Identification of molecular markers for aluminium tolerance in diploid oat through comparative mapping and QTL analysis.

The degree of aluminium tolerance varies widely across cereal species, with oats (Avena spp.) being among the most tolerant. The objective of this study was to identify molecular markers linked to aluminium tolerance in the diploid oat A. strigosa. Restriction fragment length polymorphism markers were tested in regions where comparative mapping indicated the potential for orthologous quantitative trait loci (QTL) for aluminium tolerance in other grass species. Amplified fragment length polymorphism (AFLP) and sequence-characterized amplified region (SCAR) markers were used to provide additional coverage of the genome. Four QTL were identified. The largest QTL explained 39% of the variation and is possibly orthologous to the major gene found in the Triticeae as well as Alm1 in maize and a minor gene in rice. A second QTL may be orthologous to the Alm2 gene in maize. Two other QTL were associated with anonymous markers. Together, these QTL accounted for 55% of the variation. A SCAR marker linked to the major QTL identified in this study could be used to introgress the aluminium tolerance trait from A. strigosa into cultivated oat germplasm.

A molecular linkage map with associated QTLs from a hulless x covered spring oat population.

In spring-type oat ( Avena sativa L.), quantitative trait loci (QTLs) detected in adapted populations may have the greatest potential for improving germplasm via marker-assisted selection. An F(6) recombinant inbred (RI) population was developed from a cross between two Canadian spring oat varieties: 'Terra', a hulless line, and 'Marion', an elite covered-seeded line. A molecular linkage map was generated using 430 AFLP, RFLP, RAPD, SCAR, and phenotypic markers scored on 101 RI lines. This map was refined by selecting a robust set of 124 framework markers that mapped to 35 linkage groups and contained 35 unlinked loci. One hundred one lines grown in up to 13 field environments in Canada and the United States between 1992 and 1997 were evaluated for 16 agronomic, kernel, and chemical composition traits. QTLs were localized using three detection methods with an experiment-wide error rate of approximately 0.05 for each trait. In total, 34 main-effect QTLs affecting the following traits were identified: heading date, plant height, lodging, visual score, grain yield, kernel weight, milling yield, test weight, thin and plump kernels, groat beta-glucan concentration, oil concentration, and protein. Several of these correspond to QTLs in homologous or homoeologous regions reported in other oat QTL studies. Twenty-four QTL-by-environment interactions and three epistatic interactions were also detected. The locus controlling the covered/hulless character ( N1) affected most of the traits measured in this study. Additive QTL models with N1 as a covariate were superior to models based on separate covered and hulless sub-populations. This approach is recommended for other populations segregating for major genes. Marker-trait associations identified in this study have considerable potential for use in marker-assisted selection strategies to improve traits within spring oat breeding programs.

The identification of random amplified polymorphic DNA markers for daylength insensitivity in oat.

Daylength insensitive accessions of Avena sativa L. are being used to develop cultivars that will flower normally when grown under short or long photoperiods. Field data indicate that the insensitivity trait is under the control of a single dominant gene, designated Di1. The random amplified polymorphic DNA (RAPD) technique and bulk segregant analysis of daylength sensitive and insensitive plants were used to find markers for this gene. Five of 200 random decamer primers tested produced polymorphic bands, which were shown to be linked to the trait using 30 homozygous insensitive and 30 homozygous sensitive F3 individuals. Three of the markers produced a band in the presence of the dominant allele, and two in its absence. Segregation analysis showed that markers 221 and 136 could be mapped to within 9.8 +/- 4.6 and 13.9 +/- 5.4 cM of the trait, respectively; that is, close enough to be useful in a breeding program. A study of different cultivars suggested that the band produced by primer 136 is actually the more closely linked marker and the only one present in the original Di1 gene donor CAV2700. The possibility of using both markers in populations derived from different cultivars is discussed.

Identification of an RAPD marker for the crown rust resistance gene Pc68 in oats.

The feasibility of using bulk segregant analysis to identify molecular markers for disease resistance genes in oats was investigated, utilizing random primers in conjunction with polymerase chain reaction technology. Random primers were screened for the amplification of polymorphic DNA fragments on two pools of genomic DNA isolated from plants that were homozygous for the presence and absence of the crown rust resistance gene Pc68. Ten primers were identified that amplified polymorphic DNA fragments. Of these, one was tightly linked, in repulsion, to the target gene, while the other nine were not linked to this trait. The relatively low cost of polymerase chain reaction technology, coupled with rapid leaf disc genomic DNA extraction techniques should result in the effective use of this linked marker in oat breeding selection programs.

Enhancement and regulation of extracellular protein production by Bacillus brevis 47 through manipulation of cell culture conditions.

Bacillus brevis 47 was cultivated in 2 liter fermentors in semidefined media containing polypeptone with or without glucose or fructose. Neither sugar was essential for growth or extracellular (S-layer) protein production, and 2.5 to 3.0 g/L protein was accumulated in the medium. When present, glucose was used very slowly, however, fructose was used much more quickly. Dramatic changes in metabolic indicators (dissolved oxygen and pH) were seen when fructose became depleted, and protease was produced, decreasing the amount of protein ultimatelv accumulated in the medium. Using the change in dissolved oxygen as a marker for the time of addition, polypeptone, fructose, or both were used to stimulate protein production. With the addition of polypeptone, on stimulation was achieved, but protease production was suppressed. Addition of fructose did result in a small stimulation of protein production (to 5 g/L) if added once. Further additions resulted in more growth, but no increase in protein production. Various combinations of polypeptone and fructose were also used, with the most effective combination (fructose added early, fructose and polypeptone added later) resulting in an accumulation of 15 g/L protein in the medium. This is comparable to that seen when B. brevis 47 is grown in a complex glucose medium and stimulated with polypeptone addition at 21 hours. These results are discussed with respect to the structure and function of S-layer proteins, as well as the use of this organism for the production of heterologous proteins.

A rapid and efficient method to remove labelled molecular probes from nucleic acids immobilized on solid supports.

A rapid and efficient method is described for the removal of radio-active molecular probes from nucleic acids immobilized on nylon membranes. This method involves boiling in distilled water in a microwave oven. This procedure can be completed within ten minutes, does not require the use of any buffers or reagents, and produces results comparable with conventional buffer-wash procedures recommended by the suppliers of the transfer membranes.