Frost resistance of 'Chinese Spring'/'Cheyenne' chromosome substitution lines under short- and long-day hardening conditions

Investigations were carried out under phytotronic conditions to study the effect of daylength on the frost resistance of a ‘Chinese Spring’/‘Cheyenne’ chromosome substitution series. The frost resistance of the 5A, 7A, 4B, 5B, 1D and 5D lines was significantly better when raised and hardened with long-day (16 h) rather than short-day (8h) illumination. The frost resistance-increasing effect of daylength could be demonstrated after freezing lines 5A and 5D at both - 10°C and -12°C. An increase in the duration of illumination in the course of preliminary growth and hardening promoted the development of a higher level of frost resistance. This positive effect was most pronounced for chromosome substitution lines, where the frost resistance was significantly better than that of ‘Chinese Spring’ even with normal daylengths.     

A Genetic Study of Frost Resistance in Wheat Callus Culture

The genetic control of frost resistance was studied in callus cultures using some of the chromosome substitution lines of the variety ‘Cheyenne’ into ‘Chinese Spring’. The survival of the calli derived from immature embryos was studied with triphenyltet-razolium chloride (TTC) and fluorescein diacetate (5DA) methods after hardening and freezing at a temperatures of -7 °C, -9 °C, -11 °C, -13 °C, and –15 °C. The donor ‘Cheyenne’ and the substitution lines 5A and 5D proved to be more frost resistant than the recipient ‘Chinese Spring1. These results are well correlated with the previously published studies when seedlings were tested under controlled conditions. Based on these results the tissue culture technique seems to be useful for testing varieties and lines for different levels of frost resistance and even for mutant selection.     

The detection of allelic variants at the recessive vrn loci of winter wheat

Substitution lines with reciprocal substitutions of chromosomes containing recessive alleles of the homoeologous group 5 chromosomeVrn genes between varieties of winter wheat with high vernalisation requirement (‘Mironovskaya 808’) and low vernalisation requirements (‘Bezostaya 1’) have been created. On this basis the genetic determination of vernalisation requirement was established. Substitution lines Mironovskaya 808 (Bezostaya 1 5A), Mironovskaya 808 (Bezostaya 1 5B), Mironovskaya 808 (Bezostaya 1 5D) and reciprocal substitution lines Bezostaya 1 (Mironovskaya 808 5A), Bezostaya 1 (Mironovskaya 808 5B) and Bezostaya 1 (Mironovskaya 808 5D) were grown under different durations of vernalisation (3, 4, 5, 6, 7 and 8 weeks) and their response was evaluated. Photoperiodic sensitivity of the original parental genotypes was also determined. Reciprocal substitution lines of the same chromosome that carries the same vrn allele responded differently to vernalisation deficit. Differences have been shown between all group 5 reciprocal substitutions. Lines carrying chromosomes 5A and 5D of Mironovskaya 808 had a high vernalisation requirement whereas lines carrying chromosome 5B of Bezostaya 1 (vrn2^B) had a low vernalisation requirement. The reciprocal lines had a reverse requirement. This explains the different vernalisation requirements of the original varieties: Mironovskaya 808 with a high vernalisation requirement carries two alleles (vrn1^M and vrn3^M) in its genotype that increase the vernalisation requirement, whereas Bezostaya 1 with a lower requirement for vernalisation contains only one such allele (vrn2^B). By combination of the alleles in the lines with the substitution of chromosome 5B carrying vrn2 allele that in both original genotypes work inversely to the other alleles, transgressive genotypes have been formed: genotype vrn1^M vrn2^B vrn3^M determines a higher vernalisation requirement than original variety Mironovskaya 808, and genotype vrn1^B vrn2^M vrn3^B determines a lower vernalisation requirement than the original Bezostaya 1. An incomplete vernalisation requirement prolonged the time to heading, with exponential dependence on the vernalisation deficit, or prevented heading altogether. The original varieties further differed in photoperiodic sensitivity (Mironovskaya 808 sensitive, Bezostaya 1 less sensitive) that also influenced the background of substitution lines. The impact of the background on the heading time showed itself by about one week difference between Mironovskaya 808 and Bezostaya 1 grown under 8 weeks vernalisation and normal photoperiod. The difference between the lines with Mironovskaya 808 background and the lines with Bezostaya 1 background was approximately the same and was not significantly changed in different vernalisation variants of the lines. This difference may be caused by different photoperiodic sensitivity of the original varieties, but also by other genes, such as genes of earliness per se. This revised version was published online in July 2006 with corrections to the Cover Date.     

Inter-varietal chromosome substitution lines in wheat — revisited

Summary The difficulties in developing inter-varietal chromosome substitution lines in wheat are reviewed. The use of genetical, cytological and molecular markers is suggested as a way of overcoming them. These difficulties and the use of markers, as well as the need to develop duplicate lines to detect background variation, are described using the development and analysis of the Cappelle-Desprez (Bezostaya 1) chromosome substitution set as an example. The effects of substituting Bezostaya 1 chromosomes on final plant height and adult-plant resistance to yellow rust are reported. The large number of aneuploids and substitution lines available in wheat provides a tremendous, international resource, which should be exploited in the future.     

Reciprocal substitutions analysis of freezing resistance in wheat (Triticum aestivum L.)

To investigate the effects of individual chromosomes on freezing resistance, as well as their interactions with the genetic background, reciprocal sets of chromosome substitution lines between two hard red winter wheat cultivars, ‘Cheyenne’ and ‘Wichita’, were used in this study. Duplicate lines for each chromosome were included to check background homogeneity. Two experiments were carried out in complete block designs with two replications for each duplicate. Crown and leaf water content and leaf wet weight were measured in the field experiments. Crown survival, electrolyte leakage and 50% lethality temperature (LT50) were measured in the laboratory. The results showed that ‘Cheyenne’ was more resistant than ‘Wichita’. Crown survival was significantly correlated with crown water content, crown wet weight and electrolyte leakage. Chromosomes 6A, 3B and 5D substituted from ‘Wichita’ into ‘Cheyenne’ (‘CNN‐WI’), decreased the crown survival, and increased membrane stability, crown water content and crown wet weight of ‘Cheyenne’. Thus, these chromosomes from ‘Wichita’ decreased freezing resistance in ‘Cheyenne’. Reciprocally, chromosomes 5A, 5D, 3B and 4D from ‘Cheyenne’ into ‘Wichita’ increased crown survival and decreased crown water content and crown wet weight of ‘Wichita’. It was concluded that these chromosomes from ‘Cheyenne’ cause freezing resistance in ‘Wichita’ and carry freezing‐resistance genes.     

The effect of the homoeologous group 5 chromosomes with different vrn loci on growth phases and quantitative characters of wheat

The differences between effects of homoeologous group 5 chromosomes on growth phases and agronomic characters were studied by using reciprocal substitution lines between a winter wheat cultivar with a high vernalization requirement (Mironovskaya 808) and one with lowvernalization requirement (Bezostaya 1), in which the presence of different recessive vrn alleles is supposed. The two cultivars and the substitution lines Mironovskaya 808 (Bezostaya 1 5A), Mironovskaya 808 (Bezostaya 1 5B), Mironovskaya 808 (Bezostaya 1 5D), Bezostaya1 (Mironovskaya 808 5A), Bezostaya 1 (Mironovskaya 808 5B),Bezostaya 1 (Mironovskaya 808 5D) were grown at 10 different sowing dates. The results showed that differences between the homoeologous group 5 chromosomes of Mironovskaya 808 and those of Bezostaya 1influenced the growth phases in addition to the impact by the genetic background and sowing date. We inferred from the analysis and comparison of their effect on vernalization response that vrn loci on these chromosomes influence growth phases. It is probably due to pleiotropic effects of the loci. The rare occurrence of significant interactions between group 5 chromosomes × sowing dates probably indicates independence of their effect. Agronomic characters were also markedly influenced by sowing date and the difference in backgrounds between Mironovskaya 808 and Bezostaya 1. A significant impact by at least two of the chromosomes on almost all studied characters was detected. The chromosomes affected the combined characters in the order5D>5B>5A and the positive value of the differences suggests that a content of Mironovskaya 808 chromosomes is more advantageous. It was possible to find certain indices in some agronomic traits, supporting the idea that the expression of some characters can also be connected to vernalization requirement and thus to the expression of the vrn loci. This supposition is most probable in the number of tillers and number of spikes. In some traits significant interactions occurred between homoeologous group 5 chromosomes × genetic background. Sporadic and low significance between homoeologous group 5 chromosomes × sowing dates suggest that the genetic effect of these chromosomes is independent of environmental conditions. This revised version was published online in July 2006 with corrections to the Cover Date.     

Chromosomal location of genes affecting tissue-culture response in wheat

Six ‘Chinese Spring/Triticum spelta’ substitution lines for chromosomes 1A, 1D (duplicates), 3D (duplicates), 6D, and one ‘Chinese Spring/ Marquis’ substitution line for chromosome 2B were studied for tissue-culture response (TCR). The results reported here indicate that chromosomes 2B and 6D are critical for TCR, whereas chromosome ID affects callus weight only. Chromosomes 1A and 3D were not found to be critical, however, these chromosomes may carry genes with minor effects.     

Involvement of Chromosomes 5A and 5D in Cold-Induced Abscisic Acid Accumulation in and Frost Tolerance of Wheat Calli

The relationship between frost tolerance and abscisic acid (ABA) accumulation was studied in callus cultures of three wheat cultivars differing in the level of frost-tolerance, and of the 5A and 5D chromosome substitution lines from the frost-tolerant variety ‘Cheyenne’ into frost-sensitive ‘Chinese Spring’. Following cold hardening, the increase in ABA level in the calli of the two frost tolerant cultivars was significantly higher than in those of the frost-susceptible cultivar. Similarly, in 5A and 5D substitution lines, significantly higher ABA levels were detected than in the recipient ‘Chinese Spring’. One week-long ABA treatment at 26 °C induced a significantly higher level of frost tolerance than that achieved by cold hardening, irrespective of the frost sensitivity of the examined genotypes.     

Effects of homoeologous group 1 and 6 chromosomes of the Cappelle-Desprez (Bezostaya 1) substitution lines on aspects of bread-making quality of wheat

Summary The group 1 and 6 inter-varietal chromosome substitution lines of Cappelle-Desprez (Bezostaya 1) were intercrossed along with the donor and recipient varieties, Cappelle-Desprez and Bezostaya 1, to give 36 genetically different families. The analysis of the means of these families showed that variation in SDS-sedimentation volume fitted a predominantly additive model. There were no significant within or between chromosome interactions among the group 1 and 6 chromosomes. Nor was there any evidence for interactions between these chromosomes and those of the background. Significant dominance/within chromosome interactions amongst the background chromosomes were however detected. Some of the positive effects on SDS-sedimentation were associated with increased grain hardness. Chromosome effects on % grain protein were not correlated with SDS-sedimentation.     

QTL alleles from a winter feed type can improve malting quality in barley

Mapping quantitative trait loci (QTLs) responsible for malting quality traits in barley populations has been the main genetic approach to malting quality breeding. A ‘winter × spring’ doubled haploid barley population ‘Nure’ × ‘Tremois’, where such traits were segregating, has been recently developed. Our objective was to map QTLs for malting quality from 2 years of trials in two contrasting locations. QTLs were found on six chromosomes, with a main cluster on chromosome 1H. For wort viscosity and malt extract, favourable alleles at two loci on chromosome 5H were carried by the winter feeding parent ‘Nure’. Doubled‐haploids with higher quality than the spring malting cultivar ‘Tremois’ showed either a facultative or a winter growth habit and a level of frost tolerance comparable with that of the winter tolerant parent ‘Nure’. Markers and QTLs of quality traits were further validated on a separate set of DH lines, coming from the same cross, by means of marker‐assisted selection. This showed that, at least in the present cross combination, positive contributions to malting quality can be found in winter feed barley.