金针菇生活史各阶段核相研究

对金针菇Flammulina velutipes生活史各阶段的菌丝体、子实体、担孢子等进行荧光显微观察。结果表明,金针菇单个担孢子发育而来的同核体菌丝为单核,无锁状联合,部分单孢菌株能形成同核子实体,同核子实体的原担子中只有1个核,该核在担子中进行一次有丝分裂形成纵向排列的2个子核,担子发育停止,同核子实体不产生担孢子;具有可亲和交配型的两个同核体菌丝经过质配形成异核体菌丝,异核体菌丝双核,具有锁状联合,能形成异核子实体,异核子实体的原担子中具有2个核,这2个核经过核配融合为1个二倍核,二倍核在担子中进行减数分裂形成4个单倍子核,4个子核分别进入4个担孢子中,随着担孢子继续发育,其中的单核再进行一次有丝分裂,成熟担孢子为双核,但这2个核是同质的。单核菌丝和双核菌丝都能产生粉孢子,且产生的粉孢子均为单核。     

金针菇担孢子核相及遗传属性的研究

以3个不同的金针菇菌株为材料,研究了其担孢子的核相及遗传属性。荧光染色观察显示,担孢子核相以双核为主,双核孢子、单核孢子和无核孢子分别占80.2%、7.5%和12.3%。源于单孢分离物的菌丝为有隔膜、无锁状联合的多核菌丝。在交配试验中,源于不同菌株单孢分离物的菌丝原生质体的配对形成具锁状联合的菌落,而源于同一单孢分离物的菌丝原生质体的配对则形成无锁状联合的菌落,暗示担孢子中的两个核具有相同的交配型。RAPD分析显示,源于同一单孢分离物的菌丝原生质体为10个随机引物所扩增的图谱彼此完全相同,印证了担孢子中的双核是同质的。此外,观察表明,一个担子上着生有4个担孢子。因此,金针菇是一种具4个含同质双核担孢子的四极性蕈菌。     

食用外共生菌根真菌兰茂牛肝菌Lanmaoa asiatica纯培养条件下不同发育时期的核相

食用外共生菌根菌是一类可食用并与植物共生的大型真菌,其在纯培养条件下菌丝生长缓慢,不会扭结发育成原基,不能完成生活史。因此关于食用菌根菌纯培养条件下生活史的研究报道极少。本研究的兰茂牛肝菌Lanmaoa asiatica已能在纯培养条件下诱导出原基,这使生活史的研究得以完成。利用扫描电子显微镜、透射电子显微镜及荧光显微镜对兰茂牛肝菌子实体担子、担孢子、纯培养菌丝和原基的核相进行了观察。结果表明,子实体菌丝细胞为双核,担子经过减数分裂形成4个单核担孢子;担孢子萌发时长轴端长出芽状突起伸长为菌丝,原孢子中的细胞核不分裂,直接进入菌丝,形成单核初生菌丝;初生菌丝5d后变为双核菌丝;纯培养菌丝及原基细胞均为双核,其菌丝表面光滑,未观察到锁状联合。     

基于担孢子形成过程四分体随机分离规律揭示草菇的有性生活史

本研究观察了草菇担子上着生担孢子的类型、担孢子细胞核数量,扩增了单孢菌株交配型A因子特异序列,基于减数分裂后四分体随机分离进入担孢子的遗传规律,分析了异核担孢子和同核(或单核)担孢子的比例。研究结果表明,草菇担孢子中异核担孢子的比例平均为7.14%,同核或单核担孢子的比例平均为92.86%。单核或同核的担孢子萌发后需要质配形成异核体才能完成有性生殖,交配方式类似异宗配合;异核担孢子萌发直接形成异核菌丝,其有性生殖类似同宗配合。     

土红粉盖鹅膏菌减数分裂及核相变化的观察

用双苯并咪唑（Ｈｏｅｃｈｓｔ ３３２５８）染色法对不同大小的土红粉盖鹅膏菌子０实体切取菌褶进行观察。结果表明：土红盖鹅膏菌最初形成单倍性双核原担子,单倍性双核原担子发生核配,形成二倍性单核原担子,二倍性单核原担子细胞核发生染色体复制,经减数分裂过程形成４个染色体减半的单倍性子核,这４个子核分别进入形成的４个担孢子中,留下无核的空担子;在减数分裂过程中,出现明显的土星环式细胞;在担孢子中子核又发生有     

黄伞单孢杂交育种的初步研究

以采自山西省五台山和关帝山的WT3 和GD3两个黄伞纯化菌株为材料,显微观察了黄伞担孢子萌发的菌丝及交配特征,在PDA培养基上担孢子首先在其一端萌发出菌丝,宽度约3~4μm,接着产生分枝呈散发状向四周延伸。试验表明:单核菌丝体上可产生类似原基的凸状体,但不具结实性。两个单核菌丝交配后出现锁状联合是形成双核菌丝的典型特征,并具有结实性。     

榆耳有性结构及生活史的研究

本文通过电镜扫描、石腊切片及用苏木精染色法和DAPI荧光染色,对榆耳子实体有性结构进行观察,证实榆耳子实体菌盖结构分三层:上表层为毛层,表面着生有排列较密集顶端游离的菌丝,它们相互粘连呈菌丝束;中间层为髓部,由较疏松而相互交织在一起的薄壁菌丝组成,菌丝间充满胶质物质;下表层为子实层,表面起伏不平,呈不规则的疣状突起,上面着生担子和囊状体,担子无隔膜棍棒形,外表有不规则的网状纹饰,其顶部着生4个瓶梗状小梗,每个小梗上着生1个椭圆形或腊肠形担孢子,大小为2.5—3.0×6.0—6.5μm,担孢子表面有不规则的网状纹饰结构。在担子间的囊状体为长圆柱形或圆锥形,表面有较密的不规则的网状纹饰。 榆耳有性生殖为异宗配合。绝大多数担孢子含一个细胞核,很少数担孢子含两个细胞核。孢子萌发为一端萌发,也有少数为两端萌发。初生菌丝单核,不能形成子实体,当两种不同遗传性的交配型的初生菌丝结合后,形成具有锁状联合结构的双核菌丝,并可发育成子实体。榆耳具有典型减数分裂过程,不具有减数分裂后核分裂行为,四个子核分别进入四个担孢子内。 在初生菌丝或次生菌丝上,均可产生间生的或顶生的厚垣孢子。经过温度、光照和紫外线照射的诱发,均未发现有其它类型的无性孢子产生。因此,榆耳菌的生活史和大多数担子     

金针菇单孢菌株菌丝生长速度QTL定位分析

本研究以已经完成基因组测序的单核菌株“6-3”与“6-21”为出发菌株,配对后获得有锁状联合的异核菌株并进行出菇,收集担孢子,单孢分离获得90个菌株构成作图群体,对作图群体的每个菌株进行二代测序并测定菌丝在PDA培养基的生长速度。分析“6-3”与“6-21”两单核菌株的SNP,获得68 914个高质量SNP标记用于遗传连锁群分析,构建了14个遗传连锁群,总长度744.32cM,平均长度为53.17cM,标记间平均遗传距离为1.88cM。QTL分析获得一个控制菌丝生长速度的基因座qMGRP1-LG7,该基因座包含134个基因,富集了与物质代谢有关的通路和基因。     

茯苓基本生物学特性研究

以11个不同来源的茯苓菌株为材料,研究了茯苓菌丝体、子实体和担孢子的形态特征及适宜的生长、发育条件。结果表明,茯苓菌丝体为少分枝、有隔膜、无锁状联合的多核菌丝,茯苓担孢子核相以双核为主,双核孢子,单核孢子和无核孢子分别占87.2%,4.7%和8.1%。配对试验结果表明,同一菌株及不同菌株原生质体分离株间的配对均能融洽生长,同一菌株担孢子间的配对均产生拮抗线,但其中有少数配对在交接区形成扇形区域,拮抗线随后消失,而不同菌株担孢子间的配对则全部形成稳定的栅栏型菌落,暗示茯苓担孢子中的两个细胞核是具遗传互补性,能形成独立个体的异双核,茯苓可能是一种次级同宗结合菌。     

狭义小奥德蘑属（膨瑚菌科,蘑菇目）的一个新系统

本文对狭义小奥德蘑属Oudemansiella s. str.的概念做了修订,在修订后的属中,狭义干蘑属Xerula s. str.的物种不纳入其中。在狭义小奥德蘑属下,提出了一个包含4个组O. sect. Oudemansiella、Mucidula、Dactylosporina 和 Radicatae的新系统。小奥德蘑组sect. Oudemansiella包括热带至南温带的一些物种,如新热带小奥德蘑O. platensis、澳洲小奥德蘑O. australis、旧热带小奥德蘑O. canarii和宽褶小奥德蘑O. crassifolia,这些物种的菌盖表皮为粘栅栏型,由菌丝组成,但其中常夹杂有链状排列的膨大细胞。粘蘑组sect. Mucidula包含北半球温带至亚热带的一些物种,如粘小奥德蘑O. mucida、网褶小奥德蘑O. venosolamellata和近粘小奥德蘑O. submucida,其菌盖表皮为粘子实层-栅栏型,由近棒状的顶端膨大细胞组成。小奥德蘑组和粘蘑组的物种,在外形和小生境上有相似之处,其担子果皆生于地表外的腐木上,菌柄上有或无菌环。刺孢组sect. Dactylosporina包含中南美洲那些孢子表面有指状凸起的物种。长根组sect. Radicatae由长根小奥德蘑O. radicata及其近缘种为代表,是该属中最大的组,包括该属其他三组之外的所有种。北美的O. americana、欧洲的O. caussei 和东亚的O. hongoi曾被置于小奥德蘑属中的白毛组O. sect. Albotomentosae或干蘑属的亮毛组X. sect. Hyalosetae,在本系统中它们没有纳入小奥德蘑属,因为它们可能代表一个单独的属。本文还提出了1新等级、32个新组合和1个新名称。     

Basidiospore formation in monokaryotic fruiting bodies of a mutant strain of Coprinus macrorhizus

The process of basidiospore formation in a mutant strain Fis^c of Coprinus macrorhizus, a heterothallic species of Basidiomycete, which forms monokaryotic fruiting bodies was examined. A single nucleus in a young basidium divided mitotically and two daughter nuclei were fused subsequently. The fused nucleus then divided meiotically forming four basidiospores on a basidium. The typical chromosome behaviours in the first meiotic prophase were observed. Synaptonemal complexes were observed in a basidium at the first meiotic prophase. A continuous illumination of fruiting bodies was effective to arrest meiosis in monokaryotic fruiting bodies at the particular stage of meiotic division.     

Purification and Identification of the Fruiting-Inducing Substances in Coprinus macrorhizus

Substances which are effective in inducing fruiting bodies in monokaryotic mycelia of the fis(+) strain of Coprinus macrorhizus were purified and characterized. The active components of fruiting-inducing substances were identified as adenosine-3'-monophosphate, adenosine 3',5'-cyclic monophosphate (cyclic AMP), and a protein which is bound with the cyclic AMP. Cyclic AMP was synthesized from adenine within mycelia of the mutant strains which form monokaryotic fruiting bodies without the addition of fruiting-inducing substances, but not in those of the strains which do not form monokaryotic fruiting bodies. The proteins which bind with cyclic AMP were detected in crude extracts of mycelia of those strains which form monokaryotic fruiting bodies and of the dikaryon, but not in those of the strains which do not form monokaryotic fruiting bodies.     

Stereum sanguinolentum: Is it an amphithallic basidiomycete?

Monobasidiospore isolates were prepared from basidiocarps of Stereum sanguinolentum. Five isolates per basidiome were paired with each other and with isolates from the trama. Interbasidiome pairings of the trama isolates and of a selection of single-spore isolates also were performed. Thin sections of the hymenium were stained with DAPI and examined by fluorescence microscopy to study the nuclei in the basidia. Spore prints were stained with DAPI to count the number of nuclei per spore. SEM was used to determine the number of basidiospores per basidium. All intrabasidiome pairings were compatible. In contrast, interbasidiome pairings, except one, were incompatible, independent of whether single-spore or trama isolates were paired. Fertile basidiomes were formed in single-basidiospore cultures. Basidia were regularly four-spored. On average, 5% of the basidiospores possessed one nucleus, 82% two, 2% three and 1% four nuclei. Ten percent of the spores appeared to be empty. Karyogamy, meiosis and postmeiotic mitosis were observed in the basidia. Nuclei resulting directly from meiosis, i.e., without having undergone postmeiotic mitosis, sometimes were observed in the sterigmata or spore primordia. The high number of vegetative compatibility groups (VCG) of S. sanguinolentum observed in this study and earlier studies is difficult to explain without sexual or parasexual recombination. We suppose that the majority of spores with ≥2 nuclei are amphithallic, possessing at least one nucleus of each mating type. Recombination could occur by exchange of nuclei among VCGs via anastomoses between homothallic compartments. Transfer of nuclei from heterothallic to homothallic mycelia or matings between homothallic mycelia, which originate from monokaryotic spores, might be other paths for gene exchange.     

Nuclear fusion,meiosis and the origin of dikaryotic hyphae in Armillariella mellea

The behaviour of nuclei during the growth and differentiation of basidiocarp primordia of Armillariella mellea (Vahl) Karst. is described. The primordial initials which arose from monokaryotic rhizomorphs were also monokaryotic. In older primordia, at the site of initiation of gill folds, multinucleate cells formed at the tips of monokaryotic hyphae and gave rise to the dikaryotic hyphae bearing clamp connections. These formed the gills of the older primordia. Cytological studies suggested that the nuclei in monokaryotic cells were diploid. In young basidial primordia haploidization occurred in the cells which were to become multinucleate prior to giving rise to dikaryotic hyphae of the gills. In mature basidia after nuclear fusion and meiosis had occurred, each of the four haploid daughter nucleic migrated into a basidiospore and then divided mitotically. One of the mitotic daughter nucleic migrated from each spore back into the basidium so that mature spores were uninucleate.Abbreviations M.T.O.C. microtubule organizing centre     

Ultrastructure of developing basidiospores in <Emphasis Type="Italic">Rhizopogon roseolus</Emphasis> (= <Emphasis Type="Italic">R. rubescens</Emphasis>)

The ultrastructure of developing basidiospores in Rhizopogon roseolus is described. When viewed in the fruiting body chamber using scanning electron microscopy, basidiospores appear narrowly ellipsoid and have smooth walls. Eight basidiospores are usually produced on the apex of each sterigma on the basidium. Transmission electron micrographs showed that basidiospores formed by movement of cytoplasm (including the nuclei) via the sterigmata, and then each basidiospore eventually became separated from its sterigma by an electron-lucent septum. The sterigma and basidium subsequently collapsed, resulting in spore release. Freshly released spores retained the sterigmal appendage connected to the collapsed basidium. After spore release, the major ultrastructural changes in the spore concerned the lipid bodies and the spore wall. During maturation, lipid bodies formed and then expanded. Before release, the spore wall was homogeneous and electronlucent, but after release the spore wall comprised two distinct layers with electron-dense depositions at the inner wall, and the dense depositions formed an electron-dense third layer. The mature spore wall complex comprised at least four distinct layers: the outer electron-lucent thin double layers, the mottled electron-dense third layer, and the electron-lucent fourth layer in which electron-lucent granular substances were dispersed.     

Dikaryons of the basidiomycete fungus Schizophyllum commune: evolution in long-term culture

The impact of ploidy on adaptation is a central issue in evolutionary biology. While many eukaryotic organisms exist as diploids, with two sets of gametic genomes residing in the same nucleus, most basidiomycete fungi exist as dikaryons in which the two genomes exist in separate nuclei that are physically paired and that divide in a coordinated manner during hyphal extension. To determine if haploid monokaryotic and dikaryotic mycelia adapt to novel environments under natural selection, we serially transferred replicate populations of each ploidy state on minimal medium for 18 months (approximately 13,000 generations). Dikaryotic mycelia responded to selection with increases in growth rate, while haploid monokaryotic mycelia did not. To determine if the haploid components of the dikaryon adapt reciprocally to one another's presence over time, we recovered the intact haploid components of dikaryotic mycelia at different time points (without meiosis) and mated them with nuclei of different evolutionary histories. We found evidence for coadaptation between nuclei in one dikaryotic line, in which a dominant deleterious mutation in one nucleus was followed by a compensatory mutation in the other nucleus; the mutant nuclei that evolved together had the best overall fitness. In other lines, nuclei had equal or higher fitness when paired with nuclei of other histories, indicating a heterozygote advantage. To determine if genetic exchange occurs between the two nuclei of a dikaryon, we developed a 24-locus genotyping system based on single nucleotide polymorphisms to monitor somatic exchange. We observed genetic exchange and recombination between the nuclei of several different dikaryons, resulting in genotypic variation in these mitotic cell lineages.     

Mating System and Basidiospore Formation in the Lignin-Degrading Basidiomycete Phanerochaete chrysosporium

Prototrophic strains recovered from crosses between auxotrophic strains of the lignin-degrading basidiomycete Phanerochaete chrysosporium were induced to fruit. The progeny of most of these self-crosses were prototrophic, indicating that the nuclei of the original prototroph were wild-type recombinants rather than complementary heterokaryons and that the binucleate basidiospores of this organism are homokaryotic. Various wild-type strains were shown to have multinucleate cells lacking clamp connections and to possess a variable number of sterigmata per basidium. Colonies arising from single conidia of various wild-type strains were all capable of producing fruit bodies and basidiospores. In addition, single basidiospores from three wild-type strains all produced fruit bodies and basidiospores. Nonfruiting as well as fruiting isolates were obtained from single basidiospores of five other wild-type strains. Basidiospores from these fruiting isolates always yielded colonies that fruited, again indicating that the spores are homokaryotic. Nonfruiting isolates from the same strain did not produce basidiospores when allowed to form a heterokaryon, implying that these isolates do not represent mating types. All this evidence indicates that P. chrysosporium has a primary homothallic mating system. In addition to fruiting and nonfruiting phenotypes, basidiospores from strain OGC101, a derivative of ME-446, gave rise to colonies which did not grow on cellulose (Cel⁻). The fruiting, nonfruiting, and Cel⁻ phenotypes differed from each other and from the parental wild-type strain in a variety of characteristics, including growth, conidiation, and evolution of ¹⁴CO₂ from ¹⁴C-side chain-labeled lignin, indicating that strain OCG101 is a heterokaryon.     

Alternation of nuclear phase in the filamentous basidiomycete,Helicobasidium mompa

Variation in the number of nuclei and cellular ploidy were observed in eight strains ofHelicobasidium mompa. The basidiospores, single-spore isolates and field-isolated strains were all dikaryons. The cellular ploidy, which was assessed by analyzing the fluorescence emitted by DAPI-stained nuclei, was unstable: monokaryotic strains derived from the original dikaryotic strains by successive subcultures were mainly tetraploid, although the original dikaryon was in most cases diploid. On the other hand, a dikaryotic strain derived by treatment with benomyl was haploid. These results suggest that diploid dikaryon is a normal nuclear phase ofH. mompa in nature, and the alternation of ploidy may be due to a feature of the mating system of this fungus.     

Chemical and genetical control of induction of monokaryotic fruiting bodies in Coprinus macrorhizus

Summary Fruiting-inducing substance (FIS), which is effective to induce fruiting bodies in monokaryotic mycelia of a strain of the Basidiomycete, Coprinus macrorhizus, has been detected in cell-free extracts of fruiting bodies and dikaryotic mycelia of C. macrorhizus itself and fruiting bodies of several other Basidiomycete species. Inducibility by FIS was controlled by genetic and environmental factors. Constitutive mutants which form monokaryotic fruiting bodies without addition of FIS were isolated. Fruiting bodies and monokaryotic mycelia of these mutants also contained FIS.FIS was stable to heat, acid and alkaline hydrolysis, and several enzymes degradating proteins and nucleic acids. Two fractions of FIS were obtained after Sephadex G-25 chromatography. One of them contained protein and the other appears to have similar chemical nature as adenosine-3, 5-monophosphate or adenosine-3-monophosphate which were active to induce monokaryotic fruiting.