蚁巢伞的活性物质与营养成分

蚁巢伞属的种类与大白蚁亚科白蚁专一性共生,是一类著名的美味食用菌,亦具有重 要的药用价值,极具开发利用前景.该文综述了蚁巢伞的食用和药用价值、营养成分和活性 物质研究,以及其在食品工业及保健方面的应用现状.对现有研究中存在的问题进行了论述 ,并展望了蚁巢伞属菌物在生物技术产业中的应用前景,为蚁巢伞的进一步开发研究提供参考.     

白蚁与动物及微生物的共生类型及其机制

综述了白蚁螱客的主要种类、共生关系及相关机制的研究进展。白蚁螱客中,已报道的动物种类达170种。在与动物的共生关系中存在偏利共生（宾主共栖和异种共栖）、互利共生和无关共生三种;在与微生物的共生关系中,存在与内生菌（原生动物、细菌、真菌和放线菌）和外生菌（蚁巢伞菌等）间的互利关系。指出了白蚁与螱客研究中存在的问题,给出了解决方案,并提出了今后可能的研究热点或方向,为白蚁的综合利用（如纤维素酶）及今后研究物种间的协同进化提供了基础资料。     

蚁巢伞属真菌研究进展

从蚁巢伞属真菌的分类鉴定、活性成分、生长培养及与宿主白蚁共生关系等方面进行综述。其中包括对近年来相关研究成果的总结,指出其中存在的问题,对蚁巢伞属真菌的研究前景进行展望。     

白蚁共生放线菌研究进展

白蚁与微生物的共生关系是目前较受关注的研究热点,其肠道及巢内的共生微生物在降解木质纤维素的过程中扮演着重要的角色。放线菌是这些共生微生物中的重要一类,广泛存在于肠道、蚁巢及其周围土壤中,目前已探明共生放线菌在参与白蚁碳氮循环及保护巢群免受外来病菌侵染等方面发挥着极大的作用。近年来,人们利用分子生物学技术鉴定了部分共生放线菌的类群,发现了许多具应用前景的新放线菌及相关酶和代谢产物。因此,研究与白蚁相关的放线菌不仅有助于人们了解白蚁共生菌群落间的互作及其与宿主间的关系,而且对人类开发自然资源也有较大的帮助。本文对白蚁共生放线菌的研究进展作一综述,供同行参考。     

大白蚁属Macrotermes分子研究进展

大白蚁属Macrotermes是等翅目白蚁科大白蚁亚科(Isoptera: Termitidae: Macrotermitinae)中的一类高等培菌白蚁。本文综述了1996年来有关大白蚁属分子研究的文章,提供了截止目前大白蚁属Macrotermes 生物学信息,并分析了目前大白蚁属的分子研究现状,含等翅目系统关系,大白蚁属种间关系,大白蚁拟工蚁与食性演变,大白蚁属与其共生菌关系,及其分子研究的发展方向,特别是中国大白蚁属分子研究现状。     

白蚁共生真菌——蚁巢伞属研究概况

蚁巢伞属真菌是一类极具市场开发价值的野生食用真菌。本文对蚁巢伞属真菌的分类、与白蚁的共生关系、活性成分和作用、人工培养研究以及产生的相关木质纤维素降解酶类等方面进行综述,总结了近年来该属真菌的研究现状,指出了研究过程中出现的分类混乱、重名异名现象严重等问题,展望了未来有望开发菌丝体相关产品及深化出菇机制以逐步实现蚁巢伞人工栽培的研究方向,以期为未来的研究提供依据。     

白蚁及共生微生物木质纤维素水解酶的种类

白蚁是热带生态系统重要的木质纤维素降解者。白蚁种类丰富,可分成高等白蚁和低等白蚁,食性也具有各自特点。白蚁自身可以产生纤维素酶,主要是GHF9的内切葡聚糖酶(EG),也有β-葡萄糖苷酶(GB)。低等白蚁共生的原虫中已发现丰富的纤维素酶基因,属于GHF5,7和45。同时还有其他相关功能基因,如木聚糖酶和果胶类物质水解酶。高等白蚁肠道中没有共生原虫。高等培菌白蚁可以利用共生蚁巢伞属真菌促进木质纤维素降解,真菌可以产生纤维素酶,果胶质水解酶类、木聚糖酶,同时还产生可能与木质素分解相关的一种漆酶,但是从分子水平,关于共生真菌纤维素水解酶的研究还较少。白蚁肠道已分离出许多具有木质纤维素降解能力的菌株,最近的研究也发现了大量细菌纤维素酶基因。白蚁-共生系统丰富的木质纤维素水解酶类为发展生物方法开发纤维素乙醇这一思路提供有价值的资源。     

培菌白蚁与鸡枞菌研究进展

培菌白蚁起源于非洲,蚁巢内具有复杂的社会分工.培菌白蚁依靠独特的蚁巢结构维持内部稳态和气体循环.菌圃是白蚁培育鸡枞菌的场所.鸡枞菌隶属于担子菌亚门,但其传播方式和生活史具有区别于其它担子菌的特点.鸡枞菌协助白蚁进行植物纤维的消化,白蚁则为鸡枞菌提供合适的生长环境,并控制鸡枞菌的遗传结构.培菌白蚁和鸡枞菌形成紧密的共生关系,二者缺少任何一方都不能独立生存.本文综述了培菌白蚁的分类、品级、蚁巢结构,鸡枞菌的传播方式和生活史,白蚁与鸡枞菌的共生关系等,以期望为培菌白蚁生物学及鸡枞菌的研究提供有益参考.     

白蚁的蚁客

<正> 白蚁是一类多型的、营社会生活的昆虫。白蚁巢内部常能发现许多蚁客(Termitophiles)。较低等的、蚁巢结构较简单的白蚁,其蚁客的种类和数量较少;而高等的、蚁巢结构复杂、特别是具有菌圃的蚁巢,其中蚁客的种类和数量也较多。 作者近年来(1975—1979)在浙江有关地区白蚁防治单位的协助下,自尖叉原白蚁、黑胸散白蚁、家白蚁、屏南象白蚁、黑翅土白蚁及黄翅大白蚁等6种蚁巢内,采集到30多种蚁客。经初步鉴定,它们隶属于节肢动物门中3个纲、9个目、16个科。其中以昆虫纲的种类最为丰     

白蚁菌圃真菌多样性研究进展

白蚁菌圃存在于白蚁巢中,具有硬而脆的多孔结构,是特殊的真菌生存环境。当有白蚁在白蚁巢内活动时,蚁巢伞Termitomyces是菌圃上的优势菌;当白蚁巢被废弃,炭角菌Xylaria成为菌圃上的优势真菌。菌圃中还存在其他微生物如无性型真菌（anamorphic fungi）和酵母等。菌圃中的真菌很多具有潜在药用价值或其他经济价值。从蚁巢伞、炭角菌等主要真菌类群出发,结合分子生态学研究菌圃真菌多样性的方法,综述了白蚁菌圃真菌多样性的研究进展,揭示了目前的研究热点及存在的问题,并针对这些问题提出可能的发展方向。     

Phylogenetic relationships in Termitomyces (Family Agaricaceae) based on the nucleotide sequence of ITS: a first approach to elucidate the evolutionary history of the symbiosis between fungus-growing termites and their fungi

Termitomyces constitutes a very poorly known genus of fungi whose essential characteristic is that all representatives of the genus are cultivated by termites (Macrotermitinae) in their nest and that all the fungi cultivated by termites belong to this genus. For the first time, the phylogenetic relationships of several African Termitomyces species was studied by the sequencing of their internal transcriber spacer region (ITS1--5.8S--ITS2). It appeared that this group is clearly monophyletic and belongs to the Tricholomataceae family. The total homology of the ITS zone of several Termitomyces symbionts of different termite genera indicated that the specific diversity of this group is in fact less important than previously supposed. Finally, the comparison between the Termitomyces phylogenetic tree and the taxonomic tree of Macrotermitinae showed that if for certain genera the hypothesis of termite/fungus coevolution is acceptable, it should not be applied for all symbiosis.     

Levels of specificity of Xylaria species associated with fungus-growing termites: a phylogenetic approach

Fungus-growing termites live in obligate mutualistic symbiosis with species of the basidiomycete genus Termitomyces , which are cultivated on a substrate of dead plant material. When the termite colony dies, or when nest material is incubated without termites in the laboratory, fruiting bodies of the ascomycete genus Xylaria appear and rapidly cover the fungus garden. This raises the question whether certain Xylaria species are specialised in occupying termite nests or whether they are just occasional visitors. We tested Xylaria specificity at four levels: (1) fungus-growing termites, (2) termite genera, (3) termite species, and (4) colonies. In South Africa, 108 colonies of eight termite species from three termite genera were sampled for Xylaria . Xylaria was isolated from 69% of the sampled nests and from 57% of the incubated fungus comb samples, confirming high prevalence. Phylogenetic analysis of the ITS region revealed 16 operational taxonomic units of Xylaria , indicating high levels of Xylaria species richness. Not much of this variation was explained by termite genus, species, or colony; thus, at level 2–4 the specificity is low. Analysis of the large subunit rDNA region, showed that all termite-associated Xylaria belong to a single clade, together with only three of the 26 non-termite-associated strains. Termite-associated Xylaria thus show specificity for fungus-growing termites (level 1). We did not find evidence for geographic or temporal structuring in these Xylaria phylogenies. Based on our results, we conclude that termite-associated Xylaria are specific for fungus-growing termites, without having specificity for lower taxonomic levels.     

Genetic variation of symbiotic fungi cultivated by the macrotermitine termite Odontotermes formosanus (Isoptera: Termitidae) in the Ryukyu Archipelago

Fungus-growing termites have a mutualistic relationship with their cultivated fungi. To improve understanding of genetic aspects of this relationship, we examined molecular markers in the fungus-growing termite Odontotermes formosanus and its fungi Termitomyces spp. from the Ryukyu Archipelago. Based on the polymorphic band patterns obtained from arbitrarily primed polymerase chain reaction methods, we constructed cladograms for related colonies of the termites and fungi. The resulting trees indicated that the termites display little genetic variation among the colonies, while the symbiotic fungi consist of two major genetic types. In addition, molecular phylogenetic trees of the symbiotic fungi based on internal transcribed spacer and 18S rDNA suggested that these two types of fungi are different species. We also demonstrated that the fungi comprising the fruiting bodies and fungus combs are identical, and that fungus combs are probably a monoculture within a single termite colony. Our results indicate that horizontal transmission of symbiotic fungi among termite colonies occurred during the evolutionary history of this symbiosis.     

Identifying the core microbial community in the gut of fungus‐growing termites

Gut microbes play a crucial role in decomposing lignocellulose to fuel termite societies, with protists in the lower termites and prokaryotes in the higher termites providing these services. However, a single basal subfamily of the higher termites, the Macrotermitinae, also domesticated a plant biomass‐degrading fungus (Termitomyces), and how this symbiont acquisition has affected the fungus‐growing termite gut microbiota has remained unclear. The objective of our study was to compare the intestinal bacterial communities of five genera (nine species) of fungus‐growing termites to establish whether or not an ancestral core microbiota has been maintained and characterizes extant lineages. Using 454‐pyrosequencing of the 16S rRNA gene, we show that gut communities have representatives of 26 bacterial phyla and are dominated by Firmicutes, Bacteroidetes, Spirochaetes, Proteobacteria and Synergistetes. A set of 42 genus‐level taxa was present in all termite species and accounted for 56–68% of the species‐specific reads. Gut communities of termites from the same genus were more similar than distantly related species, suggesting that phylogenetic ancestry matters, possibly in connection with specific termite genus‐level ecological niches. Finally, we show that gut communities of fungus‐growing termites are similar to cockroaches, both at the bacterial phylum level and in a comparison of the core Macrotermitinae taxa abundances with representative cockroach, lower termite and higher nonfungus‐growing termites. These results suggest that the obligate association with Termitomyces has forced the bacterial gut communities of the fungus‐growing termites towards a relatively uniform composition with higher similarity to their omnivorous relatives than to more closely related termites.     

Genetic diversity of termite-egg mimicking fungi “termite balls” within the nests of termites

Antagonistic or mutualistic interactions between insects and fungi are well-known, and the mutualistic interactions of fungus-growing ants, fungus-growing termites, and fungus-gardening beetles with their respective fungal mutualists are model examples of coevolution. However, our understanding of coevolutionary interactions between insects and fungi has been based on a few model systems. Fungal mimicry of termite eggs is one of the most striking evolutionary consequences of insect–fungus associations. This novel termite–fungus interaction is a good model system to compare with the relatively well-studied systems of fungus-growing ants and termites because termite egg-mimicking fungi are protected in the nests of social insects, as are fungi cultivated by fungus-growing ants and termites. Recently, among systems of fungus-growing ants and termites, much attention has been focused on common factors including monoculture system for the ultimate evolutionary stability of mutualism. We examined the genetic diversity of termite egg-mimicking fungi within host termite nests. RFLP analysis demonstrated that termite nests were often infected by multiple strains of termite egg-mimicking fungi, in contrast to single-strain monocultures in fungus combs of fungus-growing ants and termites. Additionally, phylogenetic analyses indicated the existence of a free-living stage of the termite egg-mimicking fungus as well as frequent long-distance gene flow by spores and subsequent horizontal transmission. Comparisons of these results with previous studies of fungus-growing ants and termites suggest that the level of genetic diversity of fungal symbionts within social insect nests may be important in shaping the outcome of the coevolutionary interaction, despite the fact that the mechanism for achieving genetic diversity varies with the evolutionary histories of the component species.     

Open relationships in the castles of clay: high diversity and low host specificity of Termitomyces fungi associated with fungus-growing termites in Africa

In the African and Asian tropics, termites of the subfamily Macrotermitinae play a major role in the decomposition of dead plant material. Their ecological success lies in the obligate mutualism of the termites with fungi of the genus Termitomyces. Before the advent of molecular studies, the interaction with these fungi was poorly understood. Here, we combined available ITS sequence data from West, Central, and South Africa with data of 39 new samples from East Africa to achieve the most comprehensive view of the diversity and host specificity of Termitomyces symbionts across Africa to date. A high amount of sequence divergence in the ITS sequences was found; 11 different Termitomyces lineages in East Africa and >30 lineages across Africa were identified, and the expected diversity is estimated to be about 41 lineages. The fungal lineages belong to four major clades, each almost exclusively associated with one termite host genus. Analysis of molecular variance revealed that 40% of the ITS sequence variation occurred between host genera, indicating close co-evolution at this level. However, within host genera, fungal lineages and haplotypes were frequently shared among host species and sampling localities, except for fungal symbionts of Odontotermes. Horizontal transmission of fungal symbionts may facilitate the transfer of haplotypes and species among hosts. However, at present, we have little understanding of the maintenance of specificity at the genus level. Possible explanations range from substrate specificity of fungi to an active selection of fungi by termites.     

Lignocellulose degradation by microorganisms from termite hills and termite guts: A survey on the present state of art

Abstract: In several aspects termites are a fascinating group of insects having attracted the interest of many researchers. They exhibit a complex social behavior and caste differentiation occurring elsewhere only among the hymenoptera. In an enlarged part of the hindgut, the paunch, termites have established a unique symbiotic association with prokaryotic and eukaryotic microorganisms. A similar flora is also found in wood-eating roaches of the genus Cryptocercus . The study of symbiosis between termites and their intestinal microbes is of general interest, because due to this symbiotic interaction termites can feed on complex biopolymers such as wood. Flagellates and bacteria occur in the gut of lower termites, while higher termites possess only bacteria. In particular spirochetes are abundant in the termite gut. Apart from spirochetes and other more common bacteria, actinomycetes, yeasts and fungi have also been isolated from different species of termites. This review summarizes the distinct role of the intestinal flora in degradation of wood components such as cellulose, hemicellulose and lignin.     

Interactions between wood-inhabiting fungi and termites: a meta-analytical review

The foraging behavior and survivorship of termites are modified by the presence of wood-inhabiting fungi. Nonetheless, it is not clear if these interactions are beneficial, negative, or neutral for termites. We conducted a meta-analytical review to determine if the presence of wood-inhabiting fungi affects the foraging behavior and survivorship of termites. Overall, the presence of wood-inhabiting fungi in a resource used by termites was positive, increasing resource consumption by 120%, and aggregation behavior by 81%. The presence of fungi also increased termite trail-following by approximately 200% and increased survival by 136%. The results varied, however, according to the type of fungi evaluated. Decay fungi and sap-stain fungi elicited positive responses in termites, whereas molds did not affect the consumption of cellulose by termites. Amongst the decay fungi group, white-rot fungi caused the strongest and most positive response in all termite behaviors evaluated, although brown-rot fungi is known to be preferred by termites. The results of our study, therefore, suggest that wood-inhabiting fungi are potential facilitators of the foraging behavior and survivorship of termites. These results have great implications for termite biocontrol, as well as for knowledge of the ecological aspects of termite–fungi interactions.     

培菌白蚁菌圃和粪便微生物多样性分析

【背景】培菌白蚁是属于白蚁科的一类与鸡枞菌属真菌共生的高等白蚁,其与体内肠道微生物和体外菌圃微生物形成三维共生体系。【目的】分析培菌白蚁菌圃和粪便的微生物多样性,并与肠道微生物进行比较。【方法】通过Illumina MiSeq高通量测序方法对培菌白蚁菌圃和粪便样品进行细菌16S rRNA基因和真菌ITS测序分析。【结果】高通量测序获得培菌白蚁菌圃和粪便样品细菌和真菌的有效序列和OTU数目。5个样品细菌OTU数目在90-199之间,而真菌OTU在10-58之间,细菌的种类多样性明显大于真菌。不论是细菌还是真菌,粪便样品的OTU数目多于菌圃样品。经物种分类分析,菌圃样品主要优势细菌是变形菌门(Proteobacteria),其相对含量超过82.4%;其次是拟杆菌门(Bacteroidetes)和厚壁菌门(Firmicutes);粪便样品中优势细菌为拟杆菌门,其次是变形菌门,粪便优势菌属为别样杆菌属和营发酵单胞菌属,这与培菌白蚁肠道菌多样性组成一致。培菌白蚁菌圃和粪便样品共生真菌主要为担子菌门(Basidiomycota)和子囊菌门(Ascomycota)。菌圃优势真菌为鸡枞菌属(Termitomyces),相对含量在51.83%以上,菌圃中还鉴定到炭角菌属(1%,Xylaria)。【结论】为今后培菌白蚁-体内外微生物共生关系研究以及微生物的分离培养提供了依据和参考。