Construction of a genetic linkage map for witloof (Cichorium intybus L. var. foliosum Hegi)

A genetic linkage map based on an intraspecific cross between two inbred lines of witloof‐chicory (Cichorium intybus L. var. foliosum Hegi) has been constructed. In total, 129 RAPD markers were scored in 565 F₂ plants. Grouping of these markers at a LOD of threshold 4.0 resulted in nine linkage groups, which is equal to the chicory haploid genome. The nine linkage groups covered 609.6 cM. All 129 RAPD markers were linked to one of the nine groups. Three RAPD markers could not be mapped. Out of the 126 remaining RAPD markers, 18 showed segregation distortion with significance value of P < 0.01.     

Identification of commercial chicory cultivars for hydroponic forcing and their phenetic relationships revealed by random amplified polymorphic DNAs and amplified fragment length polymorphisms

One‐hundred and twenty‐four amplified fragment length polymorphism (AFLP) and 49 random amplified polymorphic DNA (RAPD) markers have been used to distinguish between 20 and 23 commercial chicory cultivars, respectively. These were all Cichorium intybus var. foliosum F₁ hybrids, currently used in hydroponic forcing. Five‐hundred and twenty RAPD primers (OPERON) were tested, of which 156 resulted in reproducible patterns and 26 yielded polymorphisms. Two‐hundred and fifty‐six AFLP primer‐combinations were tested and six combinations were selected for identification purposes. Similarity indices were measured and clustering has been done using pairwise comparison. Both types of marker provide similar conclusions. Two major clusters are formed, representing late and early cultivars. All cultivars were identified using 10 informative RAPD primers or three AFLP primer combinations. A low degree of polymorphism was detected between some early cultivars, suggesting a narrow genetic base in their breeding strategy.     

QTL analysis of important pith characteristics in a cross between two inbred lines of chicory (Cichorium intybus var. foliosum): a preliminary study

The genetic basis of pith characteristics in chicory (Cichorium intybus L. var. foliosum Hegi) was investigated. Quantitative trait loci (QTL) were mapped in an F2 population (565 F2 plants) derived from a cross between two inbred chicory lines. A molecular marker linkage map of this cross had previously been constructed based on 129 random amplified polymorphic DNA markers. Each F2 plant was selfed and plant characteristics were measured in the F3 populations. Although variation in pith characteristics was largely environmentally influenced, QTL for the characteristics length of pith, browning of the pith, hollow pith and apple pith were detected in many linkage groups. Interactions between QTL were found for the three characteristics: pith length, browning of the pith and hollow pith. The QTL detected confirmed the early forcing suitability of the one parent inbred line and late forcing suitability of the other.     

Varietal identification in Cichorium intybus L. and determination of genetic purity of F1 hybrid seed samples, based on RAPD markers

Random amplified polymorphic DNA (RAPD) markers were used to distinguish between several Cichorium intybus genotypes, comprising four white witloof inbred lines, three red witloof experimental inbred lines and a number of F1 hybrids derived from two white parents. Amplification conditions and reproducibility of RAPD patterns were examined. Comparison of polymerase chain reaction (PCR) products obtained by using 100 10-mer arbitrary primers allowed identification of all the lines analysed. With several primers, we defined line-specific RAPD markers, while with others polymorphism was more extensive, revealing several RAPD markers for several lines. All the differences were confirmed both on individual heads and young seedlings for each genotype. Because of the Mendelian segregation of these molecular markers, this method was applied to evaluate the genetic purity of F1 hybrid seed samples.     

Electrophoretic Analysis of Eleven Isozyme Systems and their Possible Use as Biochemical Markers in Breeding of Chicory (Cichorium intybus L.)

Polymorphism and ontogeny of 11 chicory (Cichorium intybus L.) enzymatic systems have been analyzed by native polyacrylamide gel electrophoresis, namely: leucine aminopeptidase, phosphoglucomutase, shikimate dehydrogenase, glutamate oxaloacetate transaminase, superoxide dismutase, isocitrate dehydrogenase, esterase, phosphorylase, glucose-6-phosphate dehydrogenase, 6-phos-phogluconate dehydrogenase and glucose phosphate isomerase. The use of these systems as biochemical markers is discussed.     

Monogenic Semidominant Sulfonylurea Resistance in a Line of White Chicory

This paper reports on a chlorsulfuron-resistant line of white chicory (Cichorium intybus cv. ‘Witloof’) regenerated from non-mutagenized cell cultures. The resistance was inherited as a monogenic semi-dominant trait. Homozygous resistant individuals withstood doses of herbicide 1500 to 2000-fold higher than the susceptible ones, whereas this ratio was around 300 for the heterozygotes. Cross-resistances to seven other sulfonylureas and to one imidazolinone were revealed, leading to the conclusion that this resistance could be due to mutation of the target enzyme.     

Morphological and Physiological Responses of Plantain (Plantago lanceolata) and Chicory (Cichorium intybus) to Water Stress and Defoliation Frequency

Plants are often subjected to periods of water stress. There are little data examining the effect of water stress on the forage species Plantago lanceolata and Cichorium intybus. In two pot experiments with P. lanceolata and C. intybus, morphological responses under optimum, dry, and very‐dry water treatments with weekly, fortnightly and 3‐weekly defoliation intervals and physiological responses under optimum and very‐dry water treatments were measured. A third experiment compared the rooting depths of P. lanceolata and C. intybus under field conditions. These findings suggest that both P. lanceolata and C. intybus can survive and continue to grow under water stress conditions with the main differences between the two species being attributable to morphological characteristics (root mass, taproot diameter and shoot mass fraction) rather than differences at a physiological level. Overall, the results suggest plantain may be more productive under moderate drought due to its greater shoot mass fraction, whereas chicory may be more productive and persistent under severe drought due to its greater root mass, taproot diameter and root depth under field conditions.     

Influence of Rhizosphere Ionic Strength on Mineral Composition, Dry Matter Yield and Nutritive Value of Forage Chicory

Animal manure and urine deposition can cause localized patches of high ionic strength (IS) soil in pastures, influencing plant production, nutritive value and sward composition. Chicory (Cichorium intybus L.) appears to thrive in high‐nutrient input situations, but no information is available on chicory response to increasing IS. In a greenhouse experiment, we evaluated the effect of rhizosphere ionic strength (0.9, 4.0, 8.0 and 12.0 dS m^?1) on productivity and nutritive value of chicory. Dry matter production decreased linearly as IS increased. Shoot concentrations for Ca, Na and Cl increased as IS increased. All mineral concentrations, except Cu, were substantially higher than or equal to the highest concentrations reported for forages. At all IS, nitrate‐N and K exceeded maximum recommendation for ruminant diets. The sodium level could be high enough to reduce dry matter intake at the highest IS level. Crude protein and energy estimates indicate chicory would support production levels equivalent to those of other high‐quality forages. In vitro organic matter disappearance increased as IS increased. Chicory as a component of a forage mixture could help stabilize forage yield in pastures and also shows promise for use as a nutrient mop in feedlot areas, where excess soil nutrients are a problem.     

Forage Chicory: A Plant Resource for Nutrient-Rich Sites

Grazing livestock create localized nutrient patches that increase soil ionic strength (IS) and influence plant productivity. The ability of plant root systems to control ion absorption and flux to xylem, and to sequester ions reaching leaf tissue in bound, nontoxic forms are means of minimizing IS. A greenhouse experiment was conducted to determine the growth and mineral acquisition responses of forage chicory (Cichorium intybus L. cv. Grasslands Puna) to increasing (0.9, 4, 8, and 12 dS m^?1) IS in the rhizosphere obtained by additions of NaCl/CaCl₂ (1 : 1 m ratio). Plants were harvested four times after planting (20, 27, 34 and 41 d) to identify responses as a function of time. Increased accumulation and localization of Na in roots in comparison to shoots suggested that chicory restricted Na transport to shoots, and that insoluble Na in tissues increased with increasing IS. Soluble cations in shoots were about 50 % of total cations, irrespective of rhizosphere IS and Na uptake. Differences in the cation:anion ratio could not be accounted for by organic acid concentrations in chicory, but substantial accumulation of nonstructural carbohydrates as fructans in roots could contribute to charge balance. Our results demonstrate that forage chicory has moderate tolerance to IS, suggesting that it might be a useful species for sites with potential for IS. Chicory growth would probably be sustained under IS conditions, and the resultant vigorous growth and accumulation of mineral nutrients in shoots would contribute to acceptable nutritive value for grazing livestock. Plants capable of growing in and acquiring nutrients from nutrient‐laden patches in the sward would help minimize erosion and nutrient transport, with positive benefits for water and soil quality.     

Genetic variation for nitrate content between cultivars of endive (Cichorium endiviae L.)

Summary A high nitrate content is a negative quality trait in vegetables. Endive (Cichorium endiviae L.) contributes considerably to human nitrate intake in Northwestern Europe. A collection of 125 commercially available cultivars of endive were grown on nutrient solution and evaluated for genetic variation between cultivars for the nitrate concentration in expressed sap. In two subsequent experiments 23 cultivars, representing the range of nitrate levels found in the first experiment, were grown both in soil and on nutrient solution. There were significant differences between cultivars in nitrate accumulation. Cultivar Vicor consistently had the lowest nitrate content. Averaged over all experiments the nitrate concentration in expressed sap of this cultivar was 0.7 g·l^-1 (19%) lower than that of two recommended cultivars. The results indicate that there may be some possibilities to reduce the nitrate content of endive by cultivar choice or breeding. However, the chances of obtaining a substantial reduction of the nitrate content of endive seem less than in some other crops, such as lettuce. The nitrate levels of the cultivars showed interactions with experiments and growth medium. There was no correlation between the cultivar means for the concentrations of nitrate and chloride, or between the concentration of nitrate and the osmolarity of the plant sap.     

Identification of broad bean cultivars based on isozyme patterns

Summary With the increasing rate of new cultivar production for different crop plants, there is great need for methods of identifying each cultivar discriminatingly. Starch gel electrophoresis was employed to study the differences between the esterase and cathodal peroxidase isozyme patterns of 40 broad bean (Vicia faba L.) cultivars. A total of 10 and 17 medium to darkly stained bands were obtained for esterase and peroxidase systems, respectively. Bands from each enzyme system could be gropuped into three zones. Bands belonging to zone 1 of esterase (E₁) and zones 2 and 3 of peroxidase (P₂ and P₃) were quite distinct, stained intensely, and were especially useful for identification purposes.The differences in banding patterns among cultivars of the same origin were as great as those of cultivars of unrelated origin. A large proportion of the cultivars could be completely differentiated using both of the isozyme systems. There were no bands present in either enzyme system which were common to all cultivars.     

Selection for resistance to Plasmodiophora brassicae Wor. in oriental subspecies of Brassica rapa L.

Summary Selection for resistance to Plasmodiophora brassicae Wor. in oriental groups of Brassica rapa L.Two hundred and sixty-five cultivars of leafy, oriental bassicas were tested for resistance to 18 collections of Plasmodiophora brassicae, the causal agent of clubroot. The tests were conducted in the greenhouse at low and high level inoculum concentrations. Eleven cultivars of B. rapa pe-tsai, five cultivars of B. rapa pak-choy and three cultivars of B. rapa choy-sum consistently segregated for resistance at the lower concentration of inoculum (1000 spores/ml). All 265 cultivars were susceptible at the higher concentration (1 000 000 spores/ml). Three cultivars were used in pedigree and recurrent selection schemes for increased resistance. After three cycles of selfing resistant individuals, significantly more resistant S₃ lines were derived from each cultivar. Lines derived from two cultivars. Chinese White and PI 257236, continued to improve with each cycle of selection and demonstrated increased resistance to higher levels of inoculum (up to 1 000 000 spores/ml) New cultivars based on intercrosses of S₂ resistant individuals also had significantly better resistance than the original cultivar. After two cycles of selection in the third cultivar, PI 419007, resistance did not increase and its S₂ mass did not differ significantly from the original cultivar. Evidence that indicates resistance is pathotype-non-differential and offers an alternative to major gene, pathotype-differential types of resistance currently being introduced to the leafy oriental brassicas from other Brassica rapa groups.     

Identification of powdery-mildew-resistance genes in common wheat (Triticum aestivum L. em. Thell.). V. Old German cultivars and cultivars released in the former GDR

A total of 59 old wheat cultivars grown in Germany prior to 1960 were tested for mildew response using a collection of 12 differential isolates of Erysiphe graminis DC f. sp. tritici Marchal (Blumeria graminis (DC) Speer f. sp. tritici). Nineteen cultivars did not possess any major resistance gene and 25 were characterized by susceptible or intermediate responses. Fifteen cultivars revealed isolate-specific response patterns that could not be attributed to known major resistance genes or gene combinations. Many of the old German cultivars inherited a mildew-resistance gene from the Canadian cultivar ‘Garnet’ which is tentatively designated M1-Ga. Cultivars ‘Bretonischer Bartweizen’ (designated M1-Br) and ‘Adlungs Alemannen’ (designated M1-Ad) appeared to carry unknown resistance genes. Among 18 winter wheat cultivars released in the former GDR. eight showed susceptibility to all isolates used. Cv. “Borenos” carries resistance gene Pm3c. Five cultivars possess gene Pm4b. two cultivars gene pm5 and one cultivar a combination of genes Pm2 and Pm4b. Cultivar ‘Zentos’ was resistant to almost all isolates used. Its resistance might be conditioned by different unknown major resistance genes.     

Dry-Matter Production, Allocation and Nutritive Value of Forage Chicory Cultivars as a Function of Nitrogen

Forage chicory cultivars vary in origin and morphology and may respond differently to nutrient inputs because of photosynthate allocation and resource acquisition. Understanding nitrogen (N) influences on chicory seedling development and allocation of photosynthates among plant parts is important in terms of stand establishment, plant persistence, herbage production and nutritive value. We conducted experiments in the glasshouse to determine if amount (0, 50 and 100 mg N kg^?1 soil) and source (ammonium nitrate or urea) of exogenous N influenced leaf dry‐matter (DM) production, N nitrate (NO₃) and total non‐structural carbohydrate (TNC) allocation among roots and shoots in the chicory cultivars Forage Feast, Lacerta or Grasslands Puna. Herbage DM productivity and the ratio of energy (TNC) : protein varied among cultivars because of differential photosynthate allocation between shoots and roots, and occurred later in the growth interval when N was applied. Forage Feast, compared with the other cultivars, produced the largest roots and greatest herbage DM without added N. Leaf appearance rate in Lacerta and Grasslands Puna increased with increasing N. Instantaneous growth rates of Grasslands Puna and Lacerta at 100 N were three times that of 0 N plants. Nitrate concentrations were very high in young seedlings of all three cultivars before applying N. The findings help define application practices for these cultivars and N management practices for optimal leaf production in establishing forage chicory plants.     

Selection of cereals for weed suppression in organic agriculture: a method based on cultivar sensitivity to weed growth

Cereal cultivars conferring a high degree of crop competitive ability, especially against aggressive weeds, are highly beneficial in organic farming as well as other farming systems that aim to limit the use of herbicides. In this study, thirteen winter wheat cultivars, plus one spring wheat and one winter oat were assessed for their competitive ability at key growth stages, across three seasons. The natural population of weed species was allowed develop without agronomic intervention. Weed suppression ability for each cultivar (S _var) was calculated as the difference between weed growth in plots for each cultivar and the maximal weed growth (W _max) from adjacent uncropped areas. The sensitivity of S _var in response to changes in weed growth (S _var^W) was derived from the linear regression coefficient of S _var plotted against W _max. There was significant variation in S _var between cultivars and strong evidence for cultivars to vary in S _var^W. Amongst groups of cultivars with similar levels of S _var some could be defined as being of higher or lower sensitivity to changes in weed growth. Some cultivars also had relatively good S _var at high levels of weed growth. The use of both weed suppression ability and sensitivity across different levels of weed growth or weed populations has considerable potential for selecting new cultivars suitable for organic agriculture. Ideally new cultivars will be selected on the basis of high S _var and/or low S _var^W. This analysis provides the means to measure sensitivity of cultivar performance across a range of favourable and unfavourable conditions.     

The incompatibility system in Italian red chicory (Cichorium intybus L.)

As a result of an incompatibility mechanism which prevents both self-fertilization and intermating between plants with identical genotypes, inbreeding does not occur in Cichorium intybus. This self-incompatibility system complicates the production of inbred lines and the generation of F₁ hybrids in Italian red chicory. Histological observations on pollinated stigmas show that the incompatibility reaction in chicory is very rapid and either prevents pollen adhering to the stigmatic papillae or determines the arrest of pollen-tube growth on the stigmatic surface; incompatible pollen cannot reach the transmitting tissue of the style. Both histological and genetic analyses of F₁ progeny from a reciprocal cross between two unrelated plants suggest the occurrence of a sporophytic incompatibility system in Italian red chicory.     

Comparative study on growth and development of some accessions of local Germplasm of Bambara groundnut (<Emphasis Type="Italic">Vigna subterrenea</Emphasis> L. Verdc.) of Nigeria in two cropping seasons

Two field experiments were conducted in April (early cropping) and August, (late cropping) 2007 at the Department of Crop Science Research Farm, University of Nigeria, Nsukka, to evaluate the agronomic and yield attributes of 13 cultivars of bambara groundnut. The results obtained showed that planting dates had significant effects (P < 0.05) on all traits measured. Significant cultivar and cultivar x planting date interaction effects were observed for days to 50% flowering. The principal component analysis showed that the first three components accounted for 85.18 and 86.81% of the total variation in the early and late planting, respectively. The traits representing the cultivars along the first principal axis were number of pods per plant and seed weight per plant for the early planting and number of leaves per plant and seed weight per plant in the late planting. Cultivars were differentiated on the basis of number of flowers per plant and plant height for the early planting and days to emergence for the late planting along the second principal axis. The cluster plot revealed that the 13 bambara groundnut cultivars were grouped into three clusters at both the early and late planting dates. In the early planting, the cultivars in cluster I are associated with high number of flowers, number of pods, and plant height, while cluster II cultivars flowered earlier and had good pod and seed yield. However, cluster III cultivars performed poorly in all the traits evaluated. During the late planting, the cluster I comprised early flowering cultivars while cluster II comprised cultivars with good vegetative growth, high number of pods per plant and seed weight per plant. Cluster III cultivars are early emerging and early flowering but have poor seed yield. The correlation coefficient for seed weight per plant was highly significant and positive with number of leaves per plant, plant height, number of flowers per plant and number of pods per plant indicating that increase in these traits will ultimately increase seed weight per plant. Thus, these traits could be considered as major seed yield contributing traits that could be given significant recognition during selection.     

Evaluation of common wheat cultivars for tan spot resistance and chromosomal location of a resistance gene in the cultivar 'Salamouni'

A total of 50 wheat (Triticum aestivum L.) cultivars were evaluated for resistance to tan spot, using Pyrenophora tritici‐repentis race 1 and race 5 isolates. The cultivars ‘Salamouni’, ‘Red Chief’, ‘Dashen’, ‘Empire’ and ‘Armada’ were resistant to isolate ASC1a (race 1), whereas 76% of the cultivars were susceptible. Chi‐squared analysis of the F₂ segregation data of hybrids between 20 monosomic lines of the wheat cultivar ‘Chinese Spring’ and the resistant cultivar ‘Salamouni’ revealed that tan spot resistance in ‘Salamouni’ was controlled by a single recessive gene located on chromosome 3A. This gene is designated tsn4. The resistant cultivars identified in this study are recommended for use in breeding programmes to improve tan spot resistance in common wheat.     

Isozyme polymorphism in three gene pools of cultivated chicory (Cichorium intybus L.)

Summary Polymorphism of ten enzymes, acid phosphatase (APH), isocitrate dehydrogenase (IDH), leucine aminopeptidase (LAP), phosphorylase (PP), superoxide dismutase (SOD), malic enzyme (ME), glutamate oxaloacetate transaminase 1 and 2 (GOT-1, GOT-2) and phosphoglucomutase 1 and 2 (PGM-1 and PGM-2), was investigated in three gene pools of cultivated chicory, including six cultivated wild chccory, eight industrial chicory and eight Brussels chicory varieties. LAP, APH, PP and PGM-2 showed high phenotypic polymorphism whilst GOT-1 and ME had poor polymorphism. For three enzyme coding loci Lap, Pgm-1 and Got-2, allele frequencies were determined. Isozyme composition in the three chicory gene pools was significantly different, showing, respectively, high, intermediate and poor average amount of phenotypic polymorphism in cultivated wild chicory, industrial chicory and Brussels chicory. Isozyme variation within and between varieties of the three gene pools is discussed in relation to breeding practices.