B交配型因子对香菇双核体核型分离比的影响

通过探明A或B交配型因子对双核体回收核型的影响,探讨了香菇双核体经原生质体形成和再生后两个成员核偏分离现象的遗传基础。结果表明,B因子或某些假定的与B因子连锁的基因明显影响去双核化后核的存活力,而A因子对此无明显影响。B因子的特异性与分离自两类异核体（A≠B≠和A=B≠）回收的成员核的存活比例密切相关。可以根据这种功能将B因子排成一个分级的序列。两个参试菌株中的4个B因子的特异性顺序为B1〉B3〉B4〉B2。     

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。     

金针菇褐化病毒(FvBV)脱毒方法

【目的】评价5种不同脱毒方法对金针菇(Flammulina velutipes)菌株的脱毒效果,筛选出脱毒率高和脱毒后金针菇菌株菌丝生长速度、生物量、漆酶活力等性状改善明显的脱毒方法。【方法】以栽培金针菇菌株F-4889为研究材料,从菌丝体中提取大小约2.0 kb的病毒dsRNA,经RT-PCR鉴定该病毒为金针菇褐化病毒(FvBV)。采用菌丝尖端分离、原基组织分离、原生质体单核化、有性生殖和核迁移5种脱毒方法对金针菇菌株进行脱毒处理,利用dsRNA技术和RT-PCR检测脱毒效果。【结果】菌丝尖端分离脱毒后得到1株脱毒菌株;原基组织分离法未能脱毒;原生质体单核化脱毒法得到3株脱毒单核菌株和2株原单杂交脱毒菌株;有性生殖脱毒法获得脱毒孢子单核菌株23株和单孢杂交脱毒菌株8株;核迁移脱毒后得到5株核迁移脱毒菌株。脱毒率依次为25.0%、0、7.5%、57.5%和100%。脱毒菌株的菌丝生长速度、生物量、漆酶活力等均优于出发菌株、菌丝尖端和原基组织分离菌株。【结论】这5种方法中原生质体单核化、有性生殖和核迁移脱毒法脱毒效果较佳,均能有效脱除FvBV,脱毒率高,脱毒后菌株菌丝生长速度、生物量、漆酶活力等均明显提高。     

双向核迁移在香菇遗传和育种中的应用研究

在来源于香菇Lentinula edodes不同双核菌株的单核菌株间进行单—单杂交,并利用双向核迁移现象获得两对双核菌株.之后采用挑取菌落尖端单根菌丝的方法纯化所获得的双核菌株并通过双—单杂交进行单向核迁移,进一步纯化所获得的双核菌株.从菌落形态、显微镜镜检、出菇实验和分子标记等4个方面对两对配对单核和所获得的双核菌株...     

金针菇子实体颜色的遗传规律研究

以金针菇黄色菌株F19和白色菌株F8801为亲本,原生质体单核化获得两亲本的单核菌株,配对杂交获得F1,从F1的子实体分离单孢菌株,与两亲本的原生质体单核化菌株进行回交配对,出菇观察子实体颜色,分析菇体颜色的遗传规律。研究结果表明,黄色为显性、白色为隐性,菇体颜色受一对基因(Cc)控制,与不亲和性因子A或B都没有连锁。     

黑木耳亲本、单核、杂交菌株鉴定的研究

应用荧光核染色技术、酯酶同工酶鉴定技术,对黑木耳亲本双核菌株、原生质体单核菌株和单-单杂交菌株进行筛选鉴定。结果表明:荧光核染色技术可快速有效地鉴定获得菌株的核相,酯酶同工酶技术可准确地区分单核菌株及杂交新菌株的不同核型,研究得到1个酶带差异显著的新菌株。     

黑木耳种内杂交子的鉴定技术*

采用原生质体技术,获得黑木耳(Auricularia auricula)栽培菌株He-1的单核化菌株H1、H2、H3和栽培菌株Ju-1的单核化菌株J1、J2、J3,将H1、H2、H3分别与J1、J2、J3配对杂交,核相观察确认H2J1、H2J2和H2J3均为双核体。酯酶同工酶分析表明,H2J1、H2J2和H2J3不仅具有相应的亲本单核体共有的酶带,而且具有两个亲本各自的特异性标记酶带。RAPD分析表明,引物S30和S62对杂交子H2J1、H2J2和H2J3的扩增图谱中不仅包含相应的亲本单核体所共有的DNA带,而且包含亲本单核体各自的特异性DNA带。拮抗和栽培试验表明,杂交子H2J1、H2J2、H2J3与双核体亲本He-1和Ju-1的菌落之间有窄细的黑色拮抗线,子实体形态上有较明显差异。     

香菇亲本菌株及其杂交后代的RAPD分析

运用随机扩增多态性ＤＮＡ技术对源于两个香菇双核菌的孢子单核体,原生质体单核体及其杂交后代进行了基因组ＤＮＡ多态性分析,用９个随机引物共扩增出１１６条ＤＮＡ片段,其中８２．５％具有多态性,综合分析９个随机引物的扩增谱带,可将所有供试亲本单核本清楚地工,且单聚类分析的结果与其来源及遗传背景相吻合。此外,用两个双核亲本菌株的各４个不同酱 孢子单核体两两酱所得的所有杂交组合,也均可与双核亲本菌株明确地区分     

黑木耳种内杂交子的鉴定技术

采用原生质体技术,获得黑木耳（Auricularia auricula)栽培菌株He- 1的单核化菌株H1、H2、H3和栽培菌株Ju-1的单核化菌株J1、J2、J3,将H1、H2、H3分别与J1、J2、J3配对杂交,核对观察确认H2J1、H2J2和H2J3均为双核体。酯酶同工酶分析表明,H2J1、H2J2和H2J3不仅具有相应的亲本单核体共有的酶带,而且具有两个亲本各自的特异性标记酶带。RAPD分析表明,引物S30和S62对杂交子H2J1、H2J2和H2J3的扩增图谱中不仅包含相应的亲本单核体所共有的DNA带,而且包含亲本单核体各自的特异性DNA带。拮抗和栽培试验表明,杂交子H2J1、H2J2、H2J3与双核体亲本He-1和Ju-1的菌落之间有窄细的黑色拮抗线,子实体形态上有较明显差异。     

利用SSR标记鉴定香菇单核体及杂交后代

【目的】研究简单重复序列(Simple sequence repeat,SSR)分子标记方法用于香菇原生质体单核体、孢子单核体及其杂交后代的分离和鉴定。【方法】利用基于香菇全基因组序列信息开发的SSR标记,分析由香菇品种"L808"双核菌丝制备的原生质体单核体、孢子单核体及其杂交后代的SSR指纹。【结果】对制备的原生质体单核体的鉴定中,在不经过杂交配对的情况下,鉴定出"L808"的两种不同极性的原生质体单核体,其分离比例为191:1,该鉴定结果得到SSR标记、随机扩增多态性DNA(Random amplified polymorphismic DNA,RAPD)标记及传统方法的验证。另外,开发的香菇SSR标记还能以多位点组合的方式,用于对孢子单核体及其杂交后代的鉴定。【结论】应用SSR标记可加快香菇单核体的制备进程,并提高鉴定单核体及相关杂交菌株的准确性,促进香菇遗传育种研究。     

Nuclear selection in monokaryotization of dikaryotic mycelia ofPholiota nameko as described by leading and following nuclei

To examine monokaryotization of dikaryotic mycelia ofPholiota nameko, 18 monokaryotic stocks were used to produce a total of 130 dikaryotic stocks by reciprocal crossing. Monokaryotized mycelium was raised from dikaryotic mycelium in the peripheral zone of the growing colony. The stocks mated with a particular group of monokaryons produced wide-range monokaryotization at higher rates than the other combinations of hybridization. The growth rates of the monokaryotized mycelia exceeded from those of the corresponding parental dikaryons. The monokaryotized mycelium was isolated and back-crossed to parental monokaryotic stocks. Most of the isolates had nuclear types similar to only one of the parental stocks, while the replicates of isolates from two dikaryotic hybrids showed split nuclear type compositions. It is suggested that a relative dominance is active in the selection of one of the two nuclei of the dikaryotic cells in monokaryotization. The hierarchy of relative dominance among nuclei of 18 parental monokaryotic stocks in the monokaryotization of their reciprocal crossing products was estimated. We propose the involvement of a cascade process in dikaryotic cell division, in which the first dividing nucleus (to be found in the monokaryotized cell) may act as the leading nucleus and the other one as the following nucleus.     

Nuclear selection in oidium formation from dikaryotic mycelia ofFlammulina velutipes

The effect of nuclear dominance in monokaryotic oidium formation from dikaryotic mycelia in a tetrapolar basidiomycete,Flammulina velutipes, was examined. A total of 46 monokaryotic stocks were used to produce 194 hybrid dikaryotic stocks by crossing. The proportion of homokaryons among the oidium isolates from dikaryotic mycelia was over 95%. The staining of nuclei of oidia with propidium iodide showed that over 90% of oidia were monokaryotic and suggested that these oidia had single haploid nuclei at the G1 stage. The monokaryotic oidium isolates from hybrid dikaryons were backrossed to parental monokaryotic stocks. Although most of the monokaryotic oidium isolates (except for those from 17 hybrid dikaryons from a total of 194 test stocks) showed nuclear types similar to only one of the parental stocks, the process seems to produce essentially the split nuclear type composition. Therefore, the monokaryotization in oidium formation from dikaryotic mycelia essentially involves the process of nuclear selection. The two separate results of hierarchies of relative dominance among two nuclei of the parental dikaryons in the monokaryotic oidium formation by grouping with incompatibility factor compositions were determined. Only a few discrepancies were found in the hierarchies between the two specific nuclear compositions of hybrid dikaryons.     

长根小奥德蘑双孢菌株与四孢菌株核相变化的比较

用双苯并咪唑（Hoechst 33258）染色法分别对长根小奥德蘑Oudemansiella radicata双孢菌株和四孢菌株的菌丝、子实体、担孢子进行染色观察,结果表明：双孢长根小奥德蘑菌丝细胞多为单核,无锁状联合;原担子中单核进行一次有丝分裂形成两个横向或纵向排列的子核,这2个子核分别进入2个担孢子中,留下无核的空担子;成熟担孢子具有一个核。四孢长根小奥德蘑菌丝细胞大多数为双核,具有锁状联合;进入原担子中的两个单倍性细胞核先发生核配,形成一个二倍性的核,再经过减数分裂形成四个染色体减半的单倍性子核,     

设施化专用香菇种质资源挖掘

以香菇L808菌株基因组序列为参照,开发了300份插入/缺失(InDel)标记。通过5个菌株的初筛,选出均匀分布于基因组的82份多态标记对42份香菇种质资源进行遗传背景分析。同时在设施化栽培条件下考察了种质资源的生育期、菌棒转色、菌棒硬度、现蕾期和产量等表型。结果表明：供试香菇种质资源的遗传多样性丰富,栽培菌株与野生菌株的遗传距离较远,遗传相似性系数平均值为0.51。群体结构分析将种质资源分为6个亚群,与基于遗传距离的系统聚类结果较为一致。亚群间菌株具有较远的亲缘关系,遗传分化指数平均值为0.290,适合用于杂交育种。表型结果显示,设施化栽培条件下的种质资源农艺性状分化程度高,亚群间菌株的生育期、现蕾期和产量均有显著差异。种质资源多样性分析结果为香菇杂交育种工作奠定了基础。     

利用InDel标记分析中国香菇菌株的遗传多样性与群体结构

通过对5个香菇菌株重测序,以香菇L808-1菌株的全基因组序列为参考基因组,分析了这些菌株中插入/缺失（InDel）标记位点在香菇基因组10条染色体上的分布,并筛选了插入/缺失碱基数≥15的位点,合成了449对InDel标记引物。经过PCR和电泳检测,其中237对引物条带清晰。最终筛选出107个PIC≥0.3的标记作为核心InDel标记对来自国内的44份香菇菌株进行遗传多样性分析。聚类分析显示栽培菌株和野生菌株各自聚为一支,所选香菇菌株间存在明显的群体分层。群体结构分析显示香菇种质资源可分为4个亚群,主成分分析显示香菇菌株之间的位置及距离与聚类分析和群体结构分析结果相符。香菇InDel分子标记的开发与应用,为香菇核心种质的构建和种质资源育种引用提供了基础。     

Expression of Proteins and Glycoproteins Encoded by the Haploid Nuclei in the Dikaryotic State in the Basidiomycete Agrocybe aegerita

The total proteins and concanavalin A-binding glycoproteins of the cultivated mushroom Agrocybe aegerita were studied in homokaryotic siblings and in dikaryotic strains. The glycoproteins exhibited considerable variability compared with the proteins; the genetic diversity detected in homokaryons in the glycoprotein analysis was 30-fold higher than the genetic diversity revealed by protein analysis, and the glycoprotein patterns could be used to characterize individual genotypes. We found that the expression of glycoproteins in haploid nuclei was significantly asymmetric when the nuclei were paired in dikaryons. The expression levels of the two component nuclei depended on their genotypes, and each haploid nucleus was characterized by its level of expression. Furthermore, some specific glycoproteins that were not detected in all of the homokaryons were newly synthesized in the dikaryotic strains. Among these was a glycoprotein designated gpAa-65, which was identified in all of the dikaryotic strains and appeared to be a good molecular marker of the dikaryotic state.     

木屑马铃薯培养基促进香菇单核体菌丝体生长的表达谱分析

香菇单核体菌株在传统PDA培养基上生长时具有生长缓慢、容易老化等问题,本研究以 1株香菇双核体Y0040以及相对应的2株单核体(Y0040-1和Y0040-3)为研究材料,通过添加不同比例木屑粉的PDA培养基筛选适合香菇单核体生长的配比,结果表明添加木屑能够显著促进单核体菌丝的生长,最适添加比例为2%。将Y0040-1和Y0040-3在PDA和2%木屑PDA上培养后进行转录组表达谱差异分析,结果显示Y0040-1和Y0040-3两个单核菌株在木屑-PDA培养基上生长有 1 066个共有的差异表达基因,进一步对其注释发现,这些差异基因在细胞结构合成以及碳水化合物代谢等途径上得到富集。同时1 066个共有的差异基因中有113个共上调,富集于氧化还原反应,267个共下调主要富集于蛋白质折叠和去折叠等途径。进一步对1 066个差异基因进行CAZYmes家族和木质纤维素酶分析,发现有36个家族基因差异表达,包括了4个多铜氧化酶、 6个β-葡萄糖苷酶和2个内β-1,4-葡聚糖酶,其中多铜氧化酶基因表达在木屑培养基上都显著上升。木质纤维素降解酶基于氧化还原反应等将木质素降解为菌丝体生长发育所必需的小分子单糖,可能是木屑PDA培养基促进菌丝生长的原因之一。     

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.     

香菇菌丝后熟转色的转录组分析

香菇是世界第二大栽培食用菌,其菌丝后熟转色是其特有的栽培过程,并对其产量和品质至关重要.为了进一步了解香菇后熟转色形成的机制,本研究利用Illumina二代高通量测序平台,对初始未转色菌丝(LE 118)、光照下转色菌丝(LE313C)、黑暗下未转色菌丝(LE313W)进行转录组测序,以香菇单核体W1-26基因组为参考...