Discrimination among cultivars of rapeseed (Brassica napus L.) using DNA polymorphisms amplified from arbitrary primers.

RAPDs (Randomly Amplified Polymorphic DNAs) were used to discriminate among 23 cultivars of oilseed rape (Brassica napus) selected from several breeding programs. A set of 100 random sequence 10-mer primers were tested, of which 70 produced bands and 22 showed evidence of polymorphism. A selection of six primers produced 23 polymorphic bands of between 300 to 2200 base pairs in size, sufficient to distinguish between the cultivars. An analysis of seed of five cultivars obtained from four different sites showed stability of banding pattern over source of seed. The analysis was repeated using four different thermocyclers, each of which produced the same band pattern. UPGMA cluster analysis indicates that the relationships among some of the cultivars is closer for those from the same breeding program than for those from different programs. The results of this study show that RAPDs can be used as a method of identification for oilseed rape cultivars.

Feature expressions: creating and manipulating sequence datasets.

Annotation of features, such as introns, exons and protein coding regions in GenBank/EMBL/DDBJ entries is now standardized through use of the Features Table (FT) language. The essence of the FT language is described by the relation 'expression-->sequence', meaning that each FT expression evaluates to a sequence. For example, the expression M74750:1..50 evaluates to the first 50 bases of the sequence with accession number M74750. Because FT is intrinsic to the database definition, it can serve as a software- and platform-independent lingua franca for sequence manipulation. The XYLEM package makes it possible to create and manipulate sequence datasets using FT expressions. FEATURES is a program that resolves FT expressions into their corresponding sequences. Annotated features can be retrieved either by feature key or by expression. Even unannotated portions of a sequence can be retrieved by user-generated FT expressions. Applications of the FT language include retrieval of subsequences from large sequence entries, generation of chromosome models or artificial DNA constructs, and representation of restriction maps or mutants.

Expression of the chlorophyll-a/b-protein multigene family in pea (Pisum sativum L.) : Evidence for distinct developmental responses.

To measure transcript levels for individual members of the Cab (chlorophyll a/b protein) multigene family in pea under a range of developmental situations, we developed a system using cDNA synthesis, the polymerase chain reaction (PCR), and chemiluminescence detection. In order to design gene-specific PCR primers for all genes, a partial genomic clone for a fifth, Type I LHCII (light-harvesting complex of photosystem II) gene, Cab-9 The Cab-9 sequence appears in the Genbank/EMBL databases under the accession number M86906 , was isolated and sequenced. All seven known Cab genes in pea are expressed in light-grown buds and leaves, including several genes previously known only from genomic clones. There appear to be at least two groups of Cab genes in pea which differ in their response to light and development. The first group (consisting of Cab-8, AB96, Cab-215 and Cab-315) includes Type I, Type II and Type III genes, shows a relatively strong response to red light, and has bud transcript levels similar to or slightly higher than leaves. The second group, consisting of the Type I genes Cab-9, AB80 and AB66, shows little or no transcript accumulation 24 h after a red light pulse, and has higher transcript levels in leaves than in buds. Transcript levels for genes in this second group appear to be lower than those of the first group in all developmental situations examined. These data indicate that there has been an evolutionary divergence of the responses to light and development among the Type I LHCII genes.

Concatemer chain reaction: a Taq DNA polymerase-mediated mechanism for generating long tandemly repetitive DNA sequences.

The concatemer chain reaction (CCR) uses Taq DNA polymerase to synthesize double- or single-stranded DNA concatemers whose length and yield can be controlled by varying the number of thermal cycling steps. Although the reactions which occur in CCR are slower and more complex than in polymerase chain reaction (PCR), the practical application of the CCR technique is simple. The CCR technique is less expensive, faster, and easier than conventional methods for producing concatemers and gives greatly improved yields. The templates used in CCR may be: (i) double-stranded concatemer templates produced by ligation, (ii) double-stranded concatemers from previous CCRs, or (iii) single-stranded oligonucleotides consisting of one copy of the sense strand repeat and a complementary but overlapping repeat for the antisense strand. Different molar ratios and lengths (masses) of the two strands of the helix may be obtained. We have used both single-stranded and double-stranded concatemers as targets for RNA hybridization. Applications of this concatemer technology are discussed, including the use of concatemers as hybridization probes or targets in applications such as run-on transcription or analysis of repetitive DNA sequences.

Characterization of a single copy gene encoding ferredoxin I from pea.

We have isolated, mapped, and sequenced a genomic clone containing the ferredoxin I (Fed-1) gene from Pisum sativum. The gene is present as a single copy per haploid genome. It has no introns, and it specifies a 753-nucleotide transcript encoding a 149-amino acid protein including a 52-residue transit peptide. Upstream sequences from Fed-1 contain several elements with similarity to transcriptional regulatory elements from RbcS and Cab genes, and gel mobility shift assays show that nuclear extracts from light-grown pea leaves contain one or more DNA binding activities specific for Fed-1 5'-flanking sequences. RbcS and Cab regulatory sequences are only weak competitors for this binding, however, and the RbcS and Cab similarities mostly lie outside of the region essential for binding. These data are discussed in terms of previously observed physiological differences between the light responses of Fed-1 and other genes.

Database bias and the identification of protein coding sequences.

A simple quantitative test for the probability that an open reading frame actually codes for a protein has been described by Tramontano and Macchiato (1986). However, their test is only valid for the special case in which both coding and noncoding sequences are represented equally. We present a generalized adaptation of their method that uses estimates for the relative proportions of coding and noncoding sequences to provide a more accurate prediction.

Pea genes associated with non-host disease resistance to Fusarium are also active in race-specific disease resistance to Pseudomonas.

A given plant species is able to resist most of the potentially pathogenic microorganisms with which it comes in contact. This phenomenon, known as non-host resistance, can be overcome only by a very small number of 'true pathogens' which can use that plant as a host. In some cases, plants have developed mechanisms for overcoming infection by specific races or strains of a true pathogen. This race-specific resistance can be easily manipulated into agronomically important cultivars by plant breeders. We have previously described nine cDNA clones which represent pea genes active during non-host resistance against the fungus Fusarium solani f. sp. phaseoli. In the present work, we have used these cDNAs as probes to compare non-host resistance with race-specific responses of peas against three races of Pseudomonas syringae pv. pisi. Five of the genes most active during non-host resistance were also active in direct correlation with the phenotypic expression of resistance in race-specific reactions of five differential pea cultivars against three races of Pseudomonas syringae pv. pisi.

Improving the efficiency of dot-matrix similarity searches through use of an oligomer table.

Dot-matrix sequence similarity searches can be greatly speeded up through use of a table listing all locations of short oligomers in one of the sequences to find potential similarities with a second sequence. The algorithm described finds similarities between two sequences of lengths M and N, comparing L residues at a time, with an efficiency of L X M X N/(SK) where S is the alphabet size, and k is the length of the oligomer. For nucleic acids, in which S = 4, use of a tetranucleotide table results in an efficiency of L X M X N/256. The simplicity of the approach allows for a straightforward calculation of the level of similarities expected to be found for given search parameters. Furthermore, the storage required is minimal, allowing for even large sequences to be compared on small microcomputers. Theoretical considerations regarding the use of this search are discussed.

The disease resistance response in pea is associated with increased levels of specific mRNAs.

A cDNA library was constructed using poly(A)(+)RNA fromPisum sativum which had been treated for 8 h with the fungusFusarium solani f. sp.phaseoli. Two thousand four hundred recombinant colonies were screened by differential colony hybridization using(32)P-labelled cDNAs prepared from RNA extracted from either noninoculated or inoculated pea tissue. cDNA clones were then selected, which showed greater hybridization with cDNA prepared from pea RNA 8 h post-inoculation than with a cDNA probe from 0 h. Seven distinct hybridization classes were chosen for further study. Northern blot analyses of total cellular RNAs inoculated for 16 h with eitherF. solani phaseoli or water demonstrated that each cDNA clone selected represents an mRNA species which increases substantially in abundance during infection.Results of(3)H-uridine pulse-labelling experiments suggested that enhanced synthesis is at least partially responsible for the accumulation of the fungus-inducible mRNAs which hybridized with the clones.

The nucleotide sequence of a new human repetitive DNA consists of eight tandem repeats of 66 base pairs.

Three cloned human DNA fragments obtained from a fibroblast genomic DNA were sequenced and identified as containing members of the well-known 300-bp Alu family of interspersed, middle-repetitive DNA sequences. One of these cloned DNA fragments, p16, also contains members of a new repetitive DNA family, which repeats several thousand times in the human genome. Each member of the new 528-bp family consists of eight tandem repeats of a 66-bp sequence. An AluI recognition site is present at the same location in each repeat, and a 25-bp sequence occurs twice (as a tandem repeat) in each of the eight repeats. There is no sequence homology between the new 528-bp family and the 300-bp Alu family, and the new family lacks the flanking 7- to 20-bp direct repeats as well as the dAMP-rich sequences characteristic of the 300-bp Alu family. Construction of a putative evolutionary tree indicates that six duplication events are needed to give rise to the eight tandemly repeated 66-bp units in the new 528-bp family.

Portable microcomputer software for nucleotide sequence analysis.

The most common types of nucleotide sequence data analyses and handling can be done more conveniently and inexpensively on microcomputers than on large time-sharing systems. We present a package of computer programs for the analysis of DNA and RNA sequence data which overcomes many of the limitations imposed by microcomputers, while offering most of the features of programs commonly available on large computers, including sequence numbering and translation, restriction site and homology searches with dot-matrix plots, nucleotide distribution analysis, and graphic display of data. Most of the programs were written in Standard Pascal (on an Apple II computer) to facilitate portability to other micro-, mini-, and and mainframe computers.