Showing papers on "Heterodera avenae published in 1982"

Studies of the cereal cyst-nematode, Heterodera avenae under continuous cereals, 1975–1978. II. Fungal parasitism of nematode females and eggs

Abstract: SUMMARY The development and fungal parasitism of Heterodera avenae females and eggs on susceptible cereals was studied from 1975 to 1978 in a sandy loam soil. Despite the production of many females on the roots nematode numbers declined in two years (1975 and 1978), and it is female survival and fecundity and not female numbers which often limit H. avenae multiplication. Fungal parasites may totally destroy females on roots or result in the formation of small cysts which are often empty. Fecundity is reduced and many eggs may became infected. Parasitism of females and eggs was decreased and nematode multiplication was increased in soil treated with formalin (38% formaldehyde) at 3000 litres/ha, but because it is nematicidal and fungicidal interpretation of the effects of the sterilant are difficult. Formalin has a greater effect on H. avenae multiplication in wet summers when fungal parasites, particularly Nematophthora gynophila are more active. Parasitised females which may be destroyed in about 7 days are fragile and difficult to extract from soil. Rates of parasitism tend to be underestimated. Approximately 60% of the females which failed to form cysts containing eggs can be accounted for by N. gynophila and Verticillium chlamydosporium. Fungal parasitism is therefore the major factor in limiting the multiplication of H. avenae.

Suggestions for determination and terminology of pathotypes and genes for resistance in cyst-forming nematodes, especially heterodera avenae

Abstract: A short review of differentiation into pathotypes is given. Use of the word ≪ pathotype ≫ is recommended when a very clear difference is established between virulence of nematode populations. Our present knowledge makes it possible to differentiate between 10 pathotypes of Heterodera avenae. It is suggested that the pathotypes are given numbers, and corresponding terms should be used for genes for resistance in plants, e.g. a gene Hal on the barley chromosome gives resistance to nematode pathotypes 11,21,31,41 etc. Some proposals for improvement of pathotype identification are given.

Studies of the cereal cyst-nematode, Heterodera avenae under continuous cereals, 1974–1978. I. Plant growth and nematode multiplication

Abstract: SUMMARY Population changes of Heterodera avenae and crop growth in a sandy loam soil were studied from 1974 until 1978; the nematode decreased plant growth but failed in two of the years to multiply on susceptible hosts. Spring oats were the most heavily invaded cereal and produced the smallest shoots. Second-stage juveniles invaded cereal roots in decreasing numbers: spring oats > autumn oats > spring barley > spring wheat > autumn barley > autumn wheat. Numbers of females developing on the different cultivars were in a similar order. Most females developed on roots in 1976 despite poor crop growth in the severe drought. Numbers of H. avenae in soil treated with oxamyl (Vydate) at 8.8 kg/ha a. i. were less in all years except 1975. In the dry winter and spring of 1975/76 nematode multiplication was prevented in soil treated with oxamyl before drilling in the autumn. In all years large numbers of females were produced on the roots of all cultivars but in 1975 and 1978 nematode populations declined because few females survived to form cysts containing eggs and their fecundity was reduced. Numbers of cysts after harvest were not affected by formalin (38% formaldehyde) applied as a drench at 3000 litres/ha in 1977 but fecundity doubled in treated soil, and nematode multiplication increased from 3.8 × in untreated plots to 18.6 ×. When the plots were irrigated in 1978 numbers of cysts and fecundity increased in formalin treated soil resulting in an increase in multiplication from 0.3 × to 14.6 ×. Fungal parasites attacking H. avenae females and eggs are considered responsible for the poor multiplication of the nematode.

Population Dynamics and Control of Heterodera avenae ‐A Review with some Original Results1

Abstract: Control of Heterodera avenae should largely aim to keep densities below tolerance limits at sowing-time (in spring oats < 1 egg/g soil, in susceptible barley < 3 eggs/g soil; spring wheat is only slightly less sensitive than oats, autumn-sown cereals are more tolerant than spring-sown ones). To obtain this, knowledge of population dynamics is important. Essential items in population dynamics are the host properties of different plants (characterized by two factors which do not always covary: maximum rate of multiplication and equilibrium density of the nematode), population decline of the nematode under fallow and non-hosts and the external factors influencing these characteristics. For cereals the following host efficiency order is found: winter oats (best), spring oats, spring wheat, spring barley, winter wheat, rye. Winter barley may be close to spring barley, and maize is a bad host. Grasses are generally less good hosts than cereals and usually cause high and moderate densities of H. avenae to decline. However, especially in first-year leys, rather high equilibrium densities may sometimes be maintained. Host properties of plants vary between sites and years and also relations between hosts may change. Populations decline under fallow, non-hosts and resistant cereals, usually in the order of 70–85 96 annually. H. avenae populations are favoured by lighter soils and heavier soils with a proper structure and also by good plant nutrient conditions. Soil moisture in interaction with temperature influences population dynamics in a complex way, in which natural enemies of the nematodes may also be involved, not least certain fungi. In many fields these may keep nematode populations at harmless levels. Traditional control measures like proper crop rotations can only be used to a limited extent. The most promising approach for controlling H. avenae is an appropriate use of resistant cultivars, of which barley cultivars are also tolerant, while oat cultivars are usually very sensitive. Biological control has hitherto not been used actively. Chemical control is profitable in Australia but not under European conditions. Farmers should check the need for control through soil sample investigations or by other means.

The Decline of Heterodera avenae Populations1

Abstract: Populations of the cereal cyst nematode fail to multiply in many soils in Europe and farmers are able to grow susceptible crops intensively on infested land. Similar numbers of females develop on roots in summer in soils where numbers of the nematode increase or decline. Two fungi, Nematophthora gynophila and Verticillium chlamydosporium parasitize females on roots, prevent cyst formation, decrease fecundity, and limit nematode numbers. Formalin (38 % formaldehyde) soil drenches at 3000 1/ha reduce the activity of these fungi and populations of the nematode increase, N. gynophila is an Oomycete which infects by motile zoospores whose activity is decreased when summer rainfall is light whereas V. chlamydosporium is much less affected by soil moisture. The decline of Heterodera avenae populations is associated with large numbers of spores in soil. At present it is not possible to control the nematode by introducing these fungi into soils where they are few or absent.

Population estimates of cereal cyst nematode and response of wheat to granular nematicides

Abstract: Response of vegetative growth and grain yield of wheat Triticum aestivum cv. Condor to the control of cereal cyst nematode Heterodera avenae by nematicides applied with the seed, in the drill row was assessed in twenty field trials. These trials were conducted in 1978 on three soil types near Coonalpyn, South Australia. Aldicarb was used at all sites and fosthietan and terbufos at four sites. Significant grain yield increases to aldicarb were obtained at 12 sites while yields were increased by the three nematicides at three sites. Numbers of eggs of H. avenae were determined in soil taken in January 1978, and these counts showed that all sites were infested over the range 0.03-8.5 eggs/g soil. Plant assays of the soils assessed the reduction in the length of seminal root axes (range 0-45%) and the severity of the root knotting caused by H. avenae. The egg densities in the soil, reduction in the length of the seminal root axes and disease ratings in the plant assay were highly correlated with each other (r = 0.75; P< 0.001 to 0.91, P< 0.001). These variables were not significantly correlated with grain yield increase due to aldicarb on the two major wheat soils studied, although a correlation, explaining 32-42% of the increase, existed when all sites were considered. A mathematical model based on cropping history and an estimated annual hatch of eggs of H. avenae failed to show a relation between these variables and the yield increase from nematicide. H. avenae caused severe disease and yield loss on calcareous loams and red duplex soils but had only minimal effects at the sites on siliceous sands.

The relation between wheat yield and early damage of roots by cereal cyst nematode

Abstract: A survey of 14 farmers' fields in the Northern Adelaide Plains in 1978 showed that cereal cyst nematode (Heterodera avenae Woll.) was the major factor limiting wheat yields, with a relation of r = -0.86 (P < 0.001) between damage to wheat roots at the seedling stage and grain yield. None of the 12 physical and chemical properties of the soils measured was related to cereal cyst nematode damage or grain yield. Samples taken from experimental plots with similar soil and climate showed a build up of H. avenae after four successive wheat crops and highly significant negative correlations between the damage to seminal roots by H. avenae, dry weight at flowering, and grain yield. A highly significant positive correlation of 0.84 existed between the damage to the seminal roots and the number of females (white cysts) on the roots at flowering.

Integrated Control of Heterodera avenae1

Abstract: Cereal cyst nematode is a major pathogen in southern Australia costing $40 to $80 million in lost production each year. Our research has shown that three chemicals applied with the seed in the drill row, viz. Counter (terbufos) granules, Vydate (oxamyl) as a seed dressing and Nemadi (ethylene dibromide), reduced Heterodera avenae damage and gave yield increases which are economical in the Australian wheat farming system. A plant assay of soil has been developed to assess potential damage by H. avenae before employing chemical control. Wheat yields 2 years after growing H. avenae-resistant Festiguay wheat were 0.4 to 1 t/ha higher than after other cultivars. Rotations with legumes alternating with wheat reduced damage from H. avenae. Wheat sown without cultivation (minimum tillage) resulted in less root damage from H. avenae and higher yields than when sown into cultivated soil.

Resistance of Cereals to Heterodera avenae: Methods of Investigation, Sources and Inheritance of Resistance1

Abstract: Techniques used in cereal breeding programmes for selecting for resistance to cereal cyst nematodes are described. Routine screening is done in field nurseries and in pots of infested soil in glasshouse and controlled environments. Other investigations of resistance use a laboratory technique which permits identification of the penetration sites of individual nematodes. Erosion of resistance, as indicated by 1) the development of only one or two females or 2) the occasional development of more females on plants with resistance genes, is discussed in relation to variation in nematode virulence and to environmental, especially temperature effects. Identification of tolerance is more difficult unless the differences are great, or the experimentation carefully controlled and replicated. Direct selection for tolerance in segregating generations is not presently practicable. Indirectly selecting for mechanisms of tolerance may eventually prove possible but has not yet been exploited. Available sources of resistance are described in relation to genetic studies and complementary studies of nematode pathotype and host range. There are three distinct resistances in barley which may have been responsible for selecting present pathotypes. Two, Rha1 and Rha2, are useful in breeding and linkage and allelism at these loci are described. In oats, as in wheat, only one locus has been used by breeders. There are probably additional loci in some of the other resistance sources but polyploidy of the host and different virulence gene frequencies in unselected nematode populations make it more difficult to identify genetic relationships in oats and wheat.

Distribution of Cereal and Grass Cyst Nematodes in the Federal Republic of Germany1

Abstract: A survey of cereal and grass cyst nematodes in the Federal Republic of Germany revealed that Heterodera avenae is the most widely distributed heteroderid species and common mainly in areas with light sandy soils and intensive cereal cultivation. The so-called ≪race 3 ≫ was recovered several times, and other populations differing morphologically from ≪ typical ≫H. avenae were found. H. hordecalis, H. bifenestra, H. mani, H. iri and Punctodera punctata were also recovered in many parts of the country. In arable soils these species constituted only 7 % of all records of cereal and grass cyst nematodes, whereas they prevailed in grassland, forests and other habitats, where they amounted to almost 80 % of the records. 93 % of all H. avenae records came from agricultural soils, but only 21 % of the records of the five other species. H. hordecalis and H. bifenestra are obviously of no economic importance in FRG.

Some Problems Posed by the Heterodera avenae Complex1

Abstract: Cyst nematodes are sedentary parasites with limited host ranges and co-evolution with circumscribed host groups is believed to result in species complexes. A scheme for this process is given. The Heterodera avenae group is such a complex parasitising cereals and grasses. Although the group includes ten nominal species, only H. mani, H. avenae and H. avenae pathotype 3 present taxonomic problems of immediate relevance in agriculture. Application of a multivariate technique, principal co-ordinate analysis, to second-stage juvenile characters indicates that H. avercae pathotype 3 is as distinct from H. avenae as H. arenaria, an accepted species in the H. avenae group. In contrast there are difficulties with juvenile and cyst morphology in distinguishing H. mani from H. avenae.

Towards a consistent laboratory assay for resistance to Heterodera avenae

Abstract: Causes of variation in numbers of females on a cultivar are examined. These are such that an accurate assessment of resistance in the field is not possible. The method used for a laboratory assay is as follows. Seed is selected for uniformity of size and pre-germinated before sowing, when the seminal roots are about 1 cm long, in tubes of sandy loam. Tubes are opaque (2.5 cm internal diameter by 13 cm long) and are set on a base of potting compost. Seedlings are inoculated immediately with the required number of larvae in 1 mi water - for oats 50 larvae, wheat 75 larvae and barley 100 larvae. They are inoculated at the same density at 3-daily intervals on four further occasions. The aim is to produce 50 females on the most susceptible cultivar; densities have been determined from intolerant cultivars. Plants are grown under 10-h day-length at 15oC and are harvested 2 months after the last inoculation, at which time they are assessed and the valuable plants can be repotted and grown on for seed production.

Yield Loss Caused by Heterodera avenae in Cereal Crops Grown in a Mediterranean Climate1

Abstract: In south-eastern Australia, where large areas of cereal crops are grown in a Mediterranean climate, yield loss caused by Heterodera avenae is generally more severe than in Northern Europe. This appears to be due to differences in seasonal cropping patterns and the stages of crop growth when roots are exposed to larvae. Field observations and laboratory experiments show that, in Australia, crops ≪ sown early ≫, in late autumn, are less damaged than those ≪ sown late ≫. This is explained by the times of emergence and population density of larvae, by the nematode-fungus interaction and by the environmental conditions affecting plant growth, rather than by differences in the nematode or in host tolerance.

Studies on the Australian Pathotype of Heterodera avenae1

Abstract: Australian studies on populations of Heterodera avenae have been conducted in Victoria, Western Australia. South Australia, and New South Wales. Only one pathotype has been identified so far, and it is distinct from those recorded elsewhere. Few recognised sources of resistance in barley and oats are useable in Australian breeding programmes. The first commercially acceptable cultivars of wheat, barley, and oats resistant to cereal cyst nematode will be released in Victoria within the next year or two. Their resistances are derived from spring wheat(AUS 10894), Marocaine 079 (CI 8334), and Arena sterilis (Cc 4658) respectively.

Heredity of Heterodera avenae Resistance Originating from two Barley Cultivars and one Spring Wheat Cultivar1

Abstract: Two spring barley cultivars Bajo Aragon-1-1 and Martin 403-2 from the cyst nematode test assortment were each crossed with a susceptible, a pathotype-11 -resistant, and a pathotype-11 and 12-resistant cultivar, as well as with each other. A spring wheat cultivar, AUS 10894, from the cyst nematode test assortment was crossed with a susceptible and a resistant cultivar. From these crosses F! and F2 single plants were tested against pathotype 12 and/or pathotype 11 of Heterodera avenae in Denmark. Some plants of the spring barley cultivar Bajo Aragon-1-1 have two resistance genes, which probably are both dominant, but it is not out of the question that one might be recessive. Each gene is inherited independently of the other or with low linkage frequency. Neither gene is the same as or allelic to the resistance gene in the cultivar Ortolan, but one gene is allelic to or the same as the 191 gene in the cultivar Siri. The spring barley cv. Martin 403-2 has one dominant resistance gene which is not allelic to or the same as the resistance gene in Ortolan but is the same as or allelic to the 191 gene in the cultivar Siri. It is possible that there is one more gene, which might be recessive against pathotype 11. The spring wheat cv. AUS 10894 has one dominant resistance gene which might be the same as or allelic to the Loros gene.

Cyst‐forming Nematodes on Cereals in Bulgaria1

Abstract: Heterodera avenae and Heterodera latipons are widespread on cereals in Bulgaria and mixed populations are encountered. H. avenae populations reach their highest point on barley after ten years cereal monoculture. The two-field crop rotation maize/cereals keeps the population at a low level. H. avenae has been found on most cultivars of wheat and barley cultivated in Bulgaria. The author had detected two previously unreported hosts: Agrostis capillaris and Cynosurus cristatus. The most appropriate conditions for infection on cereals occur in April. Nematode development starts in April and finishes in the first half of June. Nematophthora gynophila parasitizes about 20% of the cysts, while Catenaria auxiliary and Lagenidiaceous fungi do so to a lesser extent.

A comparision of low volume, in-row applications of nematicides at seedling, for control of the cereal cyst nematode (Heterodera avenae) in wheat

Abstract: Previous investigations in Victoria, Australia (Meagher and Rooney, 1966; Barry et at., 1974; Meagher and Brown, 1974) have shown that crop rotation can provide good control of the cereal cyst nematode (Heterodera avenae Woll.) with resultant increases in grain yield. This practice is not always feasible economically, especially on farms of limited size, and better control of the nematode may ultimately be achieved using resistant varieties (Brown and Meagher, 1970). In the meantime, however, the use of nematicides has been considered (Brown et at., 1970; Brown, 1972, 1973; Meagher et at., 1978). These studies have shown that a wide range of nematicides, fumigant, non-volatile, and sterilant, can provide excellent control of H. avenae. This paper reports further results on the control of H. avenae in wheat, using low rates of fumigant and non-volatile nematicides applied in the drill row at seeding.

Classification of Plants Resistant to Heterodera avenae1

Abstract: Differentiation of barley plants resistant to Heterodera avenae is simple when they are completely without cysts and the number of cysts is high on a susceptible control cultivar. Problems with classification are discussed.

by cereal cyst nematode

Abstract: in the Northern Adelaide Plains in 1978 showed that cereal cyst nematode (Heterodera avenae Woll.) was the major factor limiting wheat yields, with a relation of r = -0.86 (P < 0.001) between damage to wheat roots at the seedling stage and grain yield. None of the 12 physical and chemical properties of the soils measured was related to cereal cyst nematode damage or grain yield. Samples taken from experimental plots with similar soil and climate showed a build up of H. avenae after four successive wheat crops and highly significant negative correlations between the damage to seminal roots by H. avenae, dry weight at flowering, and grain yield. A highly significant positive correlation of 0.84 existed between the damage to the seminal roots and the number of females (white cysts) on the roots at flowering. yeld responses to soil fumigation and the application of non-volatile nematicides indicate that cereal cyst nematode (CCN) (Heterodera avenae Woll.) is a major soilborne pathogen ofwheat in South Australia and Victoria (Brown et al. 19 7 0; King et al. 1982; Rovira et al. 198 1 ). The non-specific action of soil fumigants and the biocidal properties of non-volatile nematicides made it desirable to use alternative methods to assess the effect of H. avenae on yields of wheat in South Australia. This study was undertaken with plants grown under field conditions to relate seminal root damage at the seedling stage to grain yield; root damage was assessed as in the plant assay of Simon (1980).

Species Identification of European Cereal and Grass Cyst Nematodes by Larval Characters1

Abstract: Second-stage juveniles of heteroderid species often present more reliable diagnostic characters than cysts For identification of European cereal and grass cyst nematodes, size and position of the phasmids, swelling of the cuticle behind the lip region, expression of the lateral fields, shape and size of the stylet knobs and measurements of, for example, the tail and the hyaline tail portion are useful A key presented, based on larval characters, allows identification of seven European cereal and grass cyst nematode species and their distinction from other European heteroderids not reproducing on Gramineae Species identification is often difficult in the Heterodera avenae/H mani complex and evidence exists that additional species are present within this group

Variations in Cereal Yield Losses associated with Heterodera avenae in England and Wales1

Abstract: Many field experiments in England and Wales during the past 20 years have measured cereal yield losses and established regressions of yield on numbers of Heterodera avenae. Yield benefits from soil sterilants were greatest where most H avenae was present. Isogenic selections of barley and oats resistant and susceptible to H. avenae were extensively grown to assess the losses caused by this nematode alone. In some experiments these losses were identical with those measured by nematicide use, but in others (notably where broad spectrum biocides were used) losses were greater than those attributable to H. avenae and could be explained only by the known incidence of accompanying pathogens. Some yield loss may be due to migratory nematodes, e.g. Pratylenchus spp. occurring with H. avenae. Barley and wheat yields in the last 30 years have increased by 63 and 84 % due to improvements in cultivars and farming practice. Smaller percentage loss in a high yielding crop can be as costly as large percentage loss in poor crops grown on dry light soils. Many factors - soil type, rainfall, nutrients, other pathogens etc. - can greatly modify crop responses to similar popuiation levels of H. avenae.

The Effect of Environment on Survival and Hatching of Heterodera avenae1

Abstract: Eggs within cysts of Heterodera avenae are able to survive long periods of desiccation and can be held for several years at 5oC when stored at low relative humidity. While this provides an excellent means of storing the nematode for use in laboratory experiments, field experiments show that desiccated eggs are readily dispersed by wind. Tolerance to desiccation is similar in free and encysted eggs, which hatch at the same rate. When eggs are desiccated, water is withdrawn from the larva within the egg shell. If cysts are exposed to conditions favouring eclosion, subsequent desiccation reduces egg viability and larval emergence. The importance of defining pre-test conditions in survival studies is emphasized, and differences in the physiological state of eggs may explain different observations in Australian and European studies.

Cultural Practices and their Effects on Heterodera avenae and Grain Yields of Wheat in Victoria, Australia1

Abstract: The effects of various cultural practices on cereal cyst nematode (Heterodera avenae) populations, and the subsequent yield of wheat, have been studied over many seasons in Victoria, Australia. Crop rotations which include periods of fallow, or of non-host crop reduce population levels and improve yields. The inclusion of a legume has the additional advantage of improving soil nitrogen levels. Early sown crops (April/May) are less severely damaged, and produce better yields, than late sown crops (June/July). The resowing of damaged wheat crops with either wheat or barley is not effective in improving yields, although cyst numbers are lower on resown crops. Nitrogenous fertilisers are not generally applied to cereals, and although small increases in yield are sometimes obtained, they are rarely economic. Sulphate of ammonia applications increase cyst numbers, especially when applied at seeding, but urea has only a marginal effect on cyst numbers.

Characterization of Heterodera avenae in Spain1

Abstract: Several types of Heterodera spp. belonging to the ≪ avenae ≫ group have been found in Spain on cereal crops and wild Gramineae. The morphological differences between them relate to the colour of the cysts, presence or absence and consistency of the subcrystalline layer, presence or absence and shape of the ≪ underbridge ≫ in the vulvar cone, length of the 2nd-stage larvae and shape of their stylet knobs. The value of these characters in the diagnosis of these species is discussed together with the identity of the types.

The Status of Heterodera avenae on Cereals in New Zealand1

Abstract: The cereal cyst nematode (Heterodera avenae) was discovered in New Zealand in 1975 on wheat and oats. It was not at that time causing appreciable economic losses in yield, presumably because usual management practice incorporated a good crop rotation with lucerne. However, now that the growing of cereals has become more profitable, farmers are tending to grow consecutive cereal crops and more damage from H. avenae is being experienced. On one farm, up to 9 % of an oat crop was lost due to this nematode. The biotype has not yet been determined.