Aspects of the pathology and etiology of 'drippy gill' disease of the cultivated mushroom Agaricus bisporus

Agaricus bisporus sporocarps exhibiting characteristic 'drippy gill' symptoms from a natural outbreak were examined. Discrete bacterial droplets on the hymenial lamellae often coalesced to form ribbons of bacterial ooze. Longitudinal splits on the stipe were lined with a similar bacterial ooze. Bacteria isolated from both the hymenium and stipe were identified as Pseudomonas agarici, and were confirmed to be the causal organism by satisfying Koch's postulates. By light and transmission electron microscopy, the causal bacteria were found to colonize the extrahyphal spaces and degrade the extracellular matrix within affected sporocarps. Degradation of the extracellular matrix was shown to reduce the integrity of the sporocarp, and result in stipe splitting and hymenium disruption. In artificial inoculations of the pileus, bacteria were shown to exist predominantly in sporocarp tissue below the point of inoculation and above affected areas of the hymenium, indicating an approximately vertical passage through the sporocarp via the extracellular spaces. The dissolution of the extracellular matrix, and the observed failure of the bacterium to produce a toxin active against A. bisporus, allow the bacteria to pass through protective membranes unnoticed, and infect the stipe and hymenium prior to veil break. These observations dispel previous assumptions of intrahyphal existence and transmission. In the few instances in which the bacteria were observed to be intrahyphal, the host fungal cell wall was often broken, suggesting intrahyphal existence was opportunistic rather than obligatory. The taxonomic position of a bacterium isolated previously from sporocarps exhibiting symptoms similar to those of drippy gill was determined by examining the biochemical and nutritional profiles of the bacterium, and comparing them with other Pseudomonas agarici isolates.     

A quantitative trait locus of Agaricus bisporus resistance to Pseudomonas tolaasii is closely linked to natural cap color.

A quantitative trait locus (QTL) of resistance to Pseudomonas tolaasii was detected in Agaricus bisporus using a cross between a wild strain from the Sonoran desert and a cultivated strain. The resistance QTL was strongly linked with the brown color allele of PPC1. This QTL explained about 30% of the variation observed for living bacteria-induced symptoms. The use of bacterial toxin did not reproduce living bacteria symptoms but revealed the same QTL. The latter QTL was not affected by environmental variation. No relation was found between the resistance QTL and the tyrosinase gene, which is involved in the browning process.     

双孢蘑菇杂交菌株As2796家系的分子遗传研究

应用PCR和凝胶电泳等技术,对双孢蘑菇杂交菌株As2796及其亲本和子代作分子遗传标记跟踪分析,结果如下: 1) 总DNA的RAPD分析表明,随着遗传代数的增加,杂种子代和出发异核体亲本间的遗传差异逐渐增大; 2) mtDNA的酶切图谱表明,亲本8213及其杂交子代具有相同的基因型,表明双孢蘑菇的mtDNA呈单亲遗传; 3) Est同工酶的PAGE图谱表明, 结合了亲本02高产特征和8213优质特征的杂交子代具有两个亲本的标记带型,证明Est同工酶标记是双孢蘑菇新菌株特性预测或鉴定的有效指标。     

Effects of bacteria isolated from a saprophagous rhabditid nematode Caenorhabditis elegans on the mycelial growth of Agaricus bisporus

P. S. GREWAL AND P. HAND. 1992. The effects of 10 species of bacteria isolated from a saprophagous rhabditid nematode Caenorhabditis elegans on mycelial growth of the cultivated mushroom Agaricus bisporus were studied in agar cultures. Bacterial species showed differential effects on the mycelial growth of A. bisporus and the effects also depended upon the mushroom strain (C43, C54 and U3). Bacillus cereus, Bacillus sp. and Enterobacter amnigenus caused significant inhibition in mycelial growth of all three strains of A. bisporus. Pseudomonas aeruginosa, Ps. fluorescens biovar reactans and Ps. maltophilia resulted in a significant increase in mycelial growth of C54 strain. Enterobacter cloacae caused a mean inhibition of about 83% in the linear mycelial extension of the most commonly cultivated mushroom strain U3. Bacillus cereus, Ent. amnigenus and Ent. cloacae produced volatile inhibitory substance(s). This is believed to be the first report about the inhibitory effects of specific bacteria isolated from a saprophagous nematode on the mycelial growth of A. bisporus.     

双孢蘑菇杂交菌株As2796家系的分子遗传研究*

应用PCR和凝胶电泳等技术,对双孢蘑菇杂交菌株As2796及其亲本和子代作分子遗传标记跟踪分析,结果如下: 1) 总DNA的RAPD分析表明,随着遗传代数的增加,杂种子代和出发异核体亲本间的遗传差异逐渐增大; 2) mtDNA的酶切图谱表明,亲本8213及其杂交子代具有相同的基因型,表明双孢蘑菇的mtDNA呈单亲遗传; 3) Est同工酶的PAGE图谱表明, 结合了亲本02高产特征和8213优质特征的杂交子代具有两个亲本的标记带型,证明Est同工酶标记是双孢蘑菇新菌株特性预测或鉴定的有效指标。     

A novel homothallic variety of Agaricus bisporus comprises rare tetrasporic isolates from Europe

Among 400 wild specimens of A. bisporus collected in Europe, only three were tetrasporic. In the case of two of them from France, a previous study showed that one was homokaryotic and hypothetically belonged to a homothallic entity while the other was heterokaryotic and possibly resulted from hybridization between a member of this entity and a classical bisporic strain. A third tetrasporic specimen recently was discovered in Greece. Morphological and genetic comparisons, using alloenzymatic markers, molecular markers and ITS polymorphisms, reveal that this third specimen is homokaryotic and belongs, with the homokaryotic specimen from France, to the same entity. Dissimilarity analysis confirms the hybrid origin of the heterokaryotic specimen. Varietal status is proposed for this homothallic, highly homogeneous entity, and A. bisporus var. eurotetrasporus is described. This novel variety clearly differs from var. bisporus by its tetrasporic basidia and from var. burnettii by its longer spores. It has a complex story because it can interbreed with var. bisporus and shares the same habitat; however, because of its homothallic life cycle and its partial intersterility, it is probably in the process of speciation.     

RAPD discrimination of Agaricus bisporus mushroom cultivars

Cultivars of the white button mushroom Agaricus bisporus are difficult to differentiate, which has made strain protection problematic for this crop species. We have used RAPDs to discriminate between 26 strains of A. bisporus, 24 of which were commercial cultivars, and to characterise the genetic relatedness of these strains. Using 20 primers, 211 RAPD markers were identified and used in hierarchical cluster, patristic distance and parsimony analyses. All strains could be differentiated using the aggregated primer data. Although no one primer could differentiate all 26 strains, several individual primers yielded unique fingerprints for a variety of strains. The greatest differences (up to 28% variation) were observed in comparisons with or between two wild collections of A. bisporus. Quondam cultivars, commercial brown and off-white varieties proved more variable than the widely grown 'hybrid' types. Of the 15 hybrid varieties analysed, only one differed substantially (20% or more variable). The patristic and parsimony analyses both demonstrated the gross similarity of the hybrids, many of which appear to be essentially derived varieties from two original hybrid cultivars. RAPD analyses can assist mushroom strain identification and could play a role in the protection of novel cultivars.     

Entry of diphtheria toxin into cells: possible existence of cellular factor(s) for entry of diphtheria toxin into cells was studied in somatic cell hybrids and hybrid toxins

Ehrlich ascites tumor cells were found to be very insensitive to diphtheria toxin. We formed 37 hybrids from Ehrlich tumor cells and diphtheria toxin-sensitive human fibroblasts. The effects of diphtheria toxin on protein synthesis in those hybrids were examined. The hybrids were divided into three groups on the basis of toxin sensitivity. Group A hybrids were as sensitive to diphtheria toxin as human fibroblasts, Group C were as resistant as Ehrlich tumor cells, and Group B had intermediate sensitivity. Group A hybrids had diphtheria toxin-binding sites but Group B and C had no detectable binding sites. Elongation factor-2 of all the hybrids was susceptible to ADP-ribosylation by fragment A of diphtheria toxin. Cells of Group A and B became more sensitive to CRM 45 (cross-reacting material 45 of diphtheria toxin) after they were exposed to low pH (pH = 4.5). The resistance of Group C to CRM 45 was not affected by the same treatment. Group A and B hybrids and human fibroblasts had similar sensitivities to a hybrid toxin composed of wheat germ agglutinin and fragment A of diphtheria toxin, but Group C and Ehrlich tumor cells were resistant to this hybrid toxin. All the hybrids and Ehrlich tumor cells were more sensitive to a hybrid toxin composed of wheat germ agglutinin and subunit A of ricin than were human fibroblasts. On subcloning of Group B hybrids, one Group C hybrid was obtained, but no Group A hybrid. These facts suggest that Ehrlich ascites tumor cells differ from human fibroblasts in the expression of a factor(s) that is involved in entry of fragment A of diphtheria toxin into the cytoplasm after the toxin binds to its surface receptors.     

Phenotypic variation of Pseudomonas putida and P. tolaasii affects attachment to Agaricus bisporus mycelium.

The effect of phenotypic variation on attachment of Pseudomonas tolaasii and P. putida to Agaricus bisporus mycelium was investigated. Quantitative studies demonstrated the ability of each isolate to attach rapidly and firmly to A. bisporus mycelium and significant differences in attachment of wild-type and phenotypic variant strains were observed. This was most pronounced in P. tolaasii, where the percentage attachment of the wild-type form was always greater than that of the phenotypic variant. The medium upon which the bacteria were cultured, prior to conducting an attachment assay, had a significant effect on their ability to attach. Attachment of the wild-type form of P. putida was enhanced when the assay was performed in the presence of CaCl2, suggesting the involvement of electrostatic forces. No correlation was observed between bacterial hydrophobicity and ability to attach to A. bisporus mycelium. Scanning electron microscopy confirmed the results obtained from the quantitative studies and provided further evidence for marked differences in the ability of the pseudomonads to attach to mycelium. Fibrillar structures and amorphous material were frequently associated with attached cells and appeared to anchor bacteria to each other and to the hyphal surface. A time-course study of attachment using transmission electron microscopy revealed the presence of uneven fibrillar material on the surface of cells. This material stained positive for polysaccharide and may be involved in ensuring rapid, firm attachment of the cells.     

Separable domains define target cell specificities of an RTX hemolysin from Actinobacillus pleuropneumoniae.

The leukotoxin (LktA) from Pasteurella haemolytica and the hemolysin (AppA) from Actinobacillus pleuropneumoniae are members of a highly conserved family of cytolytic proteins produced by gram-negative bacteria. Despite the extensive homology between these gene products, LktA is specific for ruminant leukocytes while AppA, like other hemolysins, lyses erythrocytes and a variety of nucleated cells, including ruminant leukocytes. Both proteins require activation facilitated by the product of an accessory repeat toxin (RTX) C gene for optimal biological activity. We have constructed six genes encoding hybrid toxins by recombining domains of ltkA and appA and have examined the target cell specificities of the resulting hybrid proteins. Our results indicate that the leukocytic potential of AppA, like that of LktA, maps to the C-terminal half of the protein and is physically separable from the region specifying erythrocyte lysis. As a consequence, we were able to construct an RTX toxin capable of lysing erythrocytes but not leukocytes. The specificity of one hybrid was found to be dependent upon the RTX C gene used for activation. With appC activation, this hybrid toxin lysed both erythrocytes and leukocytes, while lktC activation produced a toxin which could attack only leukocytes. This is the first demonstration that the specificity of an RTX toxin can be determined by the process of C-mediated activation.     

Binding properties of diphtheria toxin to cells are altered by mutation in the fragment A domain

CRM197, CRM176, and CRM228 are products of single or multiple missense mutations in the diphtheria toxin gene. CRM197 differs from wild-type toxin in 1 amino acid residue of the fragment A region, and also CRM176 and CRM228 have amino acid substitution(s) in fragment A. We compared the binding properties of CRM197 to toxin-sensitive Vero cells with those of diphtheria toxin and other CRMs. Nicked CRM197 is about 50 times more effective than intact CRM197 in inhibiting the action of diphtheria toxin on sensitive cells, as shown by inhibition of diphtheria toxin cytotoxicity or inhibition of binding of 125I-diphtheria toxin. The binding of native toxin or other CRMs was not significantly affected by nicking. Moreover, the binding of CRM197 to cells was unaffected by ATP, although ATP clearly inhibits binding of diphtheria toxin, CRM176, and CRM228. Two kinds of hybrid protein were formed using fragment B of CRM197: one with fragment A of diphtheria toxin and one with fragment A of CRM228. ATP inhibited the binding of these hybrid proteins. Furthermore, the affinities of these hybrid proteins for diphtheria toxin-sensitive cells were the same as that of native toxin. Thus, it was concluded that the altered binding properties of CRM197 were due to alteration of fragment A and what the interaction of diphtheria toxin with ATP involves both fragments. The results also suggest that fragment A plays a role in diphtheria toxin-receptor interaction.     

DNA amplification polymorphisms of the cultivated mushroom Agaricus bisporus.

Single 10-bp primers were used to generate random amplified polymorphic DNA (RAPD) markers from commercial and wild strains of the cultivated mushroom Agaricus bisporus via the polymerase chain reaction. Of 20 primers tested, 19 amplified A. bisporus DNA, each producing 5 to 15 scorable markers ranging from 0.5 to 3.0 kbp. RAPD markers identified seven distinct genotypes among eight heterokaryotic strains; two of the commercial strains were shown to be related to each other through single-spore descent. Homokaryons recovered from protoplast regenerants of heterokaryotic strains carried a subset of the RAPD markers found in the heterokaryon, and both of the haploid nuclei from two heterokaryons were distinguishable. RAPD markers also served to verify the creation of a hybrid heterokaryon and to analyze meiotic progeny from this new strain: most of the basidiospores displayed RAPD fingerprints identical to that of the parental heterokaryon, although a few selected slow growers were homoallelic at a number of loci that were heteroallelic in the parent, suggesting that they represented rare homokaryotic basidiospores; crossover events between a RAPD marker locus and its respective centromere appeared to be infrequent. These results demonstrate that RAPD markers provide an efficient alternative for strain fingerprinting and a versatile tool for genetic studies and manipulations of A. bisporus.     

DNA amplification polymorphisms of the cultivated mushroom Agaricus bisporus.

Single 10-bp primers were used to generate random amplified polymorphic DNA (RAPD) markers from commercial and wild strains of the cultivated mushroom Agaricus bisporus via the polymerase chain reaction. Of 20 primers tested, 19 amplified A. bisporus DNA, each producing 5 to 15 scorable markers ranging from 0.5 to 3.0 kbp. RAPD markers identified seven distinct genotypes among eight heterokaryotic strains; two of the commercial strains were shown to be related to each other through single-spore descent. Homokaryons recovered from protoplast regenerants of heterokaryotic strains carried a subset of the RAPD markers found in the heterokaryon, and both of the haploid nuclei from two heterokaryons were distinguishable. RAPD markers also served to verify the creation of a hybrid heterokaryon and to analyze meiotic progeny from this new strain: most of the basidiospores displayed RAPD fingerprints identical to that of the parental heterokaryon, although a few selected slow growers were homoallelic at a number of loci that were heteroallelic in the parent, suggesting that they represented rare homokaryotic basidiospores; crossover events between a RAPD marker locus and its respective centromere appeared to be infrequent. These results demonstrate that RAPD markers provide an efficient alternative for strain fingerprinting and a versatile tool for genetic studies and manipulations of A. bisporus.     

Receptor-mediated transport of the hybrid protein ricin-diphtheria toxin fragment A with subsequent ADP-ribosylation of intracellular elongation factor II.

A hybrid protein of ricin and the enzymatically active fragment A of diphtheria toxin (toxin A) has been synthesized and purified. The diphtheria toxin A fragment of the hybrid protein is shown to enter the cytosol compartment of HeLa cells, its presence assayed by the fall of intracellular elongation factor II (EF-2) and the rise of ADP-ribosylated EF-2. Hybrid entrance to HeLa cells is blocked by lactose which blocks receptor-mediated entry of ricin but not by NH4Cl which blocks the transport of diphtheria toxin. It is concluded that the diphtheria toxin fragment A moiety of the hybrid enters the cell cytosol via the ricin receptor-mediated transport system. The kinetics of intracellular ADP-ribosylation of EF-2 by diphtheria toxin have also been studied. Ribosylation is preceded by a toxin dose-dependent lag period. The data suggest that the time constant responsible for the lag period is in the transport step. Models consistent with these data are discussed.     

蘑菇培养料堆制过程中微生物的演替及作用

蘑菇培养料堆制的完成依赖于微生物群落共同作用来实现。综述了堆制阶段培养料中细菌、放线菌、真菌三大类型菌群出现、发展的规律 ,各自作用特点以及它们之间的相关性、拮抗性 ,同时从呼吸途径、酶学角度阐述了嗜热真菌对料选择性的形成和蘑菇菌丝生长的积极意义。     

有害疣孢霉菌与双孢蘑菇的互作关系

通过菌丝对峙、双重培养,以及对发病双孢蘑菇子实体的显微观察,探讨有害疣孢霉菌Mycogone perniciosa（MP0012）与双孢蘑菇Agaricus bisporus（As2796）之间的互作关系。结果表明,在菌丝对峙生长阶段有害疣孢霉菌菌丝不侵入双孢蘑菇菌丝体内,两者可交叉生长,对双孢蘑菇生长影响不显著;对峙与双重培养均显示有害疣孢霉菌菌丝会产生对双孢蘑菇菌丝生长的抑制作用的挥发性物质,造成双孢蘑菇菌丝扭结断裂。同时试验证实了双孢蘑菇菌丝会促进有害疣孢霉菌厚垣孢子的产生和萌发、菌丝生长和发育。侵染实验结果表明,有害疣孢霉菌可直接侵染双孢蘑菇子实体,引起双孢蘑菇子实体病害;对罹病子实体显微观察结果发现,发病前期双孢蘑菇子实体表面长出绒毛状病原菌丝,菌柄中空,菌褶褐变腐烂并长出病原菌丝;发病中期双孢蘑菇子实体内菌丝组织会出现萎缩裂解现象,在近有害疣孢霉菌菌丝一侧的双孢蘑菇子实体菌丝细胞壁被降解;发病后期双孢蘑菇子实体菌丝组织基本消失。由此初步判断有害疣孢霉菌对双孢蘑菇的寄生类型偏向于死体营养型。     

双孢蘑菇耐热相关基因的表达载体构建及转化研究

构建了双孢蘑菇Agaricus bisporus耐热相关基因028-1全长cDNA序列的双元表达载体,通过农杆菌介导转化双孢蘑菇非耐热菌株8213,经潮霉素抗性筛选和PCR鉴定,获得了一批双孢蘑菇转基因菌株。对10株转基因菌株进行了不同温度下的草管走菌试验,结果显示大部分转基因菌株的耐热性能有较为明显的提高。     

Newly secreted adenylate cyclase toxin is responsible for intoxication of target cells by Bordetella pertussis

Adenylate cyclase (AC) toxin is present on the surface of Bordetella pertussis organisms and their addition to eukaryotic cells results in increases in intracellular cAMP. To test the hypothesis that surface-bound toxin is the source for intoxication of cells when incubated with B. pertussis, we characterized the requirements of intoxication from intact bacteria and found that this process is calcium-dependent and blocked by monoclonal antibody to AC toxin or antibody against CD11b, a surface glycoprotein receptor for the toxin. Increases in intracellular cAMP correlate with the number of adherent bacteria, not the total number present in the medium, suggesting that interaction of bacteria with target cells is important for efficient delivery of AC toxin. A filamentous haemagglutinin-deficient mutant (BP353) and a clinical isolate (GMT1), both of which have a marked reduction in AC toxin on their surface, and wild-type B. pertussis (BP338) from which surface AC toxin has been removed by trypsin, were fully competent for intoxicating target cells, demonstrating that surface-bound AC toxin is not responsible for intoxication. B. pertussis killed by gentamicin or gamma irradiation were unable to intoxicate, illustrating that toxin delivery requires viable bacteria. Furthermore, CCCP, a protonophore that disrupts the proton gradient necessary for the secretion of related RTX toxins, blocked intoxication by whole bacteria. These data establish that delivery of this toxin by intact B. pertussis is not dependent on the surface-associated AC toxin, but requires close association of live bacteria with target cells and the active secretion of AC toxin.     

Verticillium disease or "dry bubble" of cultivated mushrooms: the Agaricus bisporus lectin recognizes and binds the Verticillium fungicola cell wall glucogalactomannan

The step of recognition and (or) binding for the development of the disease of the cultivated mushroom Agaricus bisporus by the mycoparasite Verticillium fungicola was studied by several approaches: agglutination of V. fungicola germinated spores by an A. bisporus extract from fruit body cell walls, immunofluorescence microscopy of A. bisporus hyphae from fruit bodies and vegetative mycelia pretreated with purified V. fungicola cell wall glucogalactomannan, and finally, by hemagglutination experiments carried out with an A. bisporus fruit body lectin in the presence and absence of the same glucogalactomannan. Hemagglutinating activity of the purified A. bisporus fruit body lectin was clearly inhibited by the V. fungicola glucogalactomannan, whereas in the A. bisporus vegetative mycelium such lectin was not encountered. All the results obtained make evident the recognition and binding of the A. bisporus fruit body lectin to the V. fungicola cell wall glucogalactomannan, clarifying why the mushrooms, but not the vegetative mycelium, become diseased.