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Root rot

Root rot is a collective term for destructive plant diseases caused by soilborne pathogens, primarily fungi and oomycete water molds such as Phytophthora spp., Pythium spp., Fusarium spp., and Rhizoctonia solani, which infect and decay the root system, impairing water and nutrient uptake and often resulting in wilting, stunted growth, foliage yellowing, and plant death. These diseases affect a broad spectrum of plants, including herbaceous ornamentals, fruit and nut trees, vegetables like tomatoes and peppers, field crops such as wheat and cotton, and woody species in forests and landscapes, with susceptibility heightened in species like citrus, raspberries, and ginseng under stressful conditions. The pathogens thrive in compacted or waterlogged soils, where prolonged moisture allows oospores and sclerotia—durable survival structures—to germinate and spread via splashing water, contaminated tools, or infected plant material, persisting in soil for years or even decades. Symptoms typically begin belowground with roots turning soft, dark brown to black, and mushy, progressing to aboveground signs like sudden during the day, leaf chlorosis or purplish discoloration, canopy dieback, and in severe cases, the presence of fungal fruiting bodies or mushrooms near the base; affected plants may be easily pulled from the due to weakened anchorage. Economically, root rot inflicts substantial losses, such as over 40% mortality in plantations in costing millions annually, and widespread damage to agricultural and horticultural crops worldwide. Management focuses on cultural practices to prevent infection, including improving soil drainage through raised beds or amendments, avoiding overwatering and deep planting, selecting resistant cultivars, and practicing to disrupt cycles; chemical controls like phosphorous acid-based fungicides or biological agents such as Gliocladium spp. can suppress symptoms when applied preventively, though via lab testing is essential for targeted intervention.

Definition and Overview

What is Root Rot

Root rot is a characterized by the invasion and subsequent of roots by pathogenic microorganisms, which disrupts the 's ability to absorb and nutrients from the . This condition, often resulting from soilborne pathogens such as fungi and , leads to the progressive deterioration of the root system, compromising overall health and vigor. The impairs root , restricting the uptake of essential resources and ultimately contributing to decline if unchecked. The basic mechanism of root rot involves pathogens colonizing the root tissues, where they secrete extracellular enzymes like pectinases, cellulases, and proteases to break down cell walls and other structural components. These enzymes facilitate the digestion of root tissues, causing softening and necrosis that renders the roots non-functional. As the decay advances, the affected roots become blackened and mushy, further exacerbating the loss of absorptive capacity and leading to systemic plant stress. Root rot affects a broad spectrum of plants, including ornamentals, vegetables, trees, and various crops such as legumes, cereals, and fruit trees, making it a widespread issue in agriculture and horticulture. It is particularly prevalent in environments with excessive soil moisture and poor drainage, where conditions favor pathogen survival and proliferation. Globally, this disease poses a significant threat to crop productivity, with pathogens capable of persisting in soil for years.

Significance in Plants

Root rot represents a major threat to agricultural productivity worldwide, causing substantial yield reductions in key crops. For instance, Phytophthora root rot in tomatoes can result in 30-40% yield losses in greenhouse settings under Mediterranean conditions. These impacts extend to economic burdens on farmers, including increased costs for replanting and management, affecting vegetable production on a scale that underscores root rot's role in food security challenges. In forest ecosystems, root rot disrupts community structure and dynamics, leading to widespread tree mortality and altered . Armillaria root rot, prevalent in forests, kills mature trees and prevents regeneration, shifting species composition and reducing overall stand health. Outbreaks contribute to by favoring opportunistic species while eliminating dominant , as seen in forests where infected areas show diminished canopy cover and increased dead wood accumulation. This ecological disturbance can exacerbate vulnerability to secondary stressors like and , amplifying long-term effects on habitat quality. For houseplants and ornamental species, root rot is a prevalent issue in controlled environments, often resulting from overwatering in pots and leading to frequent plant replacements. In nurseries, Phytophthora-induced root rots are among the primary causes of crop loss for floricultural and woody ornamentals, necessitating high discard and replacement rates to maintain inventory quality. Home gardeners similarly face recurring losses, with affected potted plants commonly discarded due to irreversible root damage, highlighting the disease's impact on urban and hobbyist horticulture.

Causes

Pathogenic Agents

Root rot is primarily caused by a diverse group of soilborne microorganisms, including oomycetes and true fungi, which exploit water-saturated conditions to infect plant roots. Oomycetes, often referred to as water molds despite their fungus-like appearance, belong to the Stramenopiles group within the kingdom Chromista and include genera such as Phytophthora and Pythium, which are among the most destructive agents due to their ability to rapidly colonize saturated soils. True fungi, classified within the kingdom Fungi, encompass species like Fusarium, Rhizoctonia, and Armillaria, which form robust mycelial networks adapted for persistence and spread in moist environments. Oomycetes such as Phytophthora (e.g., P. cinnamomi) and Pythium (e.g., P. ultimum) produce motile zoospores that enable swift dissemination through standing water or film-like moisture on soil particles, facilitating infection in poorly drained conditions. These zoospores encyst on root surfaces and germinate to form mycelia that penetrate root tissues directly or through natural openings, thriving in saturated soils where oxygen levels are low. Over 100 species of Phytophthora and more than 200 of Pythium are known to cause root rot, with their biology characterized by coenocytic hyphae and a dependence on water for sporulation and spread. In contrast, true fungi like Fusarium (e.g., F. solani), Rhizoctonia (e.g., R. solani), and Armillaria (e.g., A. mellea) rely on septate mycelia for growth and invasion, forming extensive networks that penetrate roots primarily via wounds, root hairs, or injured tissues. Fusarium species produce toxins and enzymes that disrupt host defenses, while Rhizoctonia utilizes chitinases and other degradative compounds to breach cell walls; Armillaria spreads through root-to-root contact via rhizomorphs—black, shoestring-like structures that transport nutrients and propagules over long distances in soil. These fungi persist as dormant sclerotia or rhizomorphs in soil, reactivating in moist conditions to infect a wide range of crops and trees. The infection process for both oomycetes and fungi involves initial adhesion to root surfaces, followed by enzymatic degradation of the cuticle and cell walls using cellulases, pectinases, and other hydrolases, which release nutrients and allow hyphal ingress into cortical tissues. Once inside, pathogens secrete additional toxins and enzymes that induce tissue necrosis, impair water uptake, and promote further rot, often leading to systemic colonization if unchecked. This process is exacerbated by saturated soils, which not only aid pathogen motility but also weaken plant barriers.

Environmental Contributors

Overwatering and poor drainage are primary environmental contributors to root rot, as they create waterlogged conditions that deplete soil oxygen, leading to anaerobic environments where roots become stressed and more vulnerable to decay. In such saturated soils, root respiration is impaired due to insufficient aeration, causing cellular damage and reduced nutrient uptake, which weakens plant defenses. For instance, heavy clay soils that retain excessive moisture after irrigation or rainfall exacerbate this issue by limiting water percolation. Compacted soils further aggravate these problems by reducing pore space, which hinders air exchange and promotes water retention, intensifying anaerobic conditions around roots. Soil compaction, often resulting from heavy foot traffic, machinery, or natural settling in fine-textured soils, significantly reduces porosity and leads to low oxygen levels that stress roots and predispose them to rot. Examples include urban landscapes or agricultural fields where repeated tillage creates dense layers that impede root growth and aeration. Warm temperatures combined with high humidity or prolonged soil wetness also play a significant role in predisposing plants to root rot by enhancing environmental suitability for decay processes. Optimal conditions for many root rot scenarios fall within 20-30°C, where elevated soil moisture from humid climates or over-irrigation accelerates tissue breakdown; for example, in regions with summer temperatures averaging 25°C and frequent rains, poorly managed drip irrigation systems can maintain saturated zones that stress roots. These factors indirectly favor pathogen activity under wet, warm settings. In certain cases, high soil pH contributes to root rot susceptibility by altering nutrient availability and root health, particularly in alkaline environments above pH 7.0. For instance, Phymatotrichum root rot thrives in calcareous soils with pH 7.0-8.2 and low organic matter, where elevated pH limits iron and phosphorus uptake, weakening roots in crops like cotton. Similarly, take-all root rot in turfgrasses is more severe in soils with pH exceeding 6.5, as high alkalinity stresses plants and reduces microbial competition. Planting in contaminated nursery stock, often carrying persistent soil residues from infested sites, can introduce predisposing moisture-retentive media that mimic poor drainage conditions post-transplant.

Symptoms and Diagnosis

Visible Indicators

Root rot manifests through distinct above-ground symptoms that often mimic other plant stresses, such as drought or nutrient deficiencies, making early recognition crucial for differentiation. Common indicators include wilting of leaves and stems despite sufficient soil moisture, as the compromised root system fails to absorb water effectively. Yellowing or browning of foliage, known as chlorosis, typically begins in older leaves and progresses inward, accompanied by stunted growth where new shoots appear smaller and less vigorous. In affected trees, premature leaf drop and canopy thinning further signal decline, with branches losing density over time. Below-ground signs are more definitive upon inspection, revealing pathogen-induced in the tissues. Infected turn dark brown to black, becoming soft and mushy in texture, often emitting a foul, rotten due to tissue breakdown. In contrast, healthy roots remain firm, white, and fibrous, providing a clear visual for comparison. The disease typically progresses from subtle above-ground cues, such as minor wilting and leaf discoloration, to severe outcomes including branch dieback and eventual plant collapse if left unaddressed.

Confirmation Techniques

Field inspection serves as the initial step in confirming root rot, involving careful excavation of the root system using a trowel or similar tool to avoid further damage. Once exposed, roots are gently rinsed to reveal their condition: healthy roots appear firm, white, and fibrous, while rotted ones are typically soft, discolored (brown to black), mushy in texture, and may emit a foul odor indicative of decay. A key diagnostic cue is the "tug test," where the outer cortex of infected roots slips easily off the central vascular core, confirming rot rather than mere discoloration. This method allows growers to assess root health in situ, particularly after observing above-ground symptoms like wilting or stunting. For more precise identification, laboratory methods provide definitive confirmation by isolating and characterizing the causative pathogens. Culturing involves plating root tissue samples on selective media, such as agar tailored for oomycetes like Phytophthora, to promote pathogen growth and enable morphological identification under microscopy. Polymerase chain reaction (PCR) testing amplifies pathogen-specific DNA from root or soil samples, offering rapid and sensitive detection even at low infection levels, with results verifiable through gel electrophoresis. Soil sampling techniques, including baiting assays where susceptible host plants are grown in suspect soil to attract pathogens, further quantify pathogen presence, such as oospores per gram of soil. Samples should be collected from the infection margin—transitional tissue between healthy and rotted areas—and submitted promptly to diagnostic labs to maintain viability. Differential diagnosis is essential to rule out abiotic mimics like drought stress or nutrient deficiencies, which can produce similar foliar symptoms but lack pathogenic indicators. Microscopy of root sections reveals fungal hyphae, oospores, or other microbial structures in rot cases, absent in stress-induced damage where roots may appear shriveled but intact. Bioassays, such as inoculating healthy seedlings with soil extracts and monitoring symptom development, help confirm pathogenicity by reproducing rot in controlled conditions, distinguishing it from non-infectious wilting that resolves with rehydration. Nutrient deficiencies typically manifest as uniform chlorosis without root decay, verifiable through tissue analysis showing elemental imbalances rather than pathogen DNA. Integrating these approaches ensures accurate attribution to root rot over environmental factors.

Prevention

Cultural Methods

Cultural methods for preventing root rot emphasize routine plant care practices that minimize moisture accumulation and promote healthy root environments without relying on chemical interventions. These approaches focus on optimizing watering, planting, and selection decisions to reduce disease incidence across various crops and ornamentals. Proper watering is fundamental to root rot prevention, as excessive creates favorable conditions for pathogenic fungi and . Gardeners should allow the top few inches of to dry out between waterings, tailoring frequency to the plant's needs and environmental conditions to avoid saturation. Overwatering exacerbates root rot risks by prolonging wet conditions that pathogens exploit. Using meters provides an objective way to monitor levels in the root zone, ensuring only when necessary and preventing both stress and overhydration. Effective planting techniques further mitigate root rot by enhancing and around roots. Plants should be spaced adequately to allow for air circulation, following species-specific recommendations, which reduces buildup and limits spread. Overcrowding should be avoided, as it can lead to uneven drying and increased moisture retention. Additionally, selecting planting sites with inherent good , such as elevated or sloped areas away from low-lying water collectors, helps excess water percolate away from roots efficiently. Choosing root rot-resistant plant varieties is a proactive cultural strategy that builds inherent disease tolerance into the garden. For example, certain hybrids have been bred for resistance to crown and root rot, enabling successful cultivation in moderately susceptible soils. Similarly, in woody ornamentals, selections like (summersweet) exhibit strong tolerance to root rot, outperforming susceptible species in wetter landscapes. Prioritizing such cultivars reduces the need for intensive interventions while maintaining productivity.

Site and Soil Preparation

Proper site and soil preparation is essential to minimize the risk of root rot by ensuring optimal conditions for prior to planting. testing should be conducted to assess , levels, and capacity, allowing for targeted amendments that promote well-aerated, free-draining conditions. For most plants susceptible to root rot, a of 6.0 to 7.0 is recommended, as this range supports availability while suppressing certain pathogenic fungi that thrive in more acidic or alkaline environments. To improve drainage in heavy or clay soils, incorporate such as at a rate of 2-4 inches mixed into the top 6-12 inches of , which enhances , increases , and reduces waterlogging. In areas with persistently poor , constructing raised beds provides an effective solution by allowing excess water to percolate away from roots more readily. Poor is a key environmental contributor to root rot, as it creates conditions favorable for proliferation. Further drainage enhancements include installing French drains—trenches filled with and perforated —to redirect surface and subsurface away from planting sites, particularly in low-lying areas prone to water accumulation. Avoid selecting sites near downspouts or depressions where pools, as these exacerbate moisture retention around . Sanitation practices during preparation are critical to prevent the introduction of root rot pathogens. Tools and must be sterilized before use; for example, soak in a 1:9 bleach-to-water solution for at least 10 minutes, followed by thorough rinsing, to eliminate fungal spores. Always source disease-free planting material from reputable suppliers, inspecting for any signs of prior to planting, and discard any contaminated stock to avoid spreading inoculum into prepared sites.

Management and Treatment

Initial Response Steps

Upon detecting root rot, the first step is to carefully assess the extent of , often indicated by severe symptoms such as widespread or extensive discoloration, to determine if the can be saved. For severely affected plants, immediately excavate the entire and discard the to prevent spread, while isolating or quarantining nearby plants by avoiding shared tools, soil, or water sources. If the infection is limited and the plant appears salvageable, prune away all rotted portions of the roots—typically identified as soft, brown to black tissues—using sterilized tools to avoid introducing further , back to healthy white tissue. Disinfect the tools and any cuts with 70% or a 10% solution between uses to eliminate lingering pathogens. For plants that can be rescued, repot them promptly into a fresh, sterile growing medium, such as a pasteurized potting mix amended with for improved , in a clean pot with adequate drainage holes to promote drying and reduce moisture retention. Avoid reusing the original pot or soil, as they may harbor pathogens; sterilize clay pots with a solution if necessary, but discard plastic ones to eliminate risks.

Control Measures

Control measures for root rot focus on suppressing established infections through targeted chemical, biological, and integrated strategies, tailored to the causal pathogen—such as oomycetes or true fungi. Chemical fungicides are commonly applied as soil drenches to reach root zones effectively. For oomycete pathogens like Phytophthora and Pythium, phosphonates (e.g., fosetyl-Al or potassium phosphite) provide systemic protection by enhancing plant defenses and directly inhibiting pathogen growth, with applications at rates specified on product labels. For fungal pathogens such as Thielaviopsis or Rhizoctonia, thiophanate-methyl is effective, typically applied as a drench at rates such as 20 fluid ounces per 100 gallons of water to suppress spore germination and mycelial growth. Mefenoxam, targeting oomycetes, is used in soil drenches at 0.5–1 fluid ounce per 1,000 square feet, ensuring thorough root coverage while rotating with other groups to prevent resistance. Biological controls introduce antagonistic microbes to outcompete and parasitize root rot pathogens in the rhizosphere. Strains of Trichoderma spp., such as T. harzianum, colonize roots and produce enzymes that degrade fungal cell walls, effectively reducing infections by Rhizoctonia, Fusarium, and Pythium when applied as a soil drench or seed treatment at manufacturer-recommended rates. Bacillus subtilis formulations work similarly by secreting antibiotics and biofilms that inhibit pathogen attachment and spore germination, with studies showing variable suppression of root rot when applied at label rates. These agents are most efficacious under moderate disease pressure and require consistent reapplication every 4–6 weeks. Integrated approaches combine these tools with cultural adjustments for sustainable suppression. Improving soil aeration through core aeration or incorporation of reduces conditions that favor persistence, which can improve the efficacy of and biocontrol efficacy by reducing favorable conditions for pathogens. Efficacy is monitored via regular inspections and symptom tracking, with follow-up applications adjusted based on incidence thresholds (e.g., 10–20% infection). This holistic method minimizes reliance on single tactics and promotes long-term .

Specific Cases

In Hydroponic Systems

Hydroponic systems are particularly susceptible to root rot due to the recirculating nature of nutrient solutions, which facilitate the rapid buildup and dissemination of pathogens like species through waterborne zoospores. These pathogens, commonly Pythium aphanidermatum and Pythium ultimum, proliferate in environments with constant moisture, low dissolved oxygen, and temperatures above 72°F (22°C), conditions often prevalent in closed-loop hydroponic setups. The absence of barriers further exacerbates vulnerability, as contaminated can infect entire systems without natural dilution. In hydroponic environments, root rot symptoms manifest quickly due to the pathogen's efficient water-mediated spread, often leading to soft, honey-brown discoloration of roots within days of . Affected roots develop a slimy coating from growth, which can clog pumps, filters, and irrigation lines, compromising system functionality and accelerating plant stress. Above-ground indicators include , , and yellowing leaves, particularly in crops like , where root vigor declines rapidly, resulting in pale yellow to dark brown root tissues. Management of root rot in hydroponics emphasizes proactive water treatment and environmental controls to mitigate pathogen persistence. UV sterilizers and ozone generators effectively disinfect recirculating solutions by inactivating Pythium zoospores and reducing organic matter that harbors the pathogen. Maintaining dissolved oxygen levels above 8 mg/L through aeration suppresses Pythium survival, as low oxygen favors oomycete proliferation. Periodic system flushes with sanitized water, combined with sanitation of equipment using hydrogen peroxide or chlorine-based solutions, help remove inoculum buildup, though full flushes are less common in continuous recirculating designs.

In Field Crops and Trees

In field crops, species are major contributors to root rot in cereals such as , where they cause discoloration and lesions on and crowns, leading to , premature ripening, and reduced stand density. These infections often manifest as reddish-brown streaks on the lower stems and , exacerbating damage under dry or stressed conditions. In potatoes, species, particularly Phytophthora erythroseptica, induce root rot that extends to lower stems, resulting in , yellowing foliage, and a soft decay resembling blackleg symptoms in severe cases. This pathogen thrives in waterlogged soils, compromising and contributing to plant collapse during the growing season. For trees in orchards and forests, root rot, caused by Armillaria species, poses a significant threat by invading roots and the lower trunk, leading to that disrupts water and nutrient transport. Infected trees exhibit sparse foliage, branch dieback, and basal clusters of honey-colored mushrooms during wet periods, signaling advanced decay and potential tree mortality within years. This disease spreads via root contacts or rhizomorphs, affecting a wide range of species including in forests and trees in orchards, often resulting in widespread stand decline. Disease complexes involving multiple pathogens are particularly problematic in crops like canola, where Fusarium, Rhizoctonia, and Pythium species interact to cause root rot, leading to yield reductions of 10-50% depending on environmental factors and infection severity. These complexes weaken root systems, impair nutrient uptake, and increase susceptibility to secondary stresses, with losses most pronounced in continuous cropping systems. Effective management relies on crop rotation, which disrupts pathogen buildup by introducing non-host crops like cereals or legumes for at least two to three years. General treatments for Fusarium, such as fungicide seed treatments, can provide early-season protection when integrated with rotation.

References

  1. [1]
    Root Rots in the Garden - Wisconsin Horticulture
    Mar 1, 2024 · Root rot is a general term that describes any disease where the causal organism attacks and leads to the deterioration of a plant's root ...Missing: definition | Show results with:definition
  2. [2]
    Root Rot - an overview | ScienceDirect Topics
    ### Summary of Root Rot in Plants
  3. [3]
    Phytophthora Root and Crown Rot - UC IPM
    Symptoms on Roots and Crowns​​ In tomatoes and eggplants, roots develop water-soaked spots that turn brown, and roots may be rotted off. If mushrooms are present ...
  4. [4]
    Phymatotrichum Root Rot - BE BOLD. Shape the Future.
    This publication describes Phymatotricum root rot of plants, including disease symptoms, conditions that favor the disease, and possible control methods.Missing: definition | Show results with:definition
  5. [5]
    Black Root Rot on Ornamental Plants
    This disease causes decay of the root system and leads to yellowing, wilting, and necrosis of foliage. It is widely distributed and has been described on ...Missing: definition | Show results with:definition
  6. [6]
    [PDF] Pythium Root Rot of Herbaceous Plants - Purdue Extension
    This publication describes Pythium root rot, the symptoms of the disease, the disease cycle, and how to effectively manage the problem. The three most commonly ...Missing: review | Show results with:review
  7. [7]
    Understanding Root Rot Disease in Agricultural Crops - MDPI
    Root rot diseases remain a major global threat to the productivity of agricultural crops. They are usually caused by more than one type of pathogen.Missing: definition | Show results with:definition
  8. [8]
    Root rot in medicinal plants: a review of extensive research progress
    Root rot disease is a plant disease caused by various soil-borne pathogens, primarily characterized by the necrosis and decay of plant roots and root tubers ( ...
  9. [9]
    [PDF] Root Rot Diseases in Plants: A Review of Common Causal Agents ...
    Mar 27, 2017 · Root rot pathogens cause some of the most important plant diseases worldwide impacting several crops [1,2]. Root rot.Missing: definition prevalence
  10. [10]
    Major Soilborne Pathogens of Field Processing Tomatoes and ...
    Jan 19, 2023 · Tomato production in southern Italy is significantly affected by corky root rot. ... This disease was found to cause substantial yield loss ...
  11. [11]
    NIFA Funds Battle Against Plant Destroyer Pathogen
    Mar 18, 2022 · One species that causes late blight disease is responsible for more than $6.7 billion in potato and tomato production losses worldwide annually, ...
  12. [12]
    Limited effects of thinning on laminated root rot induced tree ...
    Nov 15, 2024 · The disease has significant impacts on species composition, biodiversity, nutrient cycling, and timber harvest (Boyce and Wagg, 1953, Cook et ...
  13. [13]
    [PDF] Armillaria Root Disease in Conifers of Western North America
    1. Individual tree mortality caused by Armillaria root disease can create habitat for cavity-nesting animals in standing and down trees.
  14. [14]
    Fungal Root Rots and Chemical Fungicide Use - Penn State Extension
    Jul 8, 2025 · Root rots of floricultural and woody ornamental crops are one of the most important causes of crop loss. In addition to killing plants and ...
  15. [15]
    Root Rots on Houseplants - Wisconsin Horticulture
    Mar 1, 2024 · Root rot is a general term that describes any disease where the pathogen (causal organism) causes the deterioration of a plant's root system.Missing: definition | Show results with:definition
  16. [16]
    https://greenhouse.cornell.edu/pests-diseases/disease-factsheets/root-rot-diseases/
  17. [17]
    https://www.canr.msu.edu/news/armillaria_root_rot_in_the_great_lakes_region
  18. [18]
    Root Rot Diseases | Greenhouse Horticulture - Cornell University
    Phytophthora Root and Stem Rot ... Phytophthora may cause root rots, but often it attacks the stem base as well, girdling the vascular system and leading to ...<|control11|><|separator|>
  19. [19]
    Armillaria root rot in the Great Lakes region - MSU Extension
    Apr 17, 2014 · Armillaria root rot affects hundreds of plant species throughout Michigan. Learn more about the biology, symptoms and control of this devastating fungus.Missing: conifer | Show results with:conifer<|control11|><|separator|>
  20. [20]
    Drying Up Root and Crown Rot Pathogens - Clemson HGIC
    Mar 1, 2019 · Prolonged standing water or compacted, water-soaked soils cause oxygen levels in the soil to drop significantly. These soils with little to no ...
  21. [21]
    Assessing and Addressing Soil Compaction in Your Yard
    Certain pathogenic organisms thrive under anaerobic conditions created by compaction and cause plant disease, especially root rot. Methods to Assess Soil ...
  22. [22]
    Phytophthora Root Rot On Woody Ornamentals
    Jun 26, 2025 · Infection can occur over a wide range of temperatures: 15°C (59°F) to 28°C (82°F). 22°C (71°F) is optimum. Soil moisture just below ...
  23. [23]
    Take-All Root Rot of Warm-Season Grasses - CAES Field Report
    Oct 18, 2016 · The disease tends to be more severe in soils with high pH. If soils have a pH higher than 6.5, use sphagnum peat moss (pH 4.4) to lower the soil ...
  24. [24]
    [PDF] Root Rot in Landscape Plants - Purdue Extension
    Figure 6. Black rotted roots and rhizomes are classic symptoms of root rot. Signs of root rot may include fungal structures that are visible to the naked eye. ...
  25. [25]
    Root Rots of Annuals and Perennials
    May 22, 2002 · Roots of a diseased plant appear water-soaked and usually are some shade of brown or black. The dis colored roots are often soft and mushy, ...
  26. [26]
    Phytophthora Root and Crown Rot in the Landscape
    Mar 18, 2021 · Phytophthora species typically cause root rot or crown rot, and symptoms often include loss of older foliage, foliar blight, chlorosis, decline ...
  27. [27]
    Fact Sheet: Root Rot – Database of Apple Diseases - Cornell blogs
    What does Root Rot look like? The first noticeable above-ground symptoms include growth stunting, wilt, off-color foliage and general decline. These symptoms ...
  28. [28]
    Confirming the Diagnoses - OSU Horticulture Department
    Growers can buy and use diagnostic test kits (also called ELISA kits) in the field. Kits all work on the same principle: they detect proteins that Phytophthora ...Missing: techniques | Show results with:techniques
  29. [29]
    Root rots: Can you tell the difference? - MSU Extension
    Mar 7, 2016 · Plant diagnosticians will observe your sample under the microscope and often culture it on media to isolate and identify the pathogen. Growers ...
  30. [30]
    5. Diseases and Disorders | NC State Extension Publications
    Feb 1, 2022 · More commonly, excess soil moisture is a contributing factor to root disease. ... Good soil drainage, proper soil pH, and optimum fertility ...
  31. [31]
    Molecular Methods for Diagnosing Plant Diseases - CSU Extension
    Sep 1, 2023 · Methods like ELISA, PCR, RPA, lateral flow assays, and next-generation sequencing offer faster, more accurate diagnoses compared to traditional ...Missing: rot inspection
  32. [32]
    Diagnosing Plant Problems: Is It Disease or Drought Stress?
    Jul 22, 2025 · Experts share visual cues, root inspection tips, and troubleshooting steps to help growers distinguish between drought stress and disease.Missing: nutrient | Show results with:nutrient
  33. [33]
    Non-Chemical Methods for Controlling Diseases in the Home ...
    Avoid excessive soil moisture. Over-watering enhances seed decay, damping-off, and root rot diseases. Try not to plant in areas having poor drainage or where ...
  34. [34]
    Interior Plant Selection and Care | UA Cooperative Extension
    Using simple moisture meters, available at most garden center and nursery outlets, is a very good way to get a general idea of the moisture level in the center ...Light · Water · Containers
  35. [35]
    Disease Management in the Home Vegetable Garden
    Apr 4, 2009 · Avoid over-watering or planting in poorly drained soils to prevent root diseases and seed decay. Space plants for good air circulation and plant ...
  36. [36]
    Fusarium crown and root rot - University of Minnesota Extension
    Cultural controls · Practice rotation by crop family. · Maintain a soil pH of 6 to 7, as the fungus thrives in low pH soil. · Avoid wounding young transplants ...
  37. [37]
    Phytophthora Resistant Plants for the Landscape
    Oct 15, 2014 · Some good choices include Clethra alnifolia (summersweet), Itea sp (sweetspire), Physocarpus opufoliius (Eastern ninebark), and Leucothoe ...Missing: varieties | Show results with:varieties
  38. [38]
    Understanding Soil pH - Penn State Extension
    Jun 28, 2023 · Liming an acid soil creates a favorable soil environment where plants can thrive. Most plants do well when the soil pH is between 6.2 and 6.8.
  39. [39]
    Best Management Practices in the Landscape - CAES Field Report
    Raise the planting bed approximately 10 to 15 inches above grade to assure good drainage and improve the visual appeal of the planting. Raised beds assure good ...Missing: enhancements | Show results with:enhancements
  40. [40]
    Soil Drainage - CSU Extension - Colorado State University
    Oct 1, 2015 · Many plants are prone to root rot in wet soils. Prolonged ... French Drains. In some situations, a French drain facilitates water drainage.
  41. [41]
    How to Clean and Disinfect Plant Containers | Yard and Garden
    Soak the container in a solution containing one part household bleach to nine parts water for a minimum of 10 minutes and rinse. Prepare the solution by adding ...Missing: prevention | Show results with:prevention
  42. [42]
    [PDF] Sanitation Practices for Disease Management in Commercial ...
    ▫ Avoid introducing diseased plants into fields; never purchase or accept diseased plant material. Diseases cannot be cured, even using fungicides. ▫ Discard ...
  43. [43]
    Houseplant Diseases & Disorders - HGIC@clemson.edu
    Feb 28, 2025 · Overwatering will cause the roots to die from a lack of oxygen. Provide drainage, and reduce watering. A pot-bound plant has filled its pot ...Missing: factors | Show results with:factors
  44. [44]
    Understanding the Phosphonate Products - Penn State Extension
    Oct 1, 2025 · Because of this unique property, phosphonates are viewed as excellent fungicides for controlling root rot diseases such as Pythium root rot ...
  45. [45]
    Black Root Rot / Floriculture and Ornamental Nurseries / Agriculture
    The benzimidazole fungicides such as thiophanate-methyl are very active against the fungus and are used as soil treatments to control it. To treat container ...
  46. [46]
    Phytophthora Root Rot on Southern Highbush Blueberry in Florida
    Feb 1, 2024 · The second group of fungicides labeled for PRR management in blueberry is the phosphonates (FRAC Group P07). Phosphonate products may contain ...
  47. [47]
    [PDF] Black Root Rot of Greenhouse Ornamentals
    Soil drenches of fungicides containing the active ingredients thiophanate-methyl, triflumizole or propiconazole may also be effective. These active ingredients ...
  48. [48]
    [PDF] Floral Crops: Diseases - VTechWorks
    Subdue Maxx 0.5-1.0 fl oz; mefenoxam Drench at seeding (soil 2-3 inches deep). Mix Subdue with 100 gal of water and apply 1 pt of solution/sq ft. Transplanting ...
  49. [49]
    Trichoderma for Control of Soil Pathogens
    Trichoderma kills several major root rot fungi: Pythium, Rhizoctonia, and Fusarium. ... T-22 is effective against root rots, but it does not control seed rot. For ...
  50. [50]
    "Efficacy of biocontrol agents in planting mixes to colonize plants roo ...
    All biological control agents, Trichoderma harzianum, Bacillus subtilis, G. intraradices, Gliocladium virens, and Streptomyces griseovirdis reduced crown rot of ...
  51. [51]
    [PDF] Biological Fungicides - Integrated Pest Management
    Bacillus subtilis works in a number of ways producing antibiotics, displacing the pathogen by inhibiting spore germination and interfering with the attachment ...
  52. [52]
    Phytophthora Dieback and Root Rot - Integrated Pest Management
    Also, there are cultivars and hybrids of rhododendron and azalea that are resistant to Phytophthora root rot that can be planted to reduce the risk of infection ...
  53. [53]
    Developing an Integrated Turfgrass Pest Management Program
    Jun 15, 2022 · IPM is a pest management system that is gaining popularity and acceptance in the turfgrass industry. It incorporates all suitable control techniques.Missing: rot efficacy
  54. [54]
    Prevention and Management of Soilborne Diseases of Ornamental ...
    Jul 18, 2022 · This publication details strategies for preventing and managing soilborne diseases in greenhouse crop production using soilless media.Introduction · Sanitation · Cultural Practices
  55. [55]
    [PDF] Root disease management in hydroponic systems - e-GRO
    Mar 6, 2022 · The key to keeping root disease low is to reduce inoculum build-up within the system. Discard infected plants as soon as any symptoms are seen. ...
  56. [56]
    Root Disease Problems & Management in Hydroponic Systems
    The most common root disease in hydroponic systems is root rot caused by the fungal-like organism, Pythium. Other fungal diseases that are occasional problems ...
  57. [57]
    Managing root disease in hydroponic lettuce - Publication : USDA ARS
    Jul 29, 2025 · This guide provides growers with tools to identify Pythium root rot in their hydroponic systems and a toolbox to manage this disease.Missing: causes symptoms
  58. [58]
    Pythium
    ### Summary: Pythium Root Rot in Hydroponics
  59. [59]
    [PDF] E2876 Fusarium root rot - Michigan State University
    Symptoms do not appear until two or three weeks after planting. The first symptoms are narrow, long, red to brown lesions on the stems; lengthwise cracks often ...
  60. [60]
    [PDF] Common Root Rot and Fusarium Foot Rot of Wheat (G1998)
    A diagnostic symptom of Fusarium foot rot is a cottony pink mycelium that may appear on affected stem bases. If the disease is severe, plants may mature early,.
  61. [61]
    Pink Rot / Potato / Agriculture - UC IPM
    With exposure to air, the surface of the decay turns a salmon pink color, which later turns to brown and then finally black. Roots and lower stems may also rot, ...
  62. [62]
    Wet conditions encourage soil-borne diseases of potatoes
    May 18, 2006 · The roots lose integrity and adhesion to the soil. To check for lower stem rot or root rot, gently but firmly pull the plant upwards, if the ...Missing: yield loss
  63. [63]
    [PDF] Armillaria Root Disease - USDA Forest Service
    Armillaria root disease is caused by fungi, found worldwide, that live on roots and stems, causing mortality, wood decay, and growth reduction.
  64. [64]
    Armillaria root rot - UC IPM
    The oak root fungus attacks and kills the vascular cambium (the tissue that generates bark and wood) in woody roots, then spreads laterally to the main stem, ...Missing: process | Show results with:process
  65. [65]
    Characterization of the Virulence and Yield Impact of Fusarium ...
    Aug 22, 2023 · Root rot is commonly associated with seed decay, damping off, and the decomposition of infected root tissues, resulting in substantial yield ...
  66. [66]
    Diversity and Pathogenicity of Fusarium Root Rot Fungi from Canola ...
    Root rot is a widely distributed disease causing significant yield losses in many agriculturally important crops worldwide [1]. The pathogens responsible ...
  67. [67]
    Canola Production Field Guide | NDSU Agriculture
    Crop rotation – Most diseases in canola are more likely to occur, and more likely to be severe, if short crop rotations are used. Lengthening crop rotation ...
  68. [68]
    Wheat – Fungicide Seed Treatments (04/28/22) | NDSU Agriculture
    Apr 28, 2022 · Fungicide seed treatments are labeled in wheat to manage seed-borne diseases, seedling blights, and early-season root rot.