Streptomyces alni as a biocontrol agent to root-rot of grapevine and increasing their efficiency by biofertilisers inocula

Root-rotted samples of grapevine cv. superior were collected from Nobaria province, Beheira Governorate, Egypt. Fusarium oxysporum Schlech. was the most fungal causing root-rot syndrome of grapevine and directly affected the yield productivity. Seven isolates of Streptomyces were isolated from grapevine rhizospheric soil and screened for antagonistic activities against F. oxysporum on dual culture plate. All isolates showed antifungal activity, but isolate No. 1 exhibited the highest activity. It was identified as Streptomyces alni according to morphological, cultural, physiological and biochemical studies. The properties of the antagonism were revealed by scanning electron microscopy (SEM) examination of F. oxysporum and S. alni on PDA medium. The forms of antagonism found in this study according to the interaction between the S. alni and the pathogen indicated a hyperparasite, including inhibition of fungal growth and colonisation of S. alni over F. oxysporum hyphae. Also, malformation and lysis of F. oxysporum hyphae and conidiophores were observed. Conidia and normal branches of fungal hyphae were absent. Greenhouse and field studies were performed to evaluate the ability of S. alni and some commercial biofertilisers incorporated into the soil for root-rot control. Pot trails indicated that antagonistic S. alni isolate and biofertilisers i.e. blue green algae, phosphoren and rhizobacterin reduced the root-rot incidence of grapevine plants Cv. superior. Soil treatment before sowing with 50 ml of S. alni suspension (1 × 10⁸ spore/ml) + 50 g of rhizobacterin for each pot was the best and significant treatment reduced root-rot of grapevine plants. Also, the total count of F. oxysporum in rhizosphere soil of grapevine treated plants was reduced compared with control. Under field conditions, drenching soil of diseased grape trees with a spore suspension of S. alni (1 × 10⁸ spore/ml) 200 ml/tree + 250 g/tree of rhizobacterien caused a significant reduction in root rot of treated grapevine trees as well as high fruit yield/tree when compared with other treatments. The obtained results suggest that S. alni could be used successfully in combination with biofertilisers, as environmentally safe, for controlling root-rot of grapevine and other soil-borne plant pathogens especially with organic farming systems.     

Effect of combination of bio-agents and mineral nutrients for the management of alfalfa wilt pathogen Fusarium oxysporum f. sp. medicaginis

Abstract

Biological and nutrient management of soil borne disease is increasingly gaining stature as a possible practical and safe approach. Inhibitory effects of fungal and bacterial antagonists were tested under in vitro conditions against the wilt pathogen of alfalfa Fusarium oxysporum f. sp. medicaginis. Trichoderma harzianum and Pseudomonas fluorescens (PI 5) were found to be effective against the alfalfa wilt pathogen. Manganese sulphate at 500 and 750 ppm inhibited the mycelial growth of F. oxysporumf. sp. medicaginis under in vitro conditions. In pot culture studies, manganese sulphate at 12.5 mg/kg reduced the wilt incidence (23.33%). Combined application of manganese sulphate 12.5 mg/kg + T. harzianum 1.25 mg/kg of soil significantly reduced the wilt incidence accompanied by improved plant growth and yield in pot culture. The mixture of manganese sulphate (25 kg/ha) + T. harzianum (2.5 kg/ha) significantly reduced the wilt incidence when applied as a basal dose in the field conditions. The average mean of disease reduction was 62.42% over control.     

Natural mycosis of mango leafhoppers (Cicadellidae: Hemiptera) by Fusarium sp.

Mango leafhoppers that feed on inflorescences and young shoots of mango (Mangifera indica L.) were found mycotized under natural conditions in Bangalore, India. Isolation and characterisation of the etiological agents by sequencing of the Translation Elongation Factor-1α gene, revealed 99% identity with the plant pathogenic fungus Fusarium proliferatum. This is an early report on the Fusarium associated entomopathogenicity in different mango leafhopper species.     

Antagonistic activity and hyphal interactions of Trichoderma spp. against Fusarium proliferatum and F. oxysporum in vitro

Trichoderma is a well-known antagonist against soilborne plant pathogens. However, the species and even various isolates have different biocontrol potential. To evaluate the antagonistic activities of Trichoderma harzianum, T. harzianum strain T100 (T100), T. viride and T. haematum against Fusarium oxysporum and F. proliferatum, we used dual culture and productions of volatile and non-volatile metabolites in three different phases in vitro. An analysis of the data in dual culture tests represented T. viride, T. haematum and T100 as effective antagonists of Fusarium while T100 was the only fungus being able to lyse the confronting mycelia. Similar results were obtained in the volatile metabolites tests also. In contrast with the two previous tests, the non-volatile metabolites produced by T. harzianum inhibited Fusarium mycelial growth the most, and T100 acted moderately. It was also clearly showed that the antagonistic effect of Trichoderma spp. was more on F. proliferatum than on F. oxysporum. Finally, because Trichoderma spp. was most effective in the second phase, we recommend to use T100 against F. proliferatum at the initial stages of infection as its mycoparasitism on F. oxysporum was observed microscopically through forming apressoria structures without any coiling around the pathogen.     

Fusarium cerealis Associated with Barley Seeds in Argentina

Fusarium head blight is a fungal disease caused by a complex of Fusarium species on cereals, such as barley and wheat. It has economic impacts due to yield reductions and mycotoxin contamination. As barley production has increased considerably in the last 5 years in Argentina, a survey was conducted for identifying Fusarium species associated with barley grains. Fusarium cerealis was isolated and identified based on morphological and molecular analysis. The potential production of nivalenol and zearalenone was assessed using specific PCR assays. Koch′s postulates were carried out to confirm the pathogenicity of the fungus.     

Evidence for recombination and segregation of virulence to pine in a hybrid cross between Gibberella circinata and G. subglutinans

Two species associated with the Gibberella fujikuroi species complex, G. circinata (the cause of pitch canker in pines) and G. subglutinans (avirulent on pine), were found to have limited interfertility in hybrid crosses. MAT idiomorphs, polymorphisms in the histone H3 gene, vegetative compatibility, and virulence phenotypes were used to verify recombination. The MAT idiomorphs appeared to be assorting independently, but the histone H3 haplotype was disproportionately represented by that of the G. subglutinans parent. Ninety-eight percent (45/46) of the progeny tested were vegetatively incompatible with both parents. All F₁ progeny were avirulent to pine, but a wide range of virulence was restored through a backcross to the virulent parent (G. circinata). Attempts at hybrid crosses using other isolate combinations were rarely successful (1/26). This limited interfertility supports retention of G. circinata and G. subglutinans as separate species, but offers opportunities to characterize the inheritance of virulence to pine.     

Microbial transformation of ginsenosides Rb1, Rb3 and Rc by Fusarium sacchari

Aims: This study examined the transformation pathways of ginsenosides G‐Rb₁, G‐Rb₃, and G‐Rc by the fungus Fusarium sacchari. Methods and Results: Ginsenosides G‐Rb₁, G‐Rb₃ and G‐Rc were isolated from leaves of Radix notoginseng, and their structural identification was confirmed using NMR. Transformation of G‐Rb₁, G‐Rb₃ and G‐Rc by Fusarium sacchari was respectively experimented. Kinetic evolutions of G‐Rb₁, G‐Rb₃ and G‐Rc and their metabolites during the cell incubation were monitored by HPLC analysis. High‐performance liquid chromatography (HPLC) was used for monitoring the transformation kinetics of bioactive compounds during F. sacchari metabolism. Conclusions: Ginsenoside C‐K was transformed by F. sacchari from G‐Rb₁ via G‐Rd or via G‐F₂, or from G‐Rb₁ via firstly Rd and then G‐F₂, and C‐Mx was transformed by F. sacchari or directly from Rb₃, or from Rb₃ via Gy‐IX, while G‐Mc was transformed by F. sacchari directly from G‐Rc. Furthermore, C‐K could be also formed from G‐Rc via notoginsenoside Fe (N‐Fe). Significance and Impact of the Study: The results showed an important practical application in the preparation of ginsenoside C‐K. As our precious research indicated C‐K possessed much more antitumor activities than C‐Mx and G‐Mc, so according to the transformation pathways proposed by this work, the production of antitumor compound C‐K may be performed by biotransformation of G‐Rb₁ previously isolated from PNLS.     

Glucosinolate profiling of Brassica rapa cultivars after infection by Leptosphaeria maculans and Fusarium oxysporum

The glucosinolate contents of two different cultivars of Brassica rapa (Herfstraap and Oleifera) infected with Leptosphaeria maculans and Fusarium oxysporum were determined. Infection triggered the accumulation of aliphatic glucosinolates (gluconapin, progoitrin, glucobrassicanapin and gluconapoleiferin) and indole glucosinolate (4-hydroxy-glucobrassicin) in Herfstraap and of two indole glucosinolates (glucobrassicin and 4-hydroxy-glucobrassicin) in Oleifera. While total and aliphatic glucosinolates decreased significantly in Oleifera, a large increase was observed in Herfstraap after fungal infection. The indole glucosinolate glucobrassicin accumulated in Oleifera at a higher rate than Herfstraap especially after infection with F. oxysporum. Apparently the interaction between fungus and B. rapa is cultivar and fungal species specific.     

长江流域禾谷镰孢菌群部分菌株系统发育学、产毒素化学型及致病力研究

从采集自长江流域引起小麦赤霉病的禾谷镰孢菌群(Fusarium graminearum clade)菌株中选取了31株,扩增并测定了这些菌株的EF-1α(translation elongation factor)、PHO(phosphate permease)基因序列,利用相关软件进行了系统发育分析。对这些菌株的产毒素化学型进行了分子检测。同时,用两个小麦品种(扬麦158和安农8455)测定了菌株的致病力。系统发育分析表明绝大多数菌株与F.asiaticum聚为一枝,只有一个菌株11027与F.graminearum聚类。30株F.asiaticum中有24株产脱氧雪腐镰孢菌烯醇(deoxynivalenol,DON)和3-乙酰脱氧雪腐镰孢菌烯醇(3-acetyldeoxynivalenol,3-AcDON),另外6株产雪腐镰孢菌烯醇(Nivalenol,NIV)。一株F.graminearum菌株11027产脱氧雪腐镰孢菌烯醇(DON)和15-乙酰脱氧雪腐镰孢菌烯醇(15-acetyldeoxynivalenol,15-AcDON)。在扬麦158上,菌株间的致病力分化较为明显,产NIV毒素的菌株致病力普遍较弱,强致病力的菌株都产3-AcDON毒素。结果表明在我国长江流域,产3-AcDON毒素的F.asiaticum是引起小麦赤霉病的优势种群,中抗赤霉病的小麦品种扬麦158可以有效评价菌株的致病力强弱。     

Biotransformations of ent-18-acetoxy-6-ketomanoyl oxides epimers at C-13 with filamentous fungi

Two ent-18-acetoxy-6-oxomanoyl oxides, epimers at C-13, have been prepared from ent-6alpha,8alpha,18-trihydroxylabda-13(16),14-diene (andalusol), isolated from Sideritis foetens, by means of several chemical pathways and a regioselective acylation with Candida cylindracea lipase (CCL). Biotransformation of these 13-epimeric ent-manoyl oxides by Fusarium moniliforme and Neurospora crassa produced mainly ent-1beta- or ent-11alpha-hydroxylations, as well as their deacetylated derivatives, in both epimers. In addition, with the 13-epi substrate N. crassa originated other minor hydroxylations by the ent-alpha face at C-1 or at C-12, whereas an ent-11beta-hydroxyl group, probably originated by reduction of an 11-oxo derivative also isolated, was achieved with the 13-normal substrate.