Incorporation of <Emphasis Type="Italic">Brassica seed meal</Emphasis> soil amendment and wheat cultivation for control of <Emphasis Type="Italic">Macrophomina phaseolina</Emphasis> in strawberry

Macrophomina. phaseolina is the cause of charcoal rot, a disease of emerging importance in strawberry production systems. Brassicaceae seed meals (SM) and prior cultivation of soils with wheat were evaluated for the capacity to suppress charcoal rot of strawberry and to determine the relative contribution of seed meal derived chemistry and soil biology in disease control. Brassicaceae seed meal amendments suppressed the abundance of M. phaseolina detected in soil systems, but optimal SM-induced pathogen suppression required a functional soil biology. Suppression of M. phaseolina was obtained with SM sourced from various Brassicaceae species and was not associated with a biologically active chemistry such as that generated by Brassica juncea SM amendment (e.g. allyl isothiocyanate). Disease control observed in natural soil was abolished when SM amended soils were pasteurized prior to infestation with M. phaseolina, suggesting a functional role of soil biology in disease suppression that was observed. Cultivation of soils with wheat prior to pathogen infestation resulted in a level of disease control superior to SM amendment, however no additive effect on disease suppression was observed with integration of the two treatments. In small scale field trials, SM amendment induced phytotoxicity was observed and may have contributed to a lack of apparent control of charcoal rot. In the same trials, significant weed control was achieved in response to SM amendment. Across trials conducted in controlled and field environments there has been a lack of consistent association between the effect of SM amendment or wheat cultivation on M. phaseolina soil density and resulting level of root infection. This suggests that the observed disease control may have a greater dependence upon microbial interactions that transpire in the rhizosphere than that which occurs in the bulk soil environment.     

Inactivation of Macrophomina phaseolina Propagules during Composting and Effect of Composts on Dry Root Rot Severity and on Seed Yield of Clusterbean

Survival of a heat-tolerant pathogen Macrophomina phaseolina, causing dry root rot of clusterbean, was studied by incorporation and retrieval of infected residue samples at various stages of the composting process of pearl millet (Pennisetum glaucum) and clusterbean (Cyamopsis tetragonoloba) residues. During the heating phase, temperatures varied from 48–51°C at 30cm and 60–62°C at 60cm depth in compost pits. Reduction in survival of M. phaseolina propagules (13–23%) was significantly higher in the residues enriched with 4% urea-N and kept at 60cm compared to 2% urea-N and at 30cm. However, a heat phase (48–62°C) was not enough to completely eradicate M. phaseolina propagules from infected residues. Further reductions (54–61%) in survived propagules were achieved by sub-lethal temperatures (48–53°C) when moistened compost materials were exposed to heat during summer days. Beneficial effects of composts were ascertained on dry root rot intensity, seed yield of clusterbean and densities of M. phaseolina, Nitrosomonas and antagonists in soil. In a two-year field study, all the composts significantly reduced plant mortality due to dry root rot and increased the yield of clusterbean. The highest disease suppression and yield promotion were recorded in soil amended with pearl millet compost and cauliflower leaf residue compost, respectively. Soil amendment with compost also lead to a significant reduced density of M. phaseolina and an increased density of antagonistic actinomycetes, lytic bacteria and Nitrosomonas. Among composts, greater potential of cauliflower compost in enhancing population of antagonists in soil was discernible.     

Charcoal rot in common bean with special reference to Kenya

Abstract

Charcoal rot caused by Macrophomina phaseolina (Deuteromycetes: Coelomycetes) is found throughout the tropics and subtropics and has a wide host range. Together with most of the legume crops, the common bean (Phaseolus vulgaris) Is a good host for the fungus which causes a range of symptoms, depending on environmental conditions and age of the plant. In addition to charcoal rot, which is a stem or stalk rot disease, the pathogen also causes damping‐off and seedling blight in beans. Charcoal rot in the mature plant is associated with senescence which is accelerated by water stress. The disease is most damaging in areas of unreliable rainfall and high temperature. In Kenya, beans are usually grown in mixed stands with maize, sorghum or millet. Population pressure has led to the cultivation of beans on land prone to drought. M. phaseolina is one of the most important pathogens affecting all the main crops of the farming systems in the semi‐arid areas of eastern Kenya and resistance to charcoal rot is a priority if beans are to be increasingly grown in these areas. The paper reviews the literature on charcoal rot of beans and on other crops where similar work has not been reported specifically for beans.     

Reduced sclerotial viability of Stromatinia cepivora and control of white rot disease of onion and garlic by means of soil bio-solarization

The suppressive effects of soil bio-solarization, which is a new method of soil disinfestation that combines soil bio-fumigation with soil solarization, against the sclerotial viability of Stromatinia cepivora and the subsequent control of white rot disease of onion and garlic were evaluated. Soil was bio-fumigated with fresh amendments of cow manure, chicken manure, horse manure, cruciferous plant residues, or Allium waste, at 30,000 kg/ha. After bio-fumigation, the soil was irrigated and covered with a 200 μm transparent plastic sheet for 60 days. Plots that received fresh amendment and remained uncovered and untreated served as controls. Solarization alone increased the maximum soil temperature to 55.3 °C, 50.3 °C and 46.3 °C at 10, 20, and 30 cm depths, respectively, which led to significant reductions (98.0%, 89.3%, and 62.7%, respectively) in the sclerotial viability of S. cepivora. Soil bio-solarization with cruciferous plant residues or Allium waste resulted in the strongest negative effects on the sclerotial viability of S. cepivora, with reductions of 100.0%, 98.7%, and 87.3% or 100.0%, 99.3%, and 87.7%, at 10, 20, and 30 cm depths, respectively. Compared to the non-treated control, these treatments significantly reduced the incidence of white rot disease in onion and garlic, which led to increases in onion and garlic yield in fields that were heavily infested by S. cepivora.

     

Etiology of and effect of environmental factors on damping-off and stem rot of cowpea in Benin

Damping-off and stem rot are two types of diseases affecting cowpea (Vigna unguiculata (L.) Walp.) in the Quémé Valley, Benin. Of the fungal species isolated from diseased plants in the field during a 2-year experiment (2001 and 2002),Sclerotium rolfsii Sacc. was found to be solely responsible for these diseases. The disease incidence decreased with increasing distance of the field from the river. Measurement ofS. rolfsii initial inoculum, soil moisture and disease incidence in cowpea field plots revealed a positive correlation among these parameters. The multiple regression analysis showed that the disease incidence increase was 0.4% for one unit increase in soil moisture percent, whereas the disease incidence increase was 19.8% for one unit increase of the density of initial inoculum of the pathogen. This is the first comprehensive study of the effects of environmental factors on the incidence of cowpea damping-off and stem rot caused byS. rolfsii in Benin, and shows that the density of the initial inoculum is the main contributing factor of the disease in the field in the Quémé Valley. http://www.phytoparasitica.org posting Dec. 19, 2004.     

Biological Soil Disinfestation (BSD), a new control method for potato brown rot,caused by <Emphasis Type="Italic">Ralstonia solanacearum</Emphasis> race 3 biovar 2

The potential of Biological Soil Disinfestation (BSD) to control potato brown rot, caused by Ralstonia solanacearum race 3 biovar 2, was investigated. BSD involves the induction of anaerobic soil conditions by increasing microbial respiration through incorporation of fresh organic amendments (here: grass or potato haulms) and by reducing re-supply of oxygen by covering with airtight plastic sheets. Control treatments were left without cover and amendment, or amended without covering or covered only without amendment. The effect of BSD on survival of R. solanacearum was tested at three different scales: in 1-l glass mesocosms under laboratory conditions, in 1.2-m-diam microplots positioned in an outdoor quarantine field, and in a naturally infested commercial field. Within a few days, anaerobic conditions developed in the BSD-treated soils. In the mesocosm and microplot experiment, anaerobic conditions persisted till the end of the 4-week experimental period. In the field experiment, the period of anaerobiosis was shorter due to birds damaging the plastic cover. In all three experiments, BSD reduced soil populations of R. solanacearum significantly by 92.5% to >99.9% compared to the non-amended and uncovered control treatments. In the field experiment, BSD also resulted in a significant reduction of R. solanacearum survival in potato tubers buried at 15 or 35 cm and in the rapid decomposition of superficially buried potatoes remaining after harvesting, thus destroying an important inoculum reservoir of R. solanacearum. The treatments with grass amendment only or covering with only plastic did not result in anaerobic conditions and did not decrease R. solanacearum populations during the experimental period. PCR-DGGE analyses of 16S-rDNA from soil samples of the various treatments in the mesocosm and microplot experiments revealed that BSD hardly affected bacterial diversity but did result in clear shifts in the composition of the bacterial community. The possible implications of these shifts are discussed. It is concluded that BSD has the potential to strongly decrease soil infestation levels of R. solanacearum and to become an important element in a sustainable and effective management strategy for potato brown rot, especially in areas where the disease is endemic.     

Root rot pathogens in field soil,roots and seeds in relation to common bean (Phaseolus vulgaris), disease and seed production

The interrelationships among bean productivity, prevalence of pathogens in roots, seeds and soil, and root rot disease were described at the pod maturity stage in 13 commercial fields. The soil population and frequency of pathogens isolated from seeds varied by pathogen species and field location. Fusarium solani was the most prevalent fungus isolated from bean seeds and field soil compared to Rhizoctonia solani, Macrophomina phaseolina and F. oxysporum. Principal component analysis revealed that the first component explaining 32% of the total variance was correlated with the root rot index. PC1 was more strongly linked to root and seed infections in comparison with soil populations of pathogens. Based on a correlation between PC2 (accounting for 23% of the total variance) and the number of seeds per bean plant, charcoal, Fusarium and Rhizoctonia root rots were recognized as more important determinants of seed losses to root rot disease. There were correlations among the major pathogens infecting either roots or seeds of beans. These findings provide useful information for future experimental plans to optimize management strategies for bean root rots.     

Infection of mungbean seed by Macrophomina phaseolina is more likely to result from localized pod infection than from systemic plant infection

The ubiquitous fungal pathogen Macrophomina phaseolina is best known as causing charcoal rot and premature death when host plants are subject to post‐flowering stress. Overseas reports of M. phaseolina causing a rapid rot during the sprouting of Australian mungbean seed resulted in an investigation of the possible modes of infection of seed. Isolations from serial portions of 10 mungbean plants naturally infected with the pathogen revealed that on most plants there were discrete portions of infected tissue separated by apparently healthy tissue. The results from these studies, together with molecular analysis of isolates collected from infected tissue on two of the plants, suggested that aerial infection of aboveground parts by different isolates is common. Inoculations of roots and aboveground parts of mungbean plants at nine temperature × soil moisture incubation combinations and of detached green pods strongly supported the concept that seed infection results from infection of pods by microsclerotia, rather than from hyphae growing systemically through the plant after root or stem infection. This proposal is reinforced by anecdotal evidence that high levels of seed infection are common when rainfall occurs during pod fill, and by the isolation of M. phaseolina from soil peds collected on pods of mungbean plants in the field. However, other experiments showed that when inoculum was placed within 130 mm of a green developing pod and a herbicide containing paraquat and diquat was sprayed on the inoculated plants, M. phaseolina was capable of some systemic growth from vegetative tissue into the pods and seeds.     

Soil solarization as a substitute for methyl bromide fumigation in greenhouse tomato production in Cyprus

Preplant soil fumigation with methyl bromide (MB) is presently standard practice in greenhouse tomato production. Since this compound is scheduled to be phased out by 2005, the possibility of using solarization as an alternative soil disinfestation method was examined in four greenhouse tomato trials. Solarization was applied for 8 weeks in July-August, using transparent polyethylene sheets for soil mulching, and compared with MB fumigation applied in September, before planting, at 80 g/m². Solarization raised the maximum soil temperature by 9°C and reduced the population density ofFusarium spp. in soil by 91–98%. Similar reductions of soil inoculum (95–99%) were obtained with MB fumigation. Both methods provided effective control of Fusarium wilt, Verticillium wilt and corky root rot on tomato plants. MB fumigation was in addition highly effective against root-knot nematodes, whereas nematode control with solarization did not exceed 50%. Both treatments resulted in similar fruit yield increases, ranging within 90–140% compared with plants grown in untreated soil. During the second cropping season following soil treatment, solarization exhibited two times higher residual effectiveness against vascular wilt diseases compared with MB fumigation. The latter treatment, however, was superior to solarization in its residual effectiveness against root-knot nematodes and to a lesser extent against corky root rot. Fruit yields from solarized and MB-fumigated soil during the second cropping season were higher than those obtained from untreated soil by approximately 35% and 60%, respectively. In Cyprus, solarization appears to be an effective alternative to MB fumigation in greenhouse tomato production, especially if integrated with other approaches enabling more effective nematode control.     

Potato brown rot incidence and severity under different management and amendment regimes in different soil types

Ralstonia solanacearum race 3 biovar 2, the causative agent of potato brown rot (bacterial wilt), is an economically important disease in tropical, subtropical and temperate regions of the world. In view of previous reports on suppression of the disease by organic amendments, and the expansion of organic agriculture, it was timely to compare the effects of organic and conventional management and various amendments on brown rot development in different soils (type: sand or clay; origin: Egypt or the Netherlands). Brown rot infection was only slightly reduced in organically compared to conventionally managed sandy soils from Egypt, but organic management significantly increased disease incidence and pathogen survival in Dutch sandy and clay soils, which correlated with high DOC contents in the organic Dutch soils. There was no correlation between disease incidence or severity and bacterial diversity in the potato rhizosphere in differently managed soils (as determined by 16S DGGE). NPK fertilization reduced bacterial wilt in conventional Egyptian soils but not in Dutch soils. Cow manure amendment significantly reduced disease incidence in organic Dutch sandy soils, but did not affect the bacterial population. However, cow manure did reduce densities of R. solanacearum in Egyptian sandy soils, most probably by microbial competition as a clear shift in populations was detected with DGGE in these and Dutch sandy soils after manure amendment. Amendment with compost did not have a suppressive effect in any soil type. The absence of a disease suppressive effect of mineral and organic fertilization in Dutch clay soils may be related to the already high availability of inorganic and organic nutrients in these soils. This study shows that the mechanism of disease suppression of soil-borne plant pathogens may vary strongly according to the soil type, especially if quite different types of soil are used.     

Solarization and natural heating of irrigated soil amended with cruciferous residues for improved control of Macrophomina phaseolina

The efficacy of summer irrigation and soil solarization combined with cruciferous residues was tested against the dry root rot pathogen Macrophomina phaseolina in an arid climate. In irrigated amended soil, polyethylene mulching during May increased the soil temperature to 57°C and 50°C at depths of 0–15 and 16–30 cm, respectively. As a result, within l5 days the population of M. phaseolina was almost eradicated (93–99%) at both soil depths. A considerable reduction (75–96%) was also achieved by natural heating of irrigated soil (46–53°C) for l5 days after amending with cruciferous residues. Mulching alone was only partially effective (69–89% reduction). These results suggest a new approach to controlling soil-borne pathogens in hot, arid regions by combining summer irrigation with soil amendment. Amendment with residues alone or in conjunction with soil solarization also increased the population of lytic bacteria against M. phaseolina .     

Fusarium wilt of watermelon in Cyprus and its management with soil solarization combined with fumigation or ammonium fertilizers

Fusarium wilt is a limiting factor to watermelon production in Cyprus. In previous studies, soil solarization applied in 1-m-wide strips provided only partial disease control. In order to improve the effectiveness of solarization, three field experiments were carried out in heavily infested soils, using various solarization techniques, alone or in combination with methyl bromide fumigation or soil amendments with ammonium-based fertilizers. Increasing the width of the solarization strip from 1 to 2 m had no significant influence on its effectiveness. Solarization with a double rather than single polyethylene sheet, in either 1- or 2-m-wide strips, improved slightly the level of wilt control but had no significant effect on yield. Combined solarization–methyl bromide treatments, however, improved significantly the level of wilt control and increased marketable yield by up to 100% over that obtained with either method alone. The low rate of methyl bromide (50gm⁻²) was as effective as the normal rate used by growers (100 g m⁻). Soil amendment with ammonium-based fertilizers improved even more the effectiveness of solarization and increased yield by up to 200% over that obtained with solarization alone. Best results were obtained with ammonium sulphate or monoammonium phosphate at a rate equivalent to 180 kg N ha⁻¹.     

Macrophomina phaseolina–host interface: Insights into an emerging dry root rot pathogen of mungbean and urdbean,and its mitigation strategies

The necrotrophic fungus Macrophomina phaseolina is an important pathogen of many crops, such as strawberry, maize, sorghum, potato, soybean, chickpea, and pigeon pea, and causes multiple diseases throughout the world. The microsclerotia, which are the source of primary inoculum, play an important role in the survival and spread of M. phaseolina, as well as disease initiation and development. South Asia has unique characteristics relative to countries with temperate climates, that is, warm temperature, high humidity, and reduced rainfall that influence the interaction between M. phaseolina and its hosts. This review discusses the distribution pattern, pathogen background, pathogenic and genetic variability, and the mitigation strategies applied worldwide to reduce the impact of diseases caused by M. phaseolina with a focus on dry root rot of mungbean and urdbean in South Asia. Dry root rot, caused by M. phaseolina, is an emerging disease of mungbean and urdbean in South Asia. Dry root rot research in South Asia has focused mostly on adopting disease mitigation strategies evolved in tropical to temperate climates such as cultural practices, chemical control, genetic resistance, and biological control. Although the disease is prevalent in most of South Asia, there have been very few studies on M. phaseolina and its host–parasite interaction. Therefore, additional research is required in this domain, which could result in improved understanding and management of M. phaseolina in the face of present and future climate extremes.     

Manipulating inoculum densities of Verticillium dahliae and Pratylenchus penetrans with green manure amendments and solarization influence potato yield

We used cover crops with demonstrated efficacy against Verticillium dahliae and Pratylenchus penetrans in combination with the biocidal practice of solarization to determine the importance of targeting both organisms for managing potato early dying, an issue relevant to the search for alternatives to soil fumigation. Two experiments were conducted in commercial fields using a split-plot design with cover crop treatments of rapeseed, marigold, forage pearl millet, sorghum-sudangrass, and corn as the main plot factor and solarization as the subplot factor. Cover crops were grown and solarization applied in year one, followed by potato in year two. The main effect of solarization was significant for reduced inoculum levels of both organisms in year two and increased tuber yields. The main effect of cover crop was also significant with lower population densities of P. penetrans following the marigold and millet treatments and of V. dahliae following rape and sorghum-sudangrass. The cover crop treatments influenced yield in only one of the experiments in the absence of solarization. The combinatorial effect of cover crops and solarization resulted in a wide range of pathogen population densities. Mean soil inoculum levels were negatively related to yield for V. dahliae in experiment 1, and for P. penetrans and the P. penetrans × V. dahliae interaction in both experiments.     

Role of stalk-anatomy and yield parameters in development of charcoal rot caused byMacrophomina phaseolina in winter sorghum

Charcoal rot caused byMacrophomina phaseolina (Tassi) Goid. damages stalk tissue and weakens stalk strength, leading to lodging of crop and loss in grain yield in sorghum. In an attempt to understand the pathogenicity byM. phaseolina in relation to stalk characters and plant outputs, the effects of morphological (stalk-thickness), anatomical (bundle-number, bundle-density, and vascular tissue) and physiological characters (water and soluble sugar content) of the stalks of winter sorghum genotypes on charcoal rot development were analyzed. Bundle-number and stalk-thickness had a significant influence on internal spread of charcoal rot. A thicker stalk facilitated the spread of lesions more than did a thinner one. A stalk with densely packed vascular bundles inhibited lesion advancement. Field studies with 24 winter sorghum genotypes demonstrated that most of the parameters that could improve grain and stover yield also increased the length of charcoal rot lesions. Lesion development in stalks showed a high degree of association with grain yield (R²=0.51) and 100-grain weight (R²=0.42). The rate of symptom development in stalks differed during dough and maturity stages. It was concluded that anatomical characters of sorghum stalk, especially bundle-number, along with yield parameters played an important role in determining the extent of stalk damage by charcoal rot in winter sorghum. http://www.phytoparasitica.org posting March 25, 2008.     

Evaluation of Bacillus spp. isolates as potential biocontrol agents against charcoal rot caused by Macrophomina phaseolina on common bean

The fungus Macrophomina phaseolina, the causal agent of charcoal rot of common beans, damages the roots, stems, and leaves of seedlings and plants and forms resistant structures, so that chemicals are not sufficient for disease control. Integrated management systems associated with the use of biological control techniques are a sustainable alternative. Here we collected 37 native bacterial isolates from the common bean rhizosphere and screened them for antagonistic activity against M. phaseolina. Four isolates (BA97, BN17, BN20, and BR20) identified as Bacillus spp. showed antagonism in vitro against M. phaseolina, inhibiting its growth by 62.5–85%. In an in planta antagonistic assay, isolate BN20 reduced disease severity the most. Isolates BA97, BN17, BN20, and BR20 produced volatile compounds as a mechanism of antagonism. They also produced indole acetic acid in vitro (1.98–3.87 μg/ml). These results suggest that seed bacterization with the rhizobacterial isolates for field planting may be an effective means to reduce crop damage by M. phaseolina.

     

Water relations,histopathology and growth of common bean (Phaseolus vulgaris L.) during pathogenesis of Macrophomina phaseolina under drought stress

Alterations in water relations, growth and histopathology caused by Macrophomina phaseolina, causal agent of charcoal rot, and drought stress were characterized in Phaseolus vulgaris L. under controlled conditions.P. vulgaris cultivars BAT 477 and TLP 19 (resistant) and Pinto UI-114 and Rio Tibagi (susceptible) were cultivated under irrigation and drought stress conditions in infested or uninfested pots with a highly virulent isolate ofM. phaseolina . Drought stress showed higher negative effects than M. phaseolina on water relations, vegetative growth and histopathology in P. vulgaris. Drought stress decreased transpiration rate, water potential, osmotic potential, turgor potential, relative water content, leaf area and dry weight of all vegetative structures of P. vulgaris. Drought stress increased charcoal rot development and stomatal resistance, and increased the association among physiological and growth characteristics and charcoal rot development. M. phaseolina invaded between epidermal cells of BAT 477 and Pinto UI-114 hypocotyls. The fungus infected cortex tissues, vascular cylinder, and pith cells of Pinto UI-114, but only epidermal and parenchyma cells of BAT 477. Typical symptoms caused by M. phaseolina were found to be associated with damage caused by the fungus on host tissues, and they were related to drought stress.     

Incidence of root rot of muskmelon in different soil management practices

The objective of this study was to estimate the effects of tillage systems and cover crops on the incidence of root rot in melon and to identify the fungal pathogens associated with the disease. Two consecutive trials were carried out in a randomized complete block design with four replications in each trial. The treatments were arranged in split-plots. Two tillage systems (no-tillage (NT) and conventional tillage (CT)) were assigned in the main plots and in the subplot the six types of ground cover crops were tested (sunn hemp, pearl millet, sunn hemp + pearl millet, corn + brachiaria, spontaneous vegetation, spontaneous vegetation + polyethylene film) or bare soil. At the end of the trials all melon plants were collected and assessed for disease incidence, isolations from symptomatic plants were made for fungal identification. Root rot incidence was lower in the NT treatments with sunn hemp, pearl millet, and spontaneous vegetation. The main fungi isolated from symptomatic roots were Fusarium solani, Macrophomina phaseolina, Monosporascus cannonballus and Rhizoctonia solani, but F. solani was the most frequently isolated fungus in both tillage systems. The results suggest that the NT system has the potential to control incidence of root rot of muskmelon, but is necessary to realize crop rotation between the planting cycles.     

In-vitro characterization of the behaviour of Macrophomina phaseolina (Tassi) Goid at the rhizosphere and during early infection of roots of resistant and susceptible varieties of sesame

There are major gaps in our knowledge of the stages of infection in soil borne pathogens. Soil borne diseases, such as charcoal root rot caused by Macrophomina phaseolina on sesame, have been studied, yet due to the difficulty in observing fungal behaviour in the soil, there has been no detailed study of the infection events. Moreover no study has attempted to compare the infection events in roots of resistant versus susceptible hosts. We present the first ultra-structural report to characterize the behaviour of the fungus in the proximity of the root, the appearance of fungal hyphae on the surface of roots, microsclerotia formation on hyphal strands, early penetration events and subsequent infection processes of M. phaseolina in sesame. We observed distinct differences in fungal behaviour in the rhizosphere and during infection of susceptible and resistant varieties. This study also describes a framework for comparative experiments. The possible reasons for the difference in behaviour of M. phaseolina in the vicinity of and during infection of roots of resistant vs. susceptible varieties of sesame and its implications for disease resistance are discussed.     

Population Dynamics of Fusarium Oxysporum f. Sp. Radicis-lycopersici in Relation to the Onset of Fusarium Crown and Root Rot of Tomato

Fusarium oxysporum f. sp. radicis-lycopersici the causal agent of crown and root rot in tomato comprises two overlapping separate phases: monocyclic and polycyclic. Oversummering inoculum is the source of primary infection (the monocyclic phase) and the spread from plant to plant via root-to-root contact is the source of the secondary infection (the polycyclic phase). In the present work, relationships between initial inoculum density, population dynamics of the pathogen in the root zone of diseased plants, and disease onset were studied. For the monocyclic phase, 55.1% of the variance of disease onset was attributed to the rate of pathogen proliferation in the root zone of plants, and only 12.8% of the variance was attributed to the amount of initial inoculum density. For the polycyclic phase, disease onset was not related to either initial inoculum density or the rate of pathogen proliferation in the root zone. At disease onset, the inoculum density of the pathogen in the root zone of plants infected from oversummering inoculum reached an average of 4.08 log cfu g soil^–1. The inoculum density of the pathogen in the root zone of plants infected by their diseased neighbors was 3.23 log cfu g soil^–1. A large variation in pathogen proliferation rate in the root zone was found among individual plants, suggesting that differences in the level of soil suppressiveness may occur not only between fields, but even in the same field over short distances.