培菌白蚁菌圃微生物降解木质纤维素的研究进展

白蚁及其共生微生物协同降解植物细胞壁的机理一直被世界各国科学家所关注。培菌白蚁作为高等白蚁,相比低等食木白蚁具有更多样化的食性,其利用外共生系统“菌圃”,对多种植物材料进行处理。本文综述了菌圃微生物降解木质纤维素的研究进展,以期为深入研究菌圃中木质纤维素降解过程及其机制,并挖掘利用菌圃降解木质纤维素的能力及仿生模拟菌圃开发新的生物质利用系统提供参考。培 菌白蚁在其巢内利用由植物材料修建的多孔海绵状结构——“菌圃”来培养共生真菌鸡枞菌Termitomyces spp.,形成了独特的木质纤维素食物降解和消化策略,使木质纤维素在培菌白蚁及其共生微生物协同作用下被逐步降解。幼年工蚁取食菌圃上的共生真菌菌丝组成的小白球和老年工蚁觅得食物并排出粪便堆积到菌圃上成为上层菌圃。这一过程中,被幼年工蚁取食的共生真菌释放木质素降解酶对包裹在植物多糖外部的木质素屏障进行解聚。菌圃微生物(包括共生真菌)对解聚的木质素基团进一步降解,将多糖长链或主链剪切成短链,使菌圃基质自下而上被逐步降解。最后下层的老熟菌圃被老年工蚁取食,其中肠的内源酶系及后肠微生物将这些短链进一步剪切和利用。因此,蚁巢菌圃及其微生物是培菌白蚁高效转化利用木质纤维素的基础。化学层面的研究表明,菌圃能够实现对植物次生物质解毒和植 物纤维化学结构解构。对共生真菌相关酶系的研究显示可能其在菌圃的植物纤维化学结构和植物次生物质的降解中发挥了作用,但不同属共生真菌间其效率和具体功能不尽相同。而菌圃中的细菌是否发挥了作用和哪些细菌类群发挥了作用等仍有待进一步的研究。相比于低等食木白蚁利用其后肠共生微生物降解木质纤维素,培菌白蚁利用菌圃降解木质纤维素具有非厌氧和能处理多种类型食物两大优势,仿生模拟菌圃降解木质纤维素的机制对林地表面枯枝落叶的资源化利用具有重要意义。     

基于Illumina MiSeq高通量测序技术分析硇洲岛海星共附生微生物多样性

【背景】海星作为海洋生物中的一类比较高级的棘皮类动物,其体内蕴藏着丰富且具有生物活性的共附生微生物资源。【目的】分析湛江硇洲岛海星中共附生微生物的多样性。【方法】采用IlluminaMiSeq高通量测序技术分别对硇洲岛海星进行共附生细菌16SrRNA基因V3-V4区和共附生真菌18S rRNA基因ITS1-ITS2区的测序,并根据测序结果进行OTU聚类分析、α多样性分析及物种分类分析等。【结果】高通量测序获得细菌和真菌Filtered的数目分别为61992和71196个,OTU数目分别为2384和529个。经物种分类分析,共附生细菌主要为变形菌门(Proteobacteria),其平均相对含量高达77.37%;其次是厚壁菌门(Firmicutes)、拟杆菌门(Bacteroidetes)、放线菌门(Actinobacteria)和梭杆菌门(Fusobacteria);其中优势细菌属为嗜冷杆菌属(Psychrobacter)和乳球菌属(Lactococcus)。共附生真菌主要为子囊菌门(Ascomycota),其相对含量高达92.33%;其次是霉菌门(Fungi)、担子菌门(Basidiomycota)、被孢菌门(Mortierellomycota)和罗兹菌门(Rozellomycota);优势真菌属以毕赤酵母属(Pichia)为主,未经分类的(unclassified)假丝酵母属(Candida)次之;【结论】硇洲岛海星体内蕴藏着丰富的共附生微生物资源,该研究为今后从事海星微生物资源持续开发和挖掘生物活性物质的研究提供一定的参考依据。     

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.     

高通量测序分析DNA提取引起的对虾肠道菌群结构偏差

【目的】通过高通量测序技术,评价不同DNA试剂盒提取引起的对虾肠道菌群结构偏差,了解健康凡纳滨对虾肠道菌群结构特征。【方法】分别以细菌、粪便和组织DNA试剂盒3次重复提取凡纳滨对虾肠道总DNA(分别编号为SIB,SIS和SIT),检测DNA含量、纯度及其16S r DNA V4区可扩增性,进一步采用Illumina Mi Seq高通量测序比较SIB和SIS样品菌群组成和多样性。【结果】细菌试剂盒提取的虾肠总DNA效果最好,粪便试剂盒次之,而组织试剂盒所提DNA含量低且难以被扩增。从SIB和SIS样品分别获得52151±5085和55296±5147条有效序列,同一(46800条)测序深度下,SIS样品OTU(operational taxonomic unit)数量和Shannon多样性指数均显著高于SIB的,而SIB样品间OTU重复性则优于SIS样品间的。从SIB和SIS样品鉴定的优势门一致,均包括变形菌门(Proteobacteria)、厚壁菌门(Firmicutes)、拟杆菌门(Bacteroidetes)、浮霉菌门(Planctomycetes)、放线菌门(Actinobacteria)和蓝细菌门(Cyanobacteria),但不同分类水平上绝大多数优势菌群丰度在两种样品间差异明显。【结论】高通量测序分析表明对虾肠道菌群结构因DNA提取方法不同而呈现显著偏差;本研究健康凡纳滨对虾肠道核心菌群主要由发光杆菌属(Photobacterium),乳球菌属(Lactococcus),弧菌属(Vibrio),Aliivibrio和3个分类未定属构成。     

基于高通量测序的褐飞虱肠道微生物多样性分析

【目的】探明褐飞虱Nilaparvata lugens成虫肠道微生物群落结构和多样性。【方法】分离褐飞虱成虫完整肠道并提取总DNA,利用Illumina MiSeq(PE300)技术对其肠道细菌16S rRNA的V3-V4变异区和真菌ITS2序列进行测序,统计肠道微生物的操作分类单元(operational taxonomic unit, OTU)数量,分析其物种组成、丰度及Alpha多样性。并通过qPCR技术验证随机挑选注释到的4种肠道菌的高通量测序数据的有效性。【结果】分别获得褐飞虱成虫肠道细菌16S rRNA和真菌ITS2优质序列32 395和24 986条,根据序列相似性进行聚类分析分别获得235和128个OTUs。其中,细菌共注释到7个门, 15个纲, 26个目, 45个科和73个属;真菌共鉴定到3个门, 9个纲, 12个目, 15个科和18个属。在门分类水平上,细菌以变形菌门(Proteobacteria)、拟杆菌门(Bacteroidetes)和厚壁菌门(Firmicutes)为优势门类;真菌以子囊菌门(Ascomycota)为绝对优势菌门。在属分类水平上,细菌的优势属为不动杆菌属Acinetobacter以及紫单胞菌科(Porphyromonadaceae)未确定属和毛螺菌科(Lachnospiraceae)未确定属,其丰度分别为36.37%, 17.22%和15.01%;真菌的优势属为粪壳菌纲(Sordariomycetes)未确定属,丰度为95.77%。Alpha多样性分析结果显示,褐飞虱肠道细菌(真菌)的观测物种数、Chao1指数、Shannon指数和Simpson 指数分别为235(128), 262.64(165.40), 3.90(0.91)和0.62(0.75)。4种肠道菌的qPCR结果显示高通量测序数据具有较高的有效性。【结论】褐飞虱成虫肠道细菌和真菌群落整体多样性比较丰富。研究结果为从共生微生物角度解析褐飞虱的环境适应性以及开发基于微生物防治的新技术等方面提供了依据。     

鸡枞菌转录组分析揭示其对木质纤维素的降解功能

【目的】探究鸡枞菌是否能降解木质纤维素成分,并理解其与共生白蚁之间的共生关系。【方法】本研究是应用新一代高通量测序技术454 GS FLX Titanium对鸡枞菌的转录组进行测序,挖掘鸡枞菌中能参与降解纤维素和木质素等成分的多样性酶系。【结果】八分之一的RUN测序总共得到了82386条表达序列标签,去除引物和载体等序列后,剩余的54410条序列被拼接成3301条contigs以及3193条singletons。根据序列相似性,将这些unigenes与三大蛋白数据库(Nr数据库、SwissProt数据库、CDD数据库)中的蛋白序列进行BLAST比较,发现有2681条基因与其他生物的已知基因有不同程度的相似性。在鸡枞菌的这些转录产物中,有33条编码可能参与降解纤维素或半纤维素的酶基因,其中包括5种纤维素酶以及28种水解半纤维素、淀粉或几丁质等物质的酶类。更重要的是,还发现了4种漆酶以及一种芳基乙醇氧化酶基因,这些都是能有效降解木质素的酶类。这些结果揭示了鸡枞菌中存在漆酶并可能有效降解植物残渣中的酚化合物。【结论】这些基因的发现说明了鸡枞菌能降解木质素,并能与共生白蚁分泌的纤维素酶协同作用有效降解纤维素。     

云南干巴菌子实体内可培养微生物

【背景】微生物在菌根真菌的孢子萌发、菌丝体生长、菌根形成以及子实体发育等过程中起到一定作用。【目的】对采自云南省昆明市嵩明县和楚雄彝族自治州禄丰县的8个干巴菌子实体内的微生物进行分离培养鉴定,为后期研究微生物与干巴菌之间的相互作用奠定基础。【方法】采用传统平板分离法从干巴菌子实体内分离获得微生物群落,t检验分析不同地区采集的干巴菌子实体内微生物菌落总数的差异,16S r RNA基因和ITS序列进行系统发育树构建和微生物多样性分析。【结果】采自嵩明县和禄丰县的8个干巴菌子实体内共分离获得282株可培养的细菌,两个地区的细菌菌落总数无显著差异(P=0.22)。所有细菌分属2门12属15种。其中80%的细菌属于变形菌门,且以γ-变形菌为优势菌群,假单胞菌属(Pseudomonas)为优势菌属。其余20%的细菌属于拟杆菌门。从干巴菌子实体中分离获得114株真菌,两个地区的真菌菌落总数无显著差异(P=0.65)。所有真菌分属2门10属10种。其中62%的真菌属于子囊菌门(Ascomycota),并以分离自禄丰县干巴菌子实体内的Lophiostoma为优势属。38%的真菌属于担子菌门(Basidiomycota),并以Asterotremella为优势属。【结论】两个不同地区采集的干巴菌子实体内细菌和真菌在菌落总数上无显著差异。所有细菌都以γ-变形菌为优势菌群,假单胞菌属为优势菌属。嵩明干巴菌子实体内真菌以担子菌门为优势菌群,Asterotremella为优势属。而禄丰干巴菌子实体内真菌则以子囊菌门为优势菌群,Lophiostoma为优势属。     

传统醋曲储存过程中的微生物多样性

【背景】醋曲是我国传统谷物醋酿造中的重要微生物来源,通常一次制备分批使用。【目的】解析传统醋曲储存过程中微生物群落结构变化规律。【方法】从山西晋南一家百年老醋坊分别采集大曲原料、新制醋曲、储存7个月和12个月的醋曲,利用高通量测序技术分析微生物多样性。【结果】从4组样品中共找到610个真菌可操作分类单元(operational taxonomic unit, OTU)和747个细菌OTU。子囊菌门(Ascomycota,占比95%)和厚壁菌门(Firmicutes,占比81%)分别为优势的真菌和细菌类群。醋曲成品中约1/3的真菌OTU和约95%的细菌OTU可在醋曲原料中找到,说明原料是醋曲的重要微生物来源。相较于新制醋曲,储存7个月和12个月醋曲中的真菌和细菌多样性均显著降低。醋曲贮存过程中微生物群落结构发生明显改变,并且相较于真菌群落结构,细菌群落结构更易波动。相较于醋曲原料,醋曲成品中显著富集扣囊复膜孢酵母(Saccharomycopsis fibuligera)、东方伊萨酵母(Issatchenkiaorientalis)等真菌,以及克罗彭斯特菌属(Kroppenstedtia)...     

基于高通量测序研究青藏高原茶卡盐湖微生物多样性

【目的】茶卡盐湖(Chaka Salt Lake,CSL)是青藏高原有名的天然结晶盐湖,具有独特的石盐盐湖矿床,盛产青盐。盐湖卤水环境中存在丰富的嗜盐菌资源和潜在的新种,细菌和古菌的群落结构特征和物种多样性尚不明确。【方法】采用Illumina高通量测序平台对茶卡盐湖水样和底泥混合物中的细菌和古菌群落进行16S r RNA基因(V3-V5区)高通量测序,检测4个样本的群落结构差异和微生物多样性。【结果】获得细菌和古菌总有效序列分别为117 192和110 571条。结果分析表明细菌和古菌的物种注释(Operational taxonomic unit,OTU)数目分别为421和317,获得分类地位明确的细菌种类为14门28纲170属,古菌为5门4纲34属。细菌的优势类群是厚壁菌门(Firmicutes),所占比例为68.37%,其次为变形菌门Proteobacteria(20.49%);优势种属依次为芽孢杆菌属Bacillus(41.94%)、海洋芽孢杆菌属Oceanobacillus(8.03%)、假单胞菌属Pseudomonas(7.67%)、盐厌氧菌属Halanaerobium(7.42%)和乳球菌属Lactococcus(7.38%);古菌的优势类群以广古菌门(Euryarchaeota)盐杆菌纲(Halobacteria)为主,优势菌是Halonotius(17.21%)和盐红菌属Halorubrum(16.23%)。【结论】揭示了茶卡盐湖中细菌和古菌的群落结构及物种多样性,为嗜盐菌的开发及后续微生物资源的挖掘提供了理论依据。     

白蜡虫蜡花微生物多样性分析

【目的】探究白蜡虫Ericerus pela(Chavannes)雄若虫分泌的蜡花中微生物的多样性,比较不同厚度蜡花(随雄若虫发育蜡质层厚度增加)中细菌及真菌的种类和变化。【方法】采用Mi Seq高通量测序方法对不同发育阶段白蜡虫雄若虫分泌的蜡花中细菌16S rRNA和真菌ITS进行测序,利用Mothur软件计算蜡花中细菌和真菌的操作分类单元(operational taxonomic unit,OTU)及其丰富度、Alpha多样性分析。【结果】细菌3个样品共获470个OTU,真菌2个样品共获264个OTU。细菌共鉴定出18门30纲92科173属;真菌共鉴定出3门15纲43科68属。其中丛毛单胞菌属Comamonas细菌在蜡花中为优势菌,分别占前、中、后期雄若虫分泌的蜡花中细菌总量的79.79%,41.61%和46.86%;枝胞属Cladosporium在前期雄若虫分泌的蜡花中占真菌总量的17.01%,隐球菌属Cryptococcus在后期雄若虫分泌的蜡花中占真菌总量的60.84%,是蜡花中真菌重要组成部分。【结论】不同发育阶段雄若虫分泌的蜡花中细菌及真菌群落存在差异,随着蜡花厚度增加,细菌多样性先增加后减少,而真菌多样性降低。     

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。     

Comparison of gut-associated and nest-associated microbial communities of a fungus-growing termite (Odontotermes yunnanensis)

Abstract The digestion of cellulose by fungus-growing termites involves a complex of different organisms, such as the termites themselves, fungi and bacteria. To further investigate the symbiotic relationships of fungus-growing termites, the microbial communities of the termite gut and fungus combs of Odontotermes yunnanensis were examined. The major fungus species was identified as Termitomyces sp. To compare the micro-organism diversity between the digestive tract of termites and fungus combs, four polymerase chain reaction clone libraries were created (two fungus-targeted internal transcribed spacer [ITS]– ribosomal DNA [rDNA] libraries and two bacteria-targeted 16S rDNA libraries), and one library of each type was produced for the host termite gut and the symbiotic fungus comb. Results of the fungal clone libraries revealed that only Termitomyces sp. was detected on the fungus comb; no non-Termitomyces fungi were detected. Meanwhile, the same fungus was also found in the termite gut. The bacterial clone libraries showed higher numbers and greater diversity of bacteria in the termite gut than in the fungus comb. Both bacterial clone libraries from the insect gut included Firmicutes, Bacteroidetes, Proteobacteria, Spirochaetes, Nitrospira, Deferribacteres, and Fibrobacteres, whereas the bacterial clone libraries from the fungal comb only contained Firmicutes, Bacteroidetes, Proteobacteria, and Acidobacteris.     

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.     

白蚁巢菌圃真菌多样性研究

培菌性白蚁能在存在于蚁巢或分散在其周围土壤中的菌圃上培养真菌。菌圃在无白蚁存在下培养会生长出炭角菌的子实体。对分别采集自我国西南四川、云南两省的4个土白蚁属菌圃采用原位培养法分离并纯化得到40株炭角菌,划分为13个形态型,ITS1-5.8S-ITS2序列分析确定为两种炭角菌。采用建立ITS基因文库的方法分析了白蚁菌圃真菌群落多样性,结果表明有白蚁存在的菌圃,蚁巢伞为单一优势菌;废弃的蚁巢中的菌圃,木霉、炭角菌等其他真菌成为优势菌。     

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.     

Symbiotic fungi produce laccases potentially involved in phenol degradation in fungus combs of fungus-growing termites in Thailand

Fungus-growing termites efficiently decompose plant litter through their symbiotic relationship with basidiomycete fungi of the genus Termitomyces. Here, we investigated phenol-oxidizing enzymes in symbiotic fungi and fungus combs (a substrate used to cultivate symbiotic fungi) from termites belonging to the genera Macrotermes, Odontotermes, and Microtermes in Thailand, because these enzymes are potentially involved in the degradation of phenolic compounds during fungus comb aging. Laccase activity was detected in all the fungus combs examined as well as in the culture supernatants of isolated symbiotic fungi. Conversely, no peroxidase activity was detected in any of the fungus combs or the symbiotic fungal cultures. The laccase cDNA fragments were amplified directly from RNA extracted from fungus combs of five termite species and a fungal isolate using degenerate primers targeting conserved copper binding domains of basidiomycete laccases, resulting in a total of 13 putative laccase cDNA sequences being identified. The full-length sequences of the laccase cDNA and the corresponding gene, lcc1-2, were identified from the fungus comb of Macrotermes gilvus and a Termitomyces strain isolated from the same fungus comb, respectively. Partial purification of laccase from the fungus comb showed that the lcc1-2 gene product was a dominant laccase in the fungus comb. These findings indicate that the symbiotic fungus secretes laccase to the fungus comb. In addition to laccase, we report novel genes that showed a significant similarity with fungal laccases, but the gene product lacked laccase activity. Interestingly, these genes were highly expressed in symbiotic fungi of all the termite hosts examined.     

Fungus-growing termites originated in African rain forest

Fungus-growing termites (subfamily Macrotermitinae, Isoptera) cultivate fungal crops (genus Termitomyces, Basidiomycotina) in gardens inside their colonies. Those fungus gardens are continuously provided with plant substrates, whereas older parts that have been well decomposed by the fungus are consumed (cf.). Fungus-growing termites are found throughout the Old World tropics, in rain forests and savannas, but are ecologically dominant in savannas. Here, we reconstruct the ancestral habitat and geographical origin of fungus-growing termites. We used a statistical model of habitat switching repeated over all phylogenetic trees sampled in a Bayesian analysis of molecular data. Our reconstructions provide strong evidence that termite agriculture originated in African rain forest and that the main radiation leading to the extant genera occurred there. Because extant savanna species are found in most genera, this moreover suggests that the savanna has repeatedly been colonized by fungus-growing termites. Furthermore, at least four independent "out-of-Africa" migrations into Asia, and at least one independent migration to Madagascar, have occurred. Although fungus growing by termites is ecologically most successful under the variable, unfavorable conditions of the savanna, it seems to have evolved under the more constant and favorable conditions of the rain forest.     

Exploring the Potential for Actinobacteria as Defensive Symbionts in Fungus-Growing Termites

In fungus-growing termites, fungi of the subgenus Pseudoxylaria threaten colony health through substrate competition with the termite fungus (Termitomyces). The potential mechanisms with which termites suppress Pseudoxylaria have remained unknown. Here we explore if Actinobacteria potentially play a role as defensive symbionts against Pseudoxylaria in fungus-growing termites. We sampled for Actinobacteria from 30 fungus-growing termite colonies, spanning the three main termite genera and two geographically distant sites. Our isolations yielded 360 Actinobacteria, from which we selected subsets for morphological (288 isolates, grouped in 44 morphotypes) and for 16S rRNA (35 isolates, spanning the majority of morphotypes) characterisation. Actinobacteria were found throughout all sampled nests and colony parts and, phylogenetically, they are interspersed with Actinobacteria from origins other than fungus-growing termites, indicating lack of specificity. Antibiotic-activity screening of 288 isolates against the fungal cultivar and competitor revealed that most of the Actinobacteria-produced molecules with antifungal activity. A more detailed bioassay on 53 isolates, to test the specificity of antibiotics, showed that many Actinobacteria inhibit both Pseudoxylaria and Termitomyces, and that the cultivar fungus generally is more susceptible to inhibition than the competitor. This suggests that either defensive symbionts are not present in the system or that they, if present, represent a subset of the community isolated. If so, the antibiotics must be used in a targeted fashion, being applied to specific areas by the termites. We describe the first discovery of an assembly of antibiotic-producing Actinobacteria occurring in fungus-growing termite nests. However, due to the diversity found, and the lack of both phylogenetic and bioactivity specificity, further work is necessary for a better understanding of the putative role of antibiotic-producing bacteria in the fungus-growing termite mutualistic system.     

Microbial community analysis in the termite gut and fungus comb of Odontotermes formosanus: the implication of Bacillus as mutualists

The microbial communities harbored in the gut and fungus comb of the fungus-growing termite Odontotermes formosanus were analyzed by both culture-dependent and culture-independent methods to better understand the community structure of their microflora. The microorganisms detected by denaturing gradient gel electrophoresis (DGGE), clonal selection, and culture-dependent methods were hypothesized to contribute to cellulose-hemicellulose hydrolysis, gut fermentation, nutrient production, the breakdown of the fungus comb and the initiation of the growth of the symbiotic fungus Termitomyces. The predominant bacterial cultivars isolated by the cultural approach belonged to the genus Bacillus (Phylum Firmicutes). Apart from their function in lignocellulosic degradation, the Bacillus isolates suppressed the growth of the microfungus Trichoderma harzianum (genus Hypocrea), which grew voraciously on the fungus comb in the absence of termites but grew in harmony with the symbiotic fungus Termitomyces. The in vitro studies suggested that the Bacillus sp. may function as mutualists in the termite-gut-fungus-comb microbial ecosystem.     

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.