Conidial water affinity is an important characteristic for thermotolerance in entomopathogenic fungi

The interspecific thermotolerance of several species of entomopathogenic fungi was evaluated based on the conidial water affinity. The species were divided between hydrophilic and hydrophobic conidia. The species with hydrophobic conidia were Beauveria bassiana (ARSEF 252), Metarhizium brunneum (ARSEF 1187), Metarhizium robertsii (ARSEF 2575), Isaria fumosorosea (ARSEF 3889) and Metarhizium anisopliae s.l. (ARSEF 5749). The species with hydrophilic conidia were Tolypocladium cylindrosporum (ARSEF 3392), Tolypocladium inflatum (ARSEF 4877), Simplicillium lanosoniveum (ARSEF 6430), Lecanicillium aphanocladii (ARSEF 6433), S. lanosoniveum (ARSEF 6651), Aschersonia placenta (ARSEF 7637) and Aschersonia aleyrodis (ARSEF 10276). The conidial surface tension of each isolate was also studied. Conidial suspensions were exposed to 38, 41 or 45 °C. After exposure, the suspensions were inoculated on media and conidial germination was evaluated. Considerable differences in thermotolerance were found among the 12 entomopathogenic fungal species. Species with hydrophobic conidia were generally more thermotolerant than species with hydrophilic conidia. All isolates with hydrophobic conidia showed higher conidial surface tension than the isolates with hydrophilic conidia.     

A new non-hydrophobic cell wall protein (CWP10) of Metarhizium anisopliae enhances conidial hydrophobicity when expressed in Beauveria bassiana

A cell wall protein, CWP10, resolved from the conidial formic acid extract of a Metarhizium anisopliae isolate, was characterized as a new 9.9-kDa protein with a 32-aa signal peptide with a central hydrophobic region (ca. 10 residues) at its N-terminus. This protein was proven neither to be hydrophobic nor glycosylated and encoded by a 363-bp, single-copy gene with three introns. CWP10 was existent in the conidial extracts of seven of 18 tested M. anisopliae isolates and much more abundant (immunogold-labeled) on conidial walls than in cytoplasm. Integrating the gene into a CWP10-absent strain of Beauveria bassiana led to excellent expression of CWP10 in aerial conidia, increasing net conidial hydrophobicity by 10.8% or adhesion to hydrophobic Teflon by 1.3-fold. However, the expressed protein had no effect on conidial tolerance to thermal and ultraviolet stresses. This is the first report on a non-hydrophobic cell-wall protein enhancing conidial hydrophobicity and adhesion of the fungal species.     

Influence of growth and environmental conditions on cell surface hydrophobicity of Pseudomonas fluorescens in non-specific adhesion

The relative cell surface hydrophobicity (CSH) of 18 soil isolates of Pseudomonas fluorescens, determined by phase exclusion, hydrophobic interaction chromatography (HIC), electrostatic interaction chromatography (ESIC), and contact angle, revealed large degrees of variability. Variation in the adhesion efficiency to Macrophomina phaseolina of the hyphae/sclerotia of these isolates was also examined. Two such isolates with maximum (32.8%; isolate 12-94) and minimum (12%; isolate 30-94) CSH were selected for further study. Early- to mid-log exponential cells of these isolates were more hydrophobic than those in stationary phase, and the CSH of these isolates was also influenced by fluctuations in temperatures and pH. Isolate 12-94 exhibited high CSH (32.3%) at 30 degrees C, compared to lower values (28-24%) in the higher temperature range (35-40 degrees C). Increasing concentrations of either Zn2+, Fe3+, K+, and Mg2+ in the growth medium were associated with the increased CSH. Trypsin, pepsin, and proteinase K (75 to 150 micrograms.mL-1) reduced the CSH of isolate 12-94 cells. CSH was reduced, following exposure to DTT, SDS, Triton X-100, or Tween 80. Prolonged exposure of cells to starvation (60 days) also caused a significant decline in CSH. Several protein bands (18, 21, 23, 26 kDa) of the outer cell membrane were absent in 60-day starved cells compared to unstarved cells. In conclusion, our findings demonstrate that CSH of P. fluorescens isolates may contribute to nonspecific attachment/adhesion onto M. phaseolina hyphae/sclerotia, and the efficiency of adhesion is regulated by growth and other environmental conditions.     

Compositional factors influencing cell surface hydrophobicity ofPasteurella multocida variants

The influence of macromolecules other than lipopolysaccharide on the hydrophobic properties ofPasteurella multocida was investigated by assessing cell surface hydrophobicity (CSH) after experimentally modifying surfaces of various strains. CSH of hydrophobic variants was enhanced by growth on blood-supplemented medium and mechanical shearing, whereas chloramphenicol, oxytetracycline, trypsin, and pronase E treatments decreased CSH. No such modifications were observed for hydrophilic strains. Microscopic observations revealed hydrophilic strains to be heavily encapsulated in contrast to hydrophobic strains. Repeated subculturing reduced encapsulation with a concomitant increase in CSH for one hydrophilic strain while exerting no changes in the other hydrophilic strain examined. Hyaluronidase removal of capsular material from a serotype A strain resulted in increased CSH; subsequent exposure to pronase E resulted in partial restoration of hydrophilicity. These data suggest the encapsulation of hydrophilicP. multocida strains masks a relatively hydrophobic surface that is conferred, at least in part, by the presence of one or more surface-exposed proteins common to both hydrophilic and hydrophobic variants.     

Using particle size analysis to determine the hydrophobicity and suspension of fungal conidia with particular relevance to formulation of biopesticide

Fungal formulations are vital for effective biopesticide development. Good formulations help to optimise field efficacy, while poor formulations result in product failure. This study aimed to produce a hydrophobicity test that would be appropriate for fungal conidia produced to a commercial quality and determine relative hydrophobicity of fungi from four different genera by using laser diffraction. A particle size analyser was used to determine the hydrophobicity of: three Metarhizium acridum samples, M. anisopliae, Beauveria bassiana, Trichoderma stromaticum, T. harzianum, T. viride and Alternaria eichhorniae conidia by suspending the conidia in three different liquids: Shellsol T (a mineral oil), water and 0.05 % Tween 80. Hydrophobicity was determined by the size of the particles formed in each of the liquids. All the Metarhizium samples were the most hydrophobic followed by B. bassiana and A. eichhorniae. The Trichoderma samples were the least hydrophobic. As a comparison, a phase exclusion assay and a salt-mediated aggregation and sedimentation (SAS) test were performed. It was not possible to get a reliable reading for the B. bassiana, A. eichhorniae and T. viride samples using the phase exclusion assay. The addition of salt in the SAS test did not affect the rate of sedimentation. It was hypothesised that conidia size affected the results of the SAS test that made A. eichhorniae the most hydrophobic conidia. Particle size analysis (PSA) was a more accurate test for comparing fungi from difference genera compared to the SAS test and phase exclusion assay. PSA was also used to test three emulsions and demonstrated that different formulations had an effect on particle size.     

Cell surface hydrophobicity of Candida albicans isolated from elder patients undergoing denture‐related candidosis

Background: The virulence potential of Candida albicans strains enrolled in denture‐related candidosis still remains uncertain. Candida albicans cells with higher cell surface hydrophobicity (CSH) rates, so‐called hydrophobic, present higher adhesion success in different host tissues than cells with lower rates, or even hydrophilic. Objective: The proposition of this study was to evaluate the differences in the CSH of strains isolated from denture users with and without denture‐related candidosis. Material and methods: The strains were obtained from two paired groups of patients living a same retirement house. Fungal cells were submitted to CSH evaluation by the hydrocarbon partition test using xylene. Results: The measures revealed that the yeasts from patients with candidosis had CSH values ranging from 4.52% to 12.24%, with an average of 8.22 ± 2.92%. In the countergroup, the CSH ranged from 3.86% to 14.36%, with an average of 8.38 ± 3.76%. The difference between the groups were considered not relevant (p = 0.997). Conclusion: The results let to the inference that natural populations of C. albicans from patients with and without clinical manifestation denture‐related candidosis do not differ one from the other regarding to CSH.     

Relationship Between Expression of Cell Surface Hydrophobicity Protein 1 (CSH1p) and Surface Hydrophobicity Properties of <Emphasis Type="Italic">Candida dubliniensis</Emphasis>

Candida dubliniensis and Candida albicans cause most of the oral candidiasis infections in AIDS patients. Unlike C. albicans, which variably expresses cell surface hydrophobicity (CSH) depending on environmental conditions, C. dubliniensis is hydrophobic under all environmental conditions. C. dubliniensis produces CdCSH1p, a protein related to CaCSH1p that contributes to CSH expression of C. albicans. We investigated whether environmental conditions affect CdCSH1p expression, CSH avidity, and adhesion to fibronectin (Fn). C. dubliniensis CD36 was grown at 23°C and 37°C in four different media. CdCSH1p expression was affected by growth temperature, with cells grown at 37°C expressing the protein, but cells grown at 23°C did not. Hydrophobic avidity for two media was higher in cells grown at 37°C than at 23°C. Cells grown at 23°C were generally less adherent than 37°C-grown cells to Fn. The results suggest CdCSH1p but not hydrophobic avidity may have a role in adhesion of C. dubliniensis to Fn.     

Temperature response,pathogenicity, seed infection and mutant evaluation against Macrophomina phaseolina causing charcoal rot disease of sesame

Charcoal rot caused by Macrophomina phaseolina is a serious disease of sesame in Pakistan. M. phaseolina sesame isolate was subjected to growth rate test at 10, 15, 20, 25, 30, 35 and 40°C. The optimum temperature for fungal growth and microsclerotia production was found to be 30–35°C. Gray to black, radial fungal colonies with intermediate mycelial growth and jet black oval to round microsclerotia were observed at this optimum range. M. phaseolina was found to be pathogenic against all the 18 tested plant species and this pathogenicity proved its necrophytic behavior. Seed infection efficiency of M. phaseolina was 100% with significant reduction in seed index. For two consecutive years 21 mutants/varieties were screened in the field for their reactions to charcoal rot disease. During 2007 three mutants NS11704S1, NS11304S2 and NS26004 were ranked as resistant while others were moderately resistant to highly susceptible. During 2008 all mutants showed a susceptible to highly susceptible reaction with variable disease reactions. All over screening results revealed that four mutants viz, NS13P1, NS163-1, NS270P1 and NS26004 showed about 50% stand with consistent performance during both years under optimum disease conditions and can be used to manage the disease following the disease management strategies, however in the future improvement for high seed yield along with resistance is a prerequisite for sustainable high production.     

Release of the extracellular matrix from conidia ofBlumeria graminis in relation to germination

The release of extracellular matrix (ECM) and the emergence of germ tubes from conidia ofBlumeria graminis were studied by light microscopy and micromanipulation. More prompt and frequent ECM release was confirmed on an artificial hydrophobic substratum than on an artificial hydrophilic substratum. Conidia initially incubated on the hydrophilic substratum were transferred by micromanipulation to either the hydrophobic or the hydrophilic substrata. Immediately after transfer onto the hydrophobic substratum, 75% of conidia released ECM, whereas only 16% did so upon transfer to the hydrophilic substratum. Conidia transferred onto the hydrophobic substratum produced a primary germ tube (PGT) more promptly and frequently than those transferred to the hydrophilic substratum. Thus, conidia recognize and respond to substratum hydrophobicity perhaps immediately after contact. When inoculated onto either isolated barley cuticle or the hydrophobic artificial substratum, 2/3 of the conidia produced a PGT from their polar regions. By contrast, on the hydrophilic substratum 2/3 of conidia did so from the side region. These results show that substratum hydrophobicity affects the location of PGT emergence from conidia. Furthermore, the study indicates that very rapid recognition of surface hydrophobicity by conidia promotes ECM release and this in turn may influence the location of PGT emergence.     

Adhesion of the Entomopathogenic Fungus Beauveria (Cordyceps) bassiana to Substrata

The entomopathogenic fungus Beauveria bassiana produces at least three distinct single-cell propagules, aerial conidia, vegetative cells termed blastospores, and submerged conidia, which can be isolated from agar plates, from rich broth liquid cultures, and under nutrient limitation conditions in submerged cultures, respectively. Fluorescently labeled fungal cells were used to quantify the kinetics of adhesion of these cell types to surfaces having various hydrophobic or hydrophilic properties. Aerial conidia adhered poorly to weakly polar surfaces and rapidly to both hydrophobic and hydrophilic surfaces but could be readily washed off the latter surfaces. In contrast, blastospores bound poorly to hydrophobic surfaces, forming small aggregates, bound rapidly to hydrophilic surfaces, and required a longer incubation time to bind to weakly polar surfaces than to hydrophilic surfaces. Submerged conidia displayed the broadest binding specificity, adhering to hydrophobic, weakly polar, and hydrophilic surfaces. The adhesion of the B. bassiana cell types also differed in sensitivity to glycosidase and protease treatments, pH, and addition of various carbohydrate competitors and detergents. The outer cell wall layer of aerial conidia contained sodium dodecyl sulfate-insoluble, trifluoroacetic acid-soluble proteins (presumably hydrophobins) that were not present on either blastospores or submerged conidia. The variations in the cell surface properties leading to the different adhesion qualities of B. bassiana aerial conidia, blastospores, and submerged conidia could lead to rational design decisions for improving the efficacy and possibly the specificity of entomopathogenic fungi for host targets.     

Assessment of alcohol percentage test for fungal surface hydrophobicity measurement

Aim: To determine whether assessing the penetration of solutions with different concentrations of ethanol (alcohol percentage test: APT) on fungal surfaces is effective in characterization of hydrophobicity on fungal surfaces. Methods and Results: APT and contact angle (CA) measurements were conducted on nine hydrophobic and two hydrophilic fungal strains from the phyla of Ascomycota, Basidiomycota and Zygomycota. There was a strong positive correlation (R² = 0·95) between the APT and CA measurements from eight of the nine hydrophobic stains (four pathogenic and mycotoxigenic Fusarium taxa, one melanosporaceous biotrophic taxon, Alternaria sp, Penicillium aurantiogriseum and Cladosporium cladosporioides). Hydrophilic control strains, Mortierella hyalina and Laccaria laccata, had CAs <90° and no measurable degree of hydrophobicity using the APT method. Conclusions: The APT method was effective in measuring the degree of hydrophobicity and can be conducted on different zones of fungal growth. Significance and Impact of the Study: Characterization of fungal surface hydrophobicity is important for understanding of its particular role and function in fungal morphogenesis and pathogenesis. APT is a simple method that can be utilized for fungal hydrophobicity measurements when CA cannot be measured because of obscured view from aerial mycelia growth.     

Surface Hydrophobicity of Culture and Water Biofilm of <Emphasis Type="Italic">Penicillium</Emphasis> spp.

Fungal surface hydrophobicity is involved in several functions in fungal growth and development. Water contact angles measurement has been used as a direct and simple approach for its characterisation in solid cultures. Microsphere adhesion assay is said to be the best method to assess cell hydrophobicity of filamentous fungi. This study aimed to apply these two methods to study hydrophobicity of Penicillium expansum and Penicillium brevicompactum grown as mycelial mats in solid culture, liquid culture and water biofilms. As result, both species in solid cultures were classified as hydrophobic with contact angles ≥90o, but in liquid cultures and water biofilms showed different levels of hydrophobicity when microsphere adhesion assay was applied. In addition, was found that biofilms have specific hydrophobic hyphae which may be involved in fungal ecological functions.     

Detection of double stranded RNA in phytopathogenic <Emphasis Type="Italic">Macrophomina phaseolina</Emphasis> causing charcoal rot in <Emphasis Type="Italic">Cyamopsis tetragonoloba</Emphasis>

One hundred one isolates of Macrophomina phaseolina from various hosts and eco-geographical locations were employed for elucidating relationships among genetic diversity and virulence. Highly pathogenic, moderately pathogenic, and hypovirulent cluster bean specific isolates were identified. In order to correlate respective phenotypes of plant pathogenic fungus multiple and complex patterns of dsRNA elements were analyzed. Double-stranded ribonucleic acids (dsRNA) are ubiquitous in all major groups and most of them have vast potential as biological control agents for fungi. Rate of virulence and its further association could ascertain by host plant and their fungal genotypes. Variability of the fungal genotypes decides the link between the complexity of dsRNA with different variants and the change in virulence pattern. Double-stranded RNA was identified in approximately 21.7% of M. phaseolina isolates from charcoal rot infected cluster bean varieties. After recurrent laboratory transfer on culture media, the preponderance of the isolates harboring dsRNAs developed degenerate culture phenotypes and showed reduced virulence (hypovirulence) to cluster bean. Macrophomina has successfully showed diversified and reproducible banding profile in dsRNA containing/free isolates. This is the first report of hypovirulence and detection of dsRNA in Macrophomina phaseolina isolates of cluster bean origin.     

Genetical and biological control of cotton ashy stem caused by Macrophomina phaseolina in outdoor pot experiment

Two outdoor pot experiments were carried out to evaluate the reaction of 11 commercial Egyptian cotton cultivars Macrophomina phaseolina, the incitant of ashy stem in cotton and to evaluate the antagonistic ability of 27 isolates of Trichoderma sp. against pathogen cotton cultivars Giza 85, Giza 87, Giza 89 and Giza 90 were resistant to M. phaseolina because both survival and plant height of these cultivars was not affected when the soil was infested with the pathogen. None of the cultivars were found to be immune to highly pathogenic of M. phaseolina isolate. Of the 27 isolate’s of Trichoderma that were evaluated, the best antagonistic performance was given by isolates nos. 2, 10, and 16 were promising for commercialization because they significantly increased survival and improved plant height and dry weight of the surviving cotton seedlings.     

Comparative hydrocarbon utilization by hydrophobic and hydrophilic variants of Pseudomonas aeruginosa

Aims: To investigate hydrocarbon degradation by hydrophobic, hydrophilic and parental strains of Pseudomonas aeruginosa. Methods and Results: Partitioning of hydrocarbon‐degrading P. aeruginosa strain in a solvent/aqueous system yielded hydrophobic and hydrophilic fractions. Exhaustive partitioning of aqueous‐phase cells yielded the hydrophilic variants (L), while sequential fractionation of the hydrophobic phase cells yielded successive fractions exhibiting increasing cell‐surface hydrophobicity (CSH). In hydrocarbon adherence assays (bacterial attachment to hydrocarbon), L had a value of 20%, which increased from 61·7% in first hydrophobic fraction (H₁) to 72·2% in the third (H₃). Crude oil degradation by L was 70%, but increased from 82% in H₁ to 93% in H₃. L variant produced most exopolysaccharides and reduced surface tension from about 73 to 49 mN m^?1. Rhamnolipid production was highest in L, but was not detected in all crude oil cultures. Conclusions: Hydrophobic subpopulations of hydrocarbon‐degrading P. aeruginosa exhibited greater hydrocarbon‐utilizing ability than hydrophilic ones, or the parental strain. Significance and Impact of the Study: Results demonstrate that a population of P. aeruginosa consists of cells with different CSH which affect hydrocarbon utilization. This potentially provides the population with the capacity to utilize different hydrophobic substrates found in petroleum. Judicious selection of such hydrophobic subpopulations can enhance hydrocarbon pollution bioremediation.     

Aspergillus fumigatus adhesion factors in dormant conidia revealed through comparative phenotypic and transcriptomic analyses

Aspergillus fumigatus is an important fungal pathogen of humans. Inhaled conidia of A. fumigatus adhere to pulmonary epithelial cells, causing opportunistic infection. However, little is known about the molecular mechanism of the adherence of resting conidia. Fungal molecules adhesive to host cells are presumed to be displayed on the conidial surface during conidial formation as a result of changes in gene expression. Therefore, we exhaustively searched for adhesion molecules by comparing the phenotypes and the gene expression profiles of A. fumigatus strains that have conidia showing either high or low adherence to human pulmonary A549 cells. Morphological observation suggested that strains that produce conidia of reduced size, hydrophobicity, or number show decreased adherence to A549 cells. K‐means cluster analyses of gene expression revealed 31 genes that were differentially expressed in the high‐adherence strains during conidial formation. We knocked out three of these genes and showed that the conidia of AFUA_4G01030 (encoding a hypothetical protein) and AFUA_4G08805 (encoding a haemolysin‐like protein) knockout strains had significantly reduced adherence to host cells. Furthermore, the conidia of these knockout strains had lower hydrophobicity and fewer surface spikes compared to the control strain. We suggest that the selectively expressed gene products, including those we identified experimentally, have composite synergistic roles in the adhesion of conidia to pulmonary epithelial cells.     

Detection,identification and morphological characteristic of Macrophomina phaseolina: the charcoal rot disease pathogens isolated from infected plants in Northern Jordan

This is the first report about charcoal rot disease in Jordan. Twenty-five Macrophomina phaseolina isolates were collected from infected plants showing typical symptoms of charcoal rot disease. All of the 25 M. phaseolina isolates were pathogenic to cucumber plants under green house effect. The amplification of the isolated DNA from the 25 pathogenic fungal cultures using ITS specific primers (ITS 1?+?ITS 4) showed a single band of 580?bp. There was a significant variation of their mycelial linear growth rate on PDA medium. The 25 M. phaseolina isolates showed a wide heterogeneity in their mycelium colour, microsclerotia distribution, pycnidia formation and chlorate phenotypes. Based on the morphological characterisation, the 25 isolates were grouped into seven different groups as indicated in a dendrogram of their morphological variation. The overall means similarity matrix of the 25 M. phaseolina recovered isolates were 0.58. The means of similarity matrix of the 25 M. phaseolina was in between 0.83 and 0.14. The similarity coefficient between the 25 isolates varies between 0.27 and 1.0.     

Hydrophobicity of bacteria Zymomonas mobilis under varied environmental conditions

Changes in the cell surface hydrophobicity (CSH) of bacteria Zymomonas mobilis 113S were examined in response to varied environmental conditions (temperature and phase of growth, concentration or type of carbon source, the presence of amphiphilic compounds). The values of CSH were elevated with a decreased growth rate over the time of cultivation up to 20–22% at the stationary phase. CSH values increased proportionally with the growth of cultivation temperature and concentration of carbon source (glucose or sucrose) or amphiphilic compound (aliphatic alcohols, Tween80) in the medium. Replacement of sucrose by glucose and the presence of Tween20 in the growth medium resulted in reduced values of CSH. An inverse relationship was detected between the number of attached cells to the hydrophilic glass surfaces and the CSH values of Z. mobilis whereas direct linear relationship was observed for hydrophobic surfaces. Permeation rates of the fluorescent probe (NPN) into the cells were directly proportional to the concentration of extracellular protein in the medium and to the values of CSH indicating the impaired barrier function for more hydrophobic cells. The multiple correlation between the CSH values and absorption indices of FT-IR spectra at the fingerprint region (866–1088 cm⁻¹) suggests the possible contribution of carbohydrates and/or lipopolysaccharides in observed changes of Z. mobilis hydrophobicity.     

Macrophomina phaseolina – Meloidogyne javanica disease complex in balsam (Impatiens balsamina): a new report

Balsam seedlings were inoculated with root-knot nematode Meloidogyne javanica Race-2 and Macrophomina phaseolina either individually or concomitantly, as well as sequentially with an interval of 15?days between the nematode or fungal inoculations to determine whether the interaction was concomitant or sequential. The greater reduction in plant growth characters was observed in the plants inoculated with M. javanica and M. phaseolina, either concomitantly or sequentially as compared to their individual inoculation. However, the highest reduction in plant growth characters were recorded in the plants inoculated with M. javanica Race-2 15?days prior to M. phaseolina followed by concomitant-inoculated M. javanica Race-2 and M. phaseolina, and M. phaseolina 15?days prior to M. javanica. The number of galls/root system and the reproduction factor of the root-knot nematode was reduced in the presence of root-rot fungus. The intensity of root-rot caused by M. phaseolina increased in the presence of root-knot nematode M. javanica as compared to when M. phaseolina was inoculated individually. Moreover, stem and collar-rot symptoms caused by M. phaseolina appeared only in the presence of root-knot nematode.     

Induction of β-1,3-glucanase and chitinase in Vigna aconitifolia inoculated with Macrophomina phaseolina

Pathogenesis-related (PR) proteins are induced in response to pathogen attack. In the present study, the induction of PR proteins in response to the fungal pathogen Macrophomina phaseolina was investigated in 15-day- and 1-month-old plants of Vigna aconitifolia with resistant and susceptible cultivars. Inoculation of the fungal pathogen resulted in the enzyme activity gradually increased throughout the experimental period of 168 h compared to control. However, the activation of β-1,3-glucanase and chitinase was more rapid and to a greater extent in the resistant FMM-96 cultivar as compared to susceptible RM0-40 and CZM-3 cultivars. Furthermore, the western blot analysis revealed the presence of 33- and 30-kDa bands of β-1,3-glucanase and chitinase in induced moth bean plants, respectively. The possible implications of these findings as part of the general defense response of moth bean plants against the fungal pathogen (M. phaseolina) have been discussed.