), PmeI (5'-GTTTAAAC-3'), and, for pSym-b, SpeI (5'-ACTAGT-3'). In addition, the endonuclease I-CeuI cleaved the 23S rRNA genes in this genome, and perhaps in most eubacterial genomes. I-CeuI digestion and polymerase chain reaction amplification of rrn regions were used to determine that there are at least three rrn loci in R. meliloti, all of which are located on the chromosome. The orientation of the rrn loci was determined by Southern blotting with probes from rrn sequences located 5' and 3' to the I-CeuI site. The rrn loci are clustered in one part of the chromosome and are oriented so that transcription will occur away from a single point in the circle, as observed for the origin of replication in the Escherichia coli and Salmonella typhimurium chromosomes. Fifteen genes that had been tagged by Tn5 insertion were localized to fragments on the chromosome physical map by using the IS50 as a probe in Southern blots. In addition, glt and gap were placed on the physical map by using Southern hybridization with cloned genes. The fortuitous occurrence of SpecI site in Tn5-233 was used to physically map 10 genetically mapped Tn5-233 integrations on pSym-b and to anchor the physical map to the genetic map. Finally, we demonstrate the usefulness of the map by localizing a total of 12 previously unmapped transposon insertions in the genome. This is the first physical map of the genome of a multireplicon member of the family Rhizobiaceae as well as the first physical map of a Rhizobium chromosome.

A genetic linkage map of Saccharum spontaneum L. 'SES 208'.

The arbitrarily primed polymerase chain reaction was used to detect single-dose polymorphisms that, in turn, were used to generate a linkage map of a polyploid relative of cultivated sugarcane, Saccharum spontaneum 'SES 208' (2n = 64). The mapping population was composed of 88 progeny from a cross between SES 208 and a diploidized haploid derived from SES 208 by anther culture, ADP 85-0068. This cross allowed direct analysis of meiosis in SES 208 and gametic segregation ratios to be observed. One hundred twenty-seven 10-mer oligonucleotide primers of arbitrary sequence were selected from a pool of 420 primers used to screen the mapping parents. Three hundred thirty-six of the 420 primers amplified 4,540 loci or 13.5 loci per primer. The selected 127 primers revealed 2,160 loci of which 279 were present in SES 208 and absent in ADP 85-0068 and easily scored. Two hundred and eight (74.6%) of these 279 polymorphisms were single-dose polymorphisms (i.e., they displayed 1:1 segregation, chi 2 at 98% confidence level). Linkage analysis (theta = 0.25, LOD = 9.0 for two-point analysis, then theta = 0.25, LOD = 6.0 for multipoint analysis) of single-dose polymorphisms placed them into 42 linkage groups containing at least 2 markers. These single-dose markers span 1,500 contiguous centimorgans (cM) with 32 markers remaining unlinked (15.4%). From this 208-marker map we estimated the genome size of SES 208 to be 2,500 cM. The map has a predicted coverage of 85.1% at 30 cM, meaning that any new marker placed has an 85.1% chance of being within 30 cM of an existing marker. Furthermore, we show that SES 208 behaves like an autopolyploid because (i) the ratio of single-dose markers to higher dose markers fit the assumption of auto-octaploidy and (ii) the absence of repulsion phase linkages. This is the first genetic map constructed directly on a polyploid species for which no diploid relatives are known.

High output genetic mapping of polyploids using PCR-generated markers.

The polymerase chain reaction (PCR) with arbitrarily selected primers has been established as an efficient method to generate fingerprints that are useful in genetic mapping and genomic fingerprinting. To further increase the productivity of mapping and fingerprinting efforts, we have altered existing protocols to include the use of the Stoffel fragment, which is derived from genetically engineered Taq polymerase. We also optimized the thermal profile of the reaction to increase the number of useful primers. In mapping of the genome of Saccharum spontaneum 'SES 208', a polyploid wild relative of sugarcane, these modifications allowed for an increase of 30% in the number of loci screened per primer, and an 80% increase in the number of polymorphisms per primer. Furthermore, the enzyme cost per reaction was decreased approximately 1.6-fold. Finally, there was an increase from about 70% to about 97% in the number of primers that were useful (i.e., gave a reproducible fingerprint) using our protocol. We have placed some of these markers into linkage groups.

Analysis of large DNA from soybean (Glycine max L. Merr.) by pulsed-field gel electrophoresis.

The technique of pulsed-field gel electrophoresis (PFE) has been used to study chromosomal regions and entire genomes of several organisms. Techniques are presented for the isolation of high molecular weight DNA from embedded soybean protoplasts and the conditions for separating large DNA fragments using PFE. Digestion was detected by Southern hybridization using single copy nodulin clones. These data are being used to generate a physical map of the nodulin region(s) of the soybean genome.

Electrophoretic separation of the three Rhizobium meliloti replicons.

The megaplasmids and the chromosome from the bacterium Rhizobium meliloti 1021 were separated in preparative quantities by using transverse alternating-field gel electrophoresis. The genetic content of each electrophoretically separated band was determined by Southern hybridization with replicon-specific probes and by comparison with Agrobacterium tumefaciens transconjugants harboring either pSym-a or pSym-b megaplasmids. Pulsed-field gel electrophoresis analyses of PacI (5'-TTAATTAA-3') and SwaI (5'-ATTTAAAT-3') digests of the whole genome and of the separated replicons were used to calculate genome sizes in two R. meliloti strains. In these strains, PacI digestion yielded only four fragments for the entire genome. The sizes of the PacI fragments from R. meliloti 1021 in megabase pairs (Mb) were 3.32 +/- 0.30, 1.42 +/- 0.13, 1.21 +/- 0.10, and 0.55 +/- 0.08, for a total genome size of 6.50 +/- 0.61 Mb. Southern hybridization with replicon-specific probes assigned one PacI fragment to the chromosome of R. meliloti 1021, one to pRme1021a, and two to pRme1021b. PacI digestion of A. tumefaciens pTi-cured, pSym transconjugants confirmed these assignments. In agreement with PacI data, the addition of the six SwaI fragments from R. meliloti 1021 gave a genome size of 6.54 +/- 0.43 Mb. pRme1021a was calculated to be 1.42 +/- 0.13 Mb, 1.34 +/- 0.09 Mb, and 1.38 +/- 0.12 Mb on the basis of PacI digestion, SwaI digestion, and the migration of uncut pRme1021a, respectively. pRme1021b was calculated to be 1.76 +/- 0.18 Mb, 1.65 +/- 0.10 Mb, and 1.74 +/- 0.13 Mb on the basis of PacI digestion, SwaI digestion, and the migration of uncut pRme1021B, respectively. The R. meliloti 1021 chromosome was calculated to be 3.32 +/- 0.30 Mb, 3.55 +/- 0.24 Mb, and 3.26 +/- 0.46 Mb on the basis of PacI data, SwaI data, and the migration of uncut chromosome, respectively.

The genomes of the family Rhizobiaceae: size, stability, and rarely cutting restriction endonucleases.

The lack of high-resolution genetic or physical maps for the family Rhizobiaceae limits our understanding of this agronomically important bacterial family. On the basis of statistical analyses of DNA sequences of the Rhizobiaceae and direct evaluation by pulsed-field agarose gel electrophoresis (PFE), five restriction endonucleases with AT-rich target sites were identified as the most rarely cutting: AseI (5'-ATTAAT-3'), DraI (5'-TTTAAA-3'), SpeI (5'-ACTAGT-3'), SspI (5'-AATAAT-3'), and XbaI (5'-TCTAGA-3'). We computed the sizes of the genomes of Bradyrhizobium japonicum USDA 424 and Rhizobium meliloti 1021 by adding the sizes of DNA fragments generated by SpeI digests. The genome sizes of R. meliloti 1021 and B. japonicum USDA 424 were 5,379 +/- 282.5 kb and 6,195 +/- 192.4 kb, respectively. We also compared the organization of the genomes of free-living and bacteroid forms of B. japonicum. No differences between the PFE-resolved genomic fingerprints of free-living and mature (35 days after inoculation) bacteroids of B. japonicum USDA 123 and USDA 122 were observed. Also, B. japonicum USDA 123 genomic fingerprints were unchanged after passage through nodules and after maintenance on a rich growth medium for 100 generations. We conclude that large-scale DNA rearrangements are not seen in mature bacteroids or during free-living growth on rich growth media under laboratory conditions.

Parentage determination in maize hybrids using the arbitrarily primed polymerase chain reaction (AP-PCR).

Using a novel procedure based on the polymerase chain reaction, we have developed a rapid, efficient, and economical method for identifying plant genotypes. The arbitrarily primed polymerase chain reaction (AP-PCR) generates reproducible fingerprints from any organism, without the need for DNA sequence information. These fingerprints include DNA fragment polymorphisms that can be (1) used for varietal identification and parentage determination, (2) followed in segregating populations produced by crosses, (3) used as markers for the construction of genetic maps, and (4) used to generate dendograms of phylogenetic relationships, especially at the intraspecific level. AP-PCR requires only minute quantities of DNA (10-25 ng per reaction) and therefore can be used in situations in which DNA is limiting. We demonstrate the use of AP-PCR to identify inbred parents of hybrid maize plants in double-blind experiments.