Linking Soil Biotic and Abiotic Factors to Apple Replant Disease: a Greenhouse Approach

Apple replant disease (ARD) is a frequently occurring plant disease, which causes retarded growth and mortality of young apple trees in replanted orchards. The aetiology is not well understood, but soil‐borne micro‐organisms are often discussed as primary causal agents of the replant problem. A greenhouse study was conducted in Laimburg, Italy, with orchard soils from the region, with the aim of obtaining information about the influence of soil biotic and abiotic factors on the aetiology of the disease. Apple rootstocks (M9) were planted into soils cultivated with apple trees that were either fumigated with chloropicrin or not fumigated, as well as mixtures of fumigated and non‐fumigated soils. In addition, uncultivated soils (from the inter‐row, from a fallow plot and from a meadow) were taken as controls. Various parameters were measured after 62 days in a controlled pot assay. Soils fumigated with chloropicrin resulted in higher apple shoot growth and lower microbial biomass carbon than non‐fumigated soils. Uncultivated soils had generally the highest microbial biomass carbon and the highest ergosterol contents. No considerable differences between basal respiration, ergosterol content, pH, electrical conductivity, and most nutrient and metal contents were observed between fumigated and non‐fumigated soils. Denaturing gradient gel electrophoresis gels of DNA extracted from the soils revealed differences in the fungal, bacterial and actinobacterial communities of the different soils, indicating significant shifts in microbial community composition after chloropicrin treatment. This study indicates biotic factors in soil to be a causal agent of apple replant disease.     

Rootstock genotype and orchard replant position rather than soil fumigation or compost amendment determine tree growth and rhizosphere bacterial community composition in an apple replant soil

Apple replant disease (ARD) is a complex soilborne disease syndrome that often causes problems when renovating old orchard sites. Soil fumigants sometimes control ARD, but biological and cultural alternatives are needed. In this study the growth of two widely used clonal apple (Malus domestica) rootstocks (M7 and M26) were compared to three new rootstocks from the Cornell-Geneva series (CG16, CG30 and CG210 (a.k.a. CG6210)) in an orchard site with a history of ARD, in Ithaca, NY. Trees were planted in two distinguishable positions – the previous tree rows versus the old inter-row grass lanes. Additionally, we compared the effects of compost amendment and fumigation with dichloropropene plus chloropicrin on tree growth on each replant rootstock. Rhizosphere bacteria and actinobacteria were assessed using PCR-DGGE for the rootstocks M7, M26, CG30 and CG210. Tree growth on the rootstocks M7, M26 and CG16 was suppressed in the old tree rows relative to grass lanes, while trees on CG30 and CG210 rootstocks grew equally well in both positions. The species composition of rhizosphere bacteria and actinobacteria differed significantly between the planting positions and between the rootstocks M7 and M26 compared to CG30 and CG210. In contrast, the preplant compost or fumigation soil treatments had no effect on tree growth and little impact on rhizosphere bacterial community composition. Abbreviations: ARD – apple replant disease; DGGE – denaturing gradient gel electrophoresis; PCR – polymerase chain reaction.     

Apple Replant Disorder of Pingyitiancha Rootstock is Closely Associated with Rhizosphere Fungal Community Development

The aim of this study was to examine rhizosphere fungal community development in apple replant soil and a new planting soil in Beijing through a potted experiment with the apomictic triploid Pingyitiancha rootstock using the Illumina Miseq method. Steam sterilization significantly enhanced seedling growth in replant soil, while root segment addition did not enhance replant disease symptoms. The bulk soil of the replant site (ReSoil) and the new soil of the planting site (NewSoil) were sampled prior to nursery planting, and rhizosphere soils were r Qinping esampled after one growing season as RePlant and NewPlant, respectively. Approximately 48.3, 47.9, 59.8 and 68.8% of the operational taxonomic units (OTUs) were classified as Ascomycota and Basidiomycota in the community of ReSoil, New Soil, RePlant and NewPlant, respectively. Shannon indices suggested that planting apple nurseries increased the fungal diversity of rhizosphere soil in both soils. Apple replant disorder (ARD) was highly associated with an unbalanced microbial ecosystem with more saprophytic and pathogenic fungi, but less species known to produce antimicrobial metabolites, while Rhizopus, Pyrenochaeta and Eurotium were identified as the key factors in ARD.     

The role of Thielaviopsis basicola in the specific replant disorders of cherry and plum

The hypothesis that Thielaviopsis basicola might be the causal agent of the specific replant disorders of cherry and plum was tested in experiments with pot-grown trees and by observations on the distribution of the pathogen. The results obtained with certain strains of T. basicola simulated and were consistent with all features known to characterize the specific replant disorders, viz. inter- and intra-generic specificity of effect; host symptoms; establishment, immobility and persistence of the causal agent in soil; normal growth of affected trees after transfer to ‘non-replant’ soil; limited influence of soil type on the incidence of the disorder. T. basicola was therefore considered to be the probable causal agent of the specific replant diseases of certain Prunus species. The etiology of these diseases is discussed. T. basicola was neither pathogenic to apple nor associated with the growth of apple. The apparently closely similar specific replant disorder of Malus is therefore considered to be causally distinct from those of cherry and plum.     

Effects of Pythium species on the growth of apple and their possible causal role in apple replant disease

Several lines of circumstantial evidence collectively indicated that poor early growth of apple (‘replant disease’) might be associated with the effects of soil-borne pythiaceous fungi. This hypothesis was supported by pathogenicity tests. All isolates tested of P. sylvaticum and certain isolates of seven other Pythium spp. significantly reduced the growth of apple seedlings. The growth reductions caused by certain Pythium isolates were of comparable magnitude to the growth increases occurring after chloropicrin-fumigation of apple orchard soils. The Pythium isolates most virulent to apple were of low virulence to a clonal cherry rootstock. Reappraisal of the nature of the disease as a non-specific soil malaise is consistent with established features of the pathology of Pythium spp. The disease, however, is an ill-defined ‘poor growth phenomenon’ with no diagnostic symptoms and conclusive evidence that Pythium spp. are widely causal is likely to be elusive.     

Rootstock genotype succession influences apple replant disease and root-zone microbial community composition in an orchard soil

Apple replant disease (ARD) is a soil-borne disease complex that affects young apple trees in replanted orchards, resulting in stunted growth and reduced yields. Newly developed rootstock genotypes with tolerance to ARD may help to control this disease. We determined the effects of rootstock genotype rotations during orchard renovation, by investigating root-zone soil microbial consortia and the relative severity of ARD on seven rootstock genotypes (M.9, M.26, G.30, G.41, G.65, G.935, and CG.6210) planted in soil where trees on four of those same rootstocks (M.9, M.26, G.30 and CG.6210) had grown for the previous 15 years. Rootstock genotyping indicated that genetic distances among rootstocks were loosely correlated with their differential responses to ARD. Root-zone fungal and bacterial community composition, assessed by DNA fingerprinting (T-RFLP), differed between M.26 and CG.6210. Soil bacterial communities were influenced most by which rootstock had grown in the soil previously, while fungal communities were influenced more by the current replanted rootstock. In a clone library of bacteria from M.26 and CG.6210 root-zone soil, β-Proteobacteria was the most abundant phylum (25% of sequences). Sequences representing the Burkholderia cepacia complex were obtained only from CG.6210 soil. Rootstock genotypes that were grown in the orchard soil previously affected subsequent ARD severity, but replanting with the same or closely related rootstocks did not necessarily exacerbate this disease problem. Our results suggest that genotype-specific interactions with soil microbial consortia are linked with apple rootstock tolerance or susceptibility to ARD.     

The Effect of Glomus mosseae and Enterobacter aerogenes on Apple Seedlings Grown in Apple Replant Disease Soil

Inoculation of apple seedlings with the mycorrhizal fungus Glomus mosseae significantly increased their growth in apple replant disease soil that was neither pasteurized nor fertilized with monoammonium phosphate. The application of Enterobacter aerogenes and peat suppressed the stunting effect observed in apple replant disease soil. These results suggest the potential of using G. mosseae alone or a E.aerogenes and peat combination for the control of apple replant disease.     

Illumina Amplicon Sequencing of 16S rRNA Tag Reveals Bacterial Community Development in the Rhizosphere of Apple Nurseries at a Replant Disease Site and a New Planting Site

We used a next-generation, Illumina-based sequencing approach to characterize the bacterial community development of apple rhizosphere soil in a replant site (RePlant) and a new planting site (NewPlant) in Beijing. Dwarfing apple nurseries of ‘Fuji’/SH6/Pingyitiancha trees were planted in the spring of 2013. Before planting, soil from the apple rhizosphere of the replant site (ReSoil) and from the new planting site (NewSoil) was sampled for analysis on the Illumina MiSeq platform. In late September, the rhizosphere soil from both sites was resampled (RePlant and NewPlant). More than 16,000 valid reads were obtained for each replicate, and the community was composed of five dominant groups (Proteobacteria, Acidobacteria, Bacteroidetes, Gemmatimonadetes and Actinobacteria). The bacterial diversity decreased after apple planting. Principal component analyses revealed that the rhizosphere samples were significantly different among treatments. Apple nursery planting showed a large impact on the soil bacterial community, and the community development was significantly different between the replanted and newly planted soils. Verrucomicrobia were less abundant in RePlant soil, while Pseudomonas and Lysobacter were increased in RePlant compared with ReSoil and NewPlant. Both RePlant and ReSoil showed relatively higher invertase and cellulase activities than NewPlant and NewSoil, but only NewPlant soil showed higher urease activity, and this soil also had the higher plant growth. Our experimental results suggest that planting apple nurseries has a significant impact on soil bacterial community development at both replant and new planting sites, and planting on new site resulted in significantly higher soil urease activity and a different bacterial community composition.     

Growth rate of fine root systems influences rootstock tolerance to replant disease

Aims

Plant tolerance to herbivory has often been linked to plant growth rate, with faster growing plants that present high tissue turnover rates expected to be more tolerant than slower-growing plants. We tested whether this relationship also holds for rootstock growth rate and tolerance to apple replant disease (ARD).

Methods

An ARD susceptible rootstock, M.26 and ARD tolerant rootstock, CG.6210 were grown in soil from an apple replant site (FS) and in pasteurized soil (PS) from the same site. Total below ground biomass production was determined by harvesting a subset of plants per soil treatment and rootstock at 11, 17, and 23 weeks after planting. Root samples were collected prior to each harvesting date to determine root respiration and total carbon (C) and nitrogen (N) content. Root dynamics were tracked during the growing season by digitally photographing root observation windows.

Results

Total root biomass, first and second order roots, and second-to-first order root ratio were higher in CG.6210 than in M.26 in both soil treatments. Roots of CG.6210 were thinner and had lower N concentration than those of M.26. Roots of M.26 had longer lifespans than those of CG.6210, and the mortality risk of M.26 roots was 56 % that of CG.6210 roots.

Conclusion

Our study indicates that rootstocks with faster growing root systems can tolerate ARD infection by investing fewer resources in individual root construction that can be shed more readily.     

Apple replant disease: the influence of soil phosphorus and other factors on the growth responses of apple seedlings to soil fumigation with chloropicrin

The effects of fumigating field soils before replanting apple are frequently predicted from bioassays where apple seedlings are grown in pots, some containing untreated soil and the others containing chloropicrin-fumigated soil. The results from 418 such bioassays made during eight years are discussed with reference to the effects of certain physical and chemical soil features. Soil phosphorus (P) content and pH had large effects on growth in fumigated (but not untreated) soils; they therefore had large effects on the growth response to soil fumigation. There were no indications of important effects due to soil content of potassium or magnesium or to soil texture. In fumigated soils, the height of seedlings was generally greater, the greater the soil P content, but in untreated soils it was mostly independent of P (range 1 – 156 mg P litre^-1soil). The differing effects of native P on growth in untreated or fumigated soils were attributed respectively to the presence and absence of vesicular-arbuscular mycorrhizas: their absence in fumigated soils was considered (for apple) to be an artefact in the seedling bioassay. The results for untreated soils indicated that the apple mycorrhizal system was very efficient in retrieving P when there was little available. Growth responses to soil fumigation were usually greater in acidic than in alkaline soils for any given level of P. When soils were P-amended before testing, the effects of native P and pH virtually disappeared and the proportion of orchard soils with economically significant growth responses increased from 39% to 67%.     

Replant problems in South Tyrol: role of fungal pathogens and microbial population in conventional and organic apple orchards

The South Tyrol, the main apple-growing area in Italy, is characterised by intensive soil cultivation. Previous investigations have revealed the existence of replant disorders although the main causes of these have not been evaluated. A survey was carried out in this area with two main aims: to evaluate the role of soil-borne pathogens in apple replant disease and to compare the impact of organic and conventional management on replant diseases caused by soil-borne pathogens. The experimental sites were chosen to obtain three pairs of contiguous conventional and organic apple orchards. There was a high level of organic matter in both the organic and the conventional apple orchards with no appreciable differences in humic fractions. The soil sickness test with apple seedlings revealed a significant reduction in growth for all soil samples as compared to the peat control. The growth score on soil samples from organic orchards was significantly higher than that obtained on conventional soil. Total fungal population in soil samples was positively correlated to the apple seedlings growth score and negatively correlated to the frequency of root colonisation. Most of the root-colonising pathogens belonged to the well-known root rot complex, Rhizoctonia solani and Pythium spp. being the most pathogenic on apple seedlings.     

Evaluation of apple replant problems based on different soil disinfection treatments—links to soil microbial community structure?

Background and aims

Replant problems or soil sickness are known phenomena but still unsolved. The aims of this study were (i) to set up a test system for detecting replant problems using in vitro propagated apple rootstocks (M26) based on different soil disinfection treatments and (ii) to explore the treatment effects on root morphology and soil microbial community structure.

Methods

The bio-test involved soil with apple replant problems (apple sick) and healthy soil from an adjacent plot, both either untreated, or submitted to treatments of 50 and 100 °C, or the chemical soil disinfectant Basamid. Histological analyses of roots and denaturing gradient gel electrophoresis (DGGE) fingerprints in rhizosphere soil collected at the final evaluation were performed.

Results

After 10 weeks, shoot dry mass on apple sick soil was 79, 108 and 124 % higher for soil treated at 50 °C, 100 °C and with Basamid, respectively, compared to the untreated soil. Roots in untreated apple sick soil showed destroyed epidermal and cortical layers. DGGE fingerprints revealed treatment dependent differences in community composition and relative abundance of total bacteria, Bacillus, Pseudomonas and total fungi.

Conclusions

The clear differences detected in soil microbial communities are the first steps towards a better understanding of the causes for apple replant problems.     

樱桃砧木实生苗对根癌菌侵染的抗性及生理响应

以贵州樱桃的6个砧木实生苗为材料,采用人工接种根癌菌的方法,探讨它们对根癌菌侵染的抗性及生理响应特征,评价其抗病性能力。结果显示:(1)接种根癌菌120d后,青岩樱桃实生苗发病率较低(6.67%),冠瘿瘤直径较小(1.76mm),感病系数也较低(6.67),属高抗砧木;沿河樱桃实生苗发病率高达50.0%,冠瘿瘤直径达6.43mm,感病系数达33.76,属高感砧木。(2)感染根癌菌后,各樱桃砧木幼苗的生理特性受到一定影响,其叶片游离脯氨酸含量增加,根系过氧化物酶(POD)和超氧化物歧化酶(SOD)活性增强,而过氧化氢酶(CAT)活性降低,其中,青岩樱桃的游离脯氨酸含量升高幅度最大,沿河樱桃的保护酶活性变化幅度明显较大。(3)樱桃砧木幼苗的发病率与感病系数呈显著正相关(0.98*);发病率与SOD活性、感病系数与POD活性和SOD活性均呈显著正相关,相关系数分别为0.86、0.82、0.83;其余指标间相关性不显著。研究表明,6个樱桃砧木实生苗对根癌菌的抗性有明显差异,并以青岩樱桃最强,且其抗性强弱与其感病后叶片脯氨酸含量和根系的POD、SOD活性增加幅度有密切关系。     

Plant growth and yield of cucumber plants grafted on different commercial and local rootstocks grown under salinity stress

This study aimed to determine the effects of different rootstocks and soilless media on the plant growth and yield of cucumber and on the leaf ion (Na⁺, Ca⁺⁺, K⁺ and Cl^?) concentrations. Four commercial rootstocks (TZ148 F₁, RS841 F₁, Nun9075 F₁ and Avar F₁) and two local landraces (Local-1 and Local-3 belonging to Cucurbita moschata L.) were used as rootstock and grafted and non grafted plants were tested in three different salinity conditions (2.5 dS m^?1, 5.0 dS m^?1 and 7.5 dS m^?1) on three different soilless media (cocopeat, perlite and rockwool) in spring period under greenhouse conditions. Salinity found to reduce root and shoot dry weight, and yield of plants in all growing media. TZ148, Nun9075 and Local-3 are found to improve tolerance of cucumber plants to saline conditions (5.0 and 7.5 dS m^?1) when used as rootstocks. Root and shoot dry weight, yield, Ca⁺⁺ in leaves and K⁺/Na⁺ ratio in leaves were significantly decreased, but Na⁺ and Cl^? concentration in leaves were increased under salt stress. Rootstock potential of Local-3 is also found to be quite good for cucumber under saline conditions.     

Genotype and Planting Density Effects on Rooting Traits and Yield in Cotton （Gossypium hirsutum L,）

Root density distribution of plants is a major Indicator of competition between plants and determines resource capture from the solh This experiment was conducted in 2005 at Anyang, located in the Yellow River region, Henan Province, China. Three cotton （Gossyplum hlrsutum L.） cultivars were chosen： hybrid Btcultlvar CRI46, conventional Btcultlvars CRI44 and CRI45. Six planting densities were designed, ranging from 1.5 to 12.0 plants/m^2. Root parameters such as surface area, diameter and length were analyzed by using the DT-SCAN Image analysis method. The root length density （RLD）, root average diameter and root area Index （RAI）, root surface area per unit land area, were studied. The results showed that RLD and RAI differed between genotypes; hybrid CRI46 had significantly higher （P 〈0.05） RLD and RAI values than conventlonal cultlvars, especially under low planting densities, less than 3.0 plants/m^2. The root area index （RAI） of hybrid CRI46 was 61% higher than of CRI44 and CRI45 at the flowering stage. The RLD and RAI were also significantly different （P = 0.000） between planting densities. The depth distribution of RAI showed that at Increasing planting densities RAI was Increasingly distributed in the soil layers below 50 cm. The RAI of hybrid CRI46 was for all planting densities, obviously higher than other cultivars during the flowering and boll stages. It was concluded that the hybrid had a strong advantage in root maintenance preventing premature senescence of roots. The root diameter of hybrid CRI46 had a genetically higher root diameter at planting densities lower than 6.0 plants/m^2. Good associations were found between yield and RAI In different stages. The optimum planting density ranged from 4.50 plants/m^2 to 6.75 plants/m^2 for conventional cultlvars and around 4.0-5.0 plants/m^2 for hybrids.     

Evidence for biological nature of the grape replant problem in California

A bioassay was developed to investigate causes of grape replant problems under controlled conditions. Soils were collected from methyl bromide-fumigated and non-fumigated plots at a site cleared from a 65-year-old grape vineyard (Vitis vinifera cv. Thompson seedless) at Parlier, CA. Subsamples of the non-fumigated soil were either left non-treated, subjected to autoclaving (twice 45 min), or heating at 40, 50, 60, 70, 80 or 90 °C for 30 min. Subsequently, the samples were placed in 120-mL pots, planted with rooted hardwood grape cuttings (V. vinifera, cv. Carignane) and placed in a greenhouse or growth chamber. Three months after transplanting, vines from non-treated or 40 °C-treated soil had lower shoot weights and densities of healthy lateral roots than vines from the other treatments. Pythium spp. were isolated from 45 to 55% of the plated root segments from vines grown in non-treated, or soil that had been heated at 40 or 50 °C but were not detected in roots from soil given other treatments. Egg masses of root-knot nematode, Meloidogyne spp., were produced on roots from non-treated or heated at 40 °C soil, but no egg masses were detected on roots of the other treatments. In another test with the same soils, remnant roots from non-fumigated or pre-plant methyl bromide-fumigated soil were extracted and amended to non-fumigated soil, soil from fumigated field plots, soil fumigated in a small container, or autoclaved potting mix. The transfer of old vine roots from non-fumigated field soil resulted in incidence of Pythium spp. on grape assay roots, but there was no measurable effect of the transfer on growth and health of the bioassay plant roots. The results of the bioassays indicate that grape replant problem at the California site had biological causes. The bioassay approach may aid in future determinations of the etiology of grape replant problems.     

棉隆对苹果连作土壤微生物及平邑甜茶幼苗生长的影响

以生产上常用苹果砧木——平邑甜茶为试材,盆栽条件下研究了棉隆微粒剂对苹果连作土壤微生物及平邑甜茶幼苗生长的影响。结果表明:与重茬(对照CK)相比,棉隆处理极显著(P0.01)降低了连作土壤中真菌数量,降幅达58.8%,细菌和放线菌数量分别显著(P0.05)降低15.3%、8.5%,细菌/真菌增加108.8%,放线菌/真菌增加124.2%;棉隆使连作条件下平邑甜茶单株幼苗根系长度、根表面积、根体积和根系活力分别提高421.4%、426.5%、171.7%、48.8%。平邑甜茶植株叶面积以及叶片中叶绿素a、b含量、净光合速率均极显著提高,分别增加162.6%、14.9%、15.0%、24.0%,叶片同化能力增强;植株长势增强,株高和地径均极显著提高,植株地上干鲜重和地下干鲜重也得到了极显著性增加,最高增加幅度达2.2倍。综上,棉隆处理后苹果连作土壤中微生物数量降低,而细菌与真菌比值、放线菌与真菌比值增加,平邑甜茶幼苗植株长势增强,棉隆可有效减轻苹果连作障碍发生。     

Anatomical Characteristics of Cherry Rootstocks as Possible Preselecting Tools for Prediction of Tree Vigor

An anatomical study of roots and stems of five self-rooted cherry rootstocks with different growth control potentials was performed to compare their structure and xylem anatomy. The aim was to correlate anatomical parameters with rootstock dwarfing potential and theoretical hydraulic conductance (k _h), and to evaluate the potential application of anatomical characteristics in the preselection process for prediction of ultimate tree vigor. One of the mechanisms of water transport efficiency reduction in dwarfing rootstock stems is from the rootstock xylem anatomy. Anatomical parameters of ??Gisela 5?? and ??Mazzard?? were typical for dwarfing and vigorous rootstocks, respectively, and were thus suggested as reference rootstocks. Significantly greater vessel diameter and frequency were found in invigorating and dwarfing rootstocks, respectively. Higher k _h was obtained in roots, compared to stems, due to significantly larger vascular elements. Dwarfing rootstocks had lower k _h due to small vessel lumens and percentage and, to a lesser extent, because of low wood/cortex ratios or percentage of wood. A higher percentage of wood or xylem in cherry roots and stems was not always positively correlated with their conductivity and vigor. Thus, these parameters cannot be reliably used in prediction of the ultimate vigor, although this method was previously suggested for some other fruit tree species. The most reliable anatomical parameters for that purpose proved to be vessel frequency, vessel lumen area, and percentage of vessels on wood cross section. These characteristics could thus be an effective way to estimate dwarfing capacity and could be applied in rootstock selection and breeding programs.     

Global RNA association with the transcriptionally active chromosome of chloroplasts

Key message

Gene expression studies in roots of apple replant disease affected plants suggested defense reactions towards biotic stress to occur which did not lead to adequate responses to the biotic stressors.

Abstract

Apple replant disease (ARD) leads to growth inhibition and fruit yield reduction in replanted populations and results in economic losses for tree nurseries and fruit producers. The etiology is not well understood on a molecular level and causal agents show a great diversity indicating that no definitive cause, which applies to the majority of cases, has been found out yet. Hence, it is pivotal to gain a better understanding of the molecular and physiological reactions of the plant when affected by ARD and later to overcome the disease, for example by developing tolerant rootstocks. For the first time, gene expression was investigated in roots of ARD affected plants employing massive analysis of cDNA ends (MACE) and RT-qPCR. In reaction to ARD, genes in secondary metabolite production as well as plant defense, regulatory and signaling genes were upregulated whereas for several genes involved in primary metabolism lower expression was detected. For internal verification of MACE data, candidate genes were tested via RT-qPCR and a strong positive correlation between both datasets was observed. Comparison of apple ‘M26’ roots cultivated in ARD soil or γ-irradiated ARD soil suggests that typical defense reactions towards biotic stress take place in ARD affected plants but they did not allow responding to the biotic stressors attack adequately, leading to the observed growth depressions in ARD variants.

     

Effects of Nitrogen and Phosphorus on the Growth of Microorganisms Associated with Apple Replant Disease and on Apple Seedlings Grown in Soil Infested with these Microorganisms*

The growth of fungi causing apple replant disease (ARD) was inhibited by the addition of N and P to the growing medium. The population of bacteria antagonistic to ARD-causing fungi was significantly increased in the growing medium supplemented with N 400 P 400 mg/l or greater. The application of nitrogen alone or in combination with phosphorus to soil infested with fungi or bacteria that cause apple replant disease significantly increased seedling height. The addition of P alone to these infested soils did not have any effect on seedling height. Significant increases in seedling height occurred with N applications when seedlings were grown in soil to which bacteria that are antagonistic to fungi causing ARD had been added. These results suggest that the application of N, with or without P, to apple replant soils may suppress the growth of ARD-causing fungi or bacteria and promote the growth of antagonistic bacteria.