南美白对虾养殖底泥中氨氧化细菌与氨氧化古菌多态性分析

【目的】本研究皆在了解虾养殖底泥中氨氧化细菌与氨氧化古菌群落多态性。【方法】以功能基因为基础,构建氨氧化细菌(AOB)与氨氧化古菌(AOA)的氨单加氧酶α亚基基因(amoA)克隆文库。利用限制性片段长度多态性(Restriction Fragment Length Polymorphism,RFLP)技术将克隆文库阳性克隆子进行归类分析分成若干个可操作分类单元(Operational Taxa Units,OTUs)。【结果】通过序列多态性分析,表明AOB amoA基因克隆文库中所有序列都属于变形杆菌门β亚纲(β-Proteobacteria)中的亚硝化单细胞菌属(Nitrosomonas)及Nitrosomonas-like,未发现亚硝化螺旋菌属(Nitrosospira)。AOA amoA基因克隆文库中只有一个OTU序列属于未分类的古菌(Unclassified-Archaea),其余序列都属于泉古菌门(Crenarchaeote)。AOA群落结构单一且存在一个绝对优势类群OTU3,其克隆子数目占克隆文库的57.45%。AOB和AOA amoA基因克隆文库分别包括13个OTUs和9个OTUs,其文库覆盖率分别为73.47%和90.43%。AOB amoA基因克隆文库的Shannon-Wiener指数、Evenness指数、Simpson指数、Richness指数均高于AOA。【结论】虾养殖塘底泥中存在氨氧化古菌的amoA基因,且多态性低于氨氧化细菌,表明氨氧化古菌在虾养殖塘底泥的氮循环中可能具有重要的作用。     

珠三角养殖水体中参与氮循环的微生物群落结构

【目的】为了研究珠三角地区养殖水体中各种含氮化合物循环转化的特征及其相关功能微生物的群落结构。【方法】构建人工模拟养殖系统,采用15N-稳定性同位素探测技术(stable isotope probing,15N-SIP)标记参与氮素迁移的微生物,通过氯化铯-溴化乙锭密度梯度超高速离心法分离15N标记的DNA,并以此构建含15N-DNA的细菌和古菌16S rRNA基因克隆文库。【结果】15N标记的基因组DNA经过超高速密度梯度离心后成功与14N-DNA分离;对克隆文库序列的分析表明:细菌文库得到的19个可操作分类单元(Operational TaxaUnits,OTUs)分别归为变形菌门(Proteobacteria)和浮霉菌门(Planctomycetes)。变形菌门为绝对优势类群,占整个细菌克隆文库的99.2%,其中优势菌群为丛毛胞菌属(Comamonas)(15.7%)、亚硝化单胞菌属(Nitrosomonas)(12.4%)、肠杆菌科(Enterobacteriaceae)(11.5%)和硝化杆菌属(Nitrobacter)(11.5%);古菌文库得到的9个OTUs归为奇古菌门(Thaumarchaeota)、泉古菌门(Crenarchaeota)和广古菌门(Euryarchaeota)。【结论】将15N-SIP技术应用于珠三角养殖水体氮素循环微生物群落结构的研究中,得到了丰富的氮素循环微生物群落的组成,这些信息为进一步分离纯化氮素降解微生物提供了重要的参考,为营造健康的水产养殖环境提供科学依据。     

艾比湖湿地三种植物根际土壤氨氧化细菌群落的多样性

摘要:【目的】以艾比湖湿地盐节木(Halocnemum strobilaceum)、芦苇(Reed)及盐角草(Salicornia)三种植物为对象,研究其根际土壤氨氧化细菌(AOB)的群落多样性。【方法】利用PCR-RFLP的方法,构建氨氧化细菌amoA基因克隆文库,进行系统发育分析。结合三种植物根际理化因子特点,探讨三种植物根际AOB群落结构组成的特点。【结果】通过序列多态性分析表明,三种植物根际土壤AOB amoA基因克隆文库中的所有序列均属于β亚纲(β-Proteobacteria)中的亚硝化单胞菌属(Nitrosomonas)及Nitrosomonas-like,未发现亚硝化螺菌属(Nitrosospira)。三个AOB amoA基因克隆文库分别包括9个OTUs、12个OTUs和7个OTUs,其文库覆盖度均达99%以上,代表性强。三个文库的丰富度、Chao1指数、ACE指数、Shannon指数均为R＞H＞S。【结论】三种植物的AOB多样性为芦苇＞盐节木＞盐角草,并且其最优氨氧化菌群各不相同。本研究为系统认识艾比湖湿地植物根际氨氧化细菌群落多样性和结构组成提供了基础。     

固定化硝化菌群联合芽孢杆菌处理对虾养殖废水

【背景】高度集约化的对虾养殖业面临着日益严重的水污染问题,同步高效降解养殖废水中的有机物、氨氮和亚硝酸盐是对虾养殖业健康可持续发展的重要保障之一。【目的】通过分别固定化硝化菌群(Nitrifyingbacterialconsortia,NBC)和芽孢杆菌,优化菌群空间结构,提高菌群功能,实现同步高效降解对虾养殖废水中的有机物、亚硝酸盐和氨氮,保障南美白对虾养殖的可持续发展。【方法】采集养殖虾塘底泥进行硝化细菌自养富集和连续培养,利用16S rRNA基因高通量测序技术分析硝化菌群组成。从5株芽孢杆菌中筛选化学需氧量(Chemical oxygen demand,COD)降解能力最强的菌株。选用吸附和成球效果好的无毒包埋材料,通过正交实验优化固定化配方提高机械强度。选择硝化菌群和芽孢杆菌最适使用浓度进行分别固定化并联合应用于对虾养殖废水的处理。【结果】高通量分析结果显示硝化菌群中变形菌门(Proteobacteria,61.10%)占绝对优势,具有自养硝化功能的类群丰度达12.69%并呈高多样性。还包含丰度达47.44%的具有反硝化功能或者潜在反硝化功能的优势菌群和丰度达12.85%的光合细菌,是高有机负荷下硝化作用的重要补充,并可通过反硝化作用实现真正脱氮。COD降解能力最强的是解淀粉芽孢杆菌(Bacillusamyloliquefacien)YL-10,48h内COD降解率达100%。固定化最佳配方为贝壳粉5%、海藻酸钠3%、交联剂氯化钙为4%、优化后的固定化小球其机械强度可达129.68m N。固定化使硝化菌群的氨氮和亚硝酸盐降解率分别提高了128.13%和130.11%(P0.05),但对芽孢杆菌YL-10的COD降解率无明显提高。1×10~8 CFU/mL为硝化菌群和芽孢杆菌YL-10在养殖废水中最适使用浓度。在固定化硝化菌群和芽孢杆菌YL-10联合作用下,对虾养殖废水的氨氮、亚硝酸盐和COD浓度在48h内分别由初始的6.32±0.12、5.69±0.11和65.29±1.14 mg/L降至0.03±0.03、0.06±0.01和0 mg/L (P0.05),降解率分别为99.57%、99.03%和100%。【结论】通过优化固定化有效提高硝化菌群的硝化作用,联合COD降解能力强的芽孢杆菌,同步高效降解对虾养殖废水中的有机物、氨氮和亚硝酸盐,为规模化应用于南美白对虾高密度养殖提供科学依据。     

九龙江河口区nirS型反硝化细菌多样性及系统发育学分析

【目的】结合16S rRNA基因克隆文库和nirS基因克隆文库的分析,揭示九龙江河口区nirS型反硝化细菌多样性。【方法】选取九龙江河口区一富营养化采样点,分别采集水样及沉积物样品,进行理化因子的测定并提取细菌总DNA。以水样DNA构建16S rRNA基因克隆文库,以沉积物DNA构建nirS基因克隆文库,分析微生物群落结构的多样性并构建系统发育树。【结果】从16S rRNA基因克隆文库中获得86条有效序列,按97%的序列相似性划分为53个OTU,分别属于Proteobacteria门、Planctomycetes门、Bacteroidetes门、Actinobacteria门、Firmicutes门和Chloroflexi门。其中属于Proteobacteria门OTU的克隆子占克隆数的62.9%,是最优势的类群,分属于Alphaproteobacteria、Betaproteobacteria、Gammaproteobacteria和Deltaproteobacteria纲等。从nirS基因克隆文库中获得190条有效序列,翻译为氨基酸序列后,按82%的序列相似性划分为60个OTU,并定位到属的水平。其中Proteobacteria门是最优势的类群,占文库克隆子总数的71.6%,包括Alphaproteobacteria纲(5.8%)、Betaproteobacteria纲(49.0%)和Gammaproteobacteria纲(16.9%)。nirS基因克隆文库中丰度最高的OTU与GenBank中的一株可培养反硝化菌Thauera sp. R-26906具有100%的序列相似性。【结论】九龙江河口区的微生物以及亚硝酸盐还原酶基因(nirS)具有丰富的多样性。大部分NirS序列在GenBank中的最相似序列来源于河口、海湾等相似的环境。     

奇古菌亚硝酸盐还原酶基因相似基因的多样性

摘要:【目的】氨氧化古菌(Ammonia-oxidizing archaea,AOA)是奇古菌门中的唯一类群,广泛分布于各个生态系统中,对氮素生物地球化学循环起着重要作用。亚硝酸还原酶是反硝化作用的关键酶,目前关于AOA反硝化作用的研究较少,对AOA 亚硝酸盐还原酶基因多样性的研究有利于揭示AOA在反硝化中的作用。【方法】本研究以水体、沉积物和土壤为研究对象,构建了奇古菌样的nirK基因克隆文库,研究了这些环境中nirK相似基因的多样性。【结果】对奇古菌样的nirK基因文库及其序列分析表明:湖水及其沉积物的 nirK基因克隆文库得到10个OTUs,菜田土壤和水样则有8个OTUs;系统发育进化树表明这些nirK氨基酸序列和Candidatus Nitrosopumilus koreensis AR1,Nitrosopumilus maritimus SCM1最为相似,但相似度较低(53%－68%)。克隆文库多样性指数分析表明:所有样品都存在不同类型的nirK基因,水体样品nirK基因类型的多样性和均匀度高于土壤样品,菜田土壤的nirK基因类型多样性最高,分布最均匀。【结论】本研究表明土壤和淡水环境中奇古菌门nirK基因也具有较高的多样性,并且这些基因型与海洋样品差异非常大,这些基因编码的亚硝酸盐还原酶可能对这些环境中的反硝化作用有重要意义。     

干湿交替对生物滞留系统中氮素功能微生物群落的影响

【目的】为探究生物滞留系统干湿交替下环境因子对氮素功能微生物群落的影响。【方法】应用高通量测序技术(Illumina MiSeq PE300),并以amoA和nirS功能基因为分子标记,对无植物型和植物型生物滞留系统在干湿交替下不同土壤空间位置(种植层、淹没层)的硝化和反硝化细菌的多样性和群落结构进行研究,并对微生物群落与环境因子的相互关系进行相关性分析。【结果】微生物种群的功能基因存在显著的空间差异,相比淹没层,种植层的功能细菌更丰富。种植层的OTUs高于淹没层,而进水再湿润促使两种功能基因在种植层和淹没层的OTUs占比差异性增大。群落组成分析表明,amoA型硝化细菌和nirS型反硝化细菌的优势细菌门均为变形菌门(Proteobacteria)。虽然植物根系对氮素功能微生物的多样性指数影响不显著,但在属水平上,植物系统种植层的反硝化菌群种类高于淹没层,而无植物系统则刚好相反。CCA/RDA分析表明,土壤空间位置是影响硝化和反硝化菌群结构的最重要环境因子。【结论】本研究证实干湿交替运行下生物滞留系统中的氮素功能微生物群落受土壤空间位置、水分含量和植物根系的共同调控,其机制有待进一步研究。     

过表达亚硝酸盐还原酶的重组大肠杆菌辅助污水短程硝化

【目的】为了体现并突出亚硝酸盐还原酶在污水脱氮以及短程硝化中的重要性,对过表达亚硝酸盐还原酶的大肠杆菌进行了污水脱氮的研究。【方法】通过转化带有亚硝酸盐还原酶基因的重组质粒,将亚硝酸盐还原酶在大肠杆菌中过表达,通过分析重组大肠杆菌的产物研究了该酶的表达及还原亚硝酸盐的情况,通过将该重组菌与已报道的硝化-反硝化细菌或生活污水进行混合培养,研究重组菌用于辅助氨氮去除的短程硝化能力。【结果】重组大肠杆菌能正确表达亚硝酸盐还原酶,OD600=2.0的菌悬液在2 h内还原约1 mmol/L的亚硝酸盐,并产生几乎等量的一氧化氮;重组大肠杆菌与Acinetobacter sp.YF14菌株等比例混合时,12 h能够提高氨氮脱氮效率约(36.0±7.4)%,且在4 h时,最大亚硝酸盐的积累量减少37%;重组大肠杆菌(OD600=1.0)12 h内能够提高污水厂活性污泥的脱氮效率约(31.0±5.7)%,且未检测到亚硝酸盐和硝酸盐的积累;溶氧水平对于亚硝酸盐还原酶重组菌辅助脱氮具有明显的影响,中等溶氧量[(6.4?0.7)mg/L]时脱氮效果最好。【结论】过表达亚硝酸盐还原酶的大肠杆菌可以提高污水脱氮的短程硝化能力。     

基于mcrA基因的沁水盆地煤层气田产甲烷菌群与途径分析

【目的】分析沁水盆地煤层气田不同煤层气井产出水样中产甲烷菌群和生物成因气的生成途径。【方法】以甲基辅酶M还原酶基因(mcr A)作为目标基因,采用454焦磷酸高通量测序方法,同时比对NCBI功能基因文库中的mcr A序列,分析不同煤层气井产出水中的产甲烷菌群。【结果】高通量测序表明,5个出水样产甲烷菌群OTUs(Operational taxonomic units)数为64–157个,共有的为22个,各占样品总数14%-34%;样品共检测到4种已知菌属,即甲烷杆菌属(Methanobacterium)、甲烷微菌属(Methanomicrobium)、甲烷叶菌属(Methanolobus)和甲烷螺菌属(Methanospirillum),优势菌属均为Methanobacterium。系统发育分析表明,未明确地位的菌属主要与Methanobacterium、Methanomicrobium、产甲烷球菌属(Methanococcus)和甲烷囊菌属(Methanoculleus)有较近的亲缘关系。5个样品中菌属所占比例不同,检测到的菌属类别大致相同。所有检测样品生物成因煤层气(Coalbed methane,CBM)的生成途径主要为氢营养型产甲烷途径。【结论】沁水盆地不同煤层气田产甲烷菌群菌种差异比较大,但生物成因气生成途径基本相似,与地理位置和煤藏条件没有相关性。     

淡水富营养型湖泊沉积物亚硝酸还原酶基因(nirS)的多样性和系统发育

【目的】以亚硝酸盐还原酶基因(nirS)为分子标记,探讨富营养化湖泊武汉东湖沉积物中NirS类反硝化细菌群落的多样性及系统发育,并分析环境因子对群落分布的影响。【方法】在武汉东湖4个典型子湖郭郑湖、汤菱湖、团湖和庙湖采集沉积物样品,测定环境参数;提取沉积物中微生物群落基因组DNA,分别构建4个子湖的反硝化微生物的nirS基因文库,利用限制性片段长度的多态性分析(Restriction Fragment LengthPolymorphism,RFLP)技术初步分群,确定各群的代表菌株并测定其nirS基因序列;利用DOTUR软件计算各群落多样性和丰富度指数,以Neighbor-Joining法构建供试菌与参比菌的系统发育树。【结果】环境参数测定结果表明东湖4个子湖中庙湖沉积物总氮(TN)和氨态氮(NH 4+-N)含量最高,团湖最低,郭郑湖沉积物中NO 3-浓度最高。基于NirS序列的生物多样性和丰富度分析表明团湖生物多样性和丰富度指数最高而庙湖各项指数均较低。各子湖供试序列及其代表序列综合RFLP聚类分析表明,武汉东湖沉积物中NirS类反硝化微生物种群具有丰富的多样性。NJ系统发育分析表明东湖沉积物NirS类反硝化菌群可分成3个较大群体(群I-III)。群I占总群体的67.7%,广泛分布于不同的生态环境;来自郭郑湖代表菌的81%分布于群I,而庙湖的代表菌中65%分布于群II。比较分析发现来自于东湖和人工湿地两种生境的NirS群落间具有较高的相似性。【结论】武汉东湖淡水富营养型湖泊沉积物中亚硝酸还原酶基因(nirS)具有丰富的多样性。东湖沉积物中TN、NH 4+和NO 3-的浓度可能是影响NirS类反硝化微生物多样性和空间分布的重要因素之一。     

Effects of aeration cycles on nitrifying bacterial populations and nitrogen removal in intermittently aerated reactors

The effects of the lengths of aeration and nonaeration periods on nitrogen removal and the nitrifying bacterial community structure were assessed in intermittently aerated (IA) reactors treating digested swine wastewater. Five IA reactors were operated in parallel with different aeration-to-nonaeration time ratios (ANA). Populations of ammonia-oxidizing bacteria (AOB) and nitrite-oxidizing bacteria (NOB) were monitored using 16S rRNA slot blot hybridizations. AOB species diversity was assessed using amoA gene denaturant gradient gel electrophoresis. Nitrosomonas and Nitrosococcus mobilis were the dominant AOB and Nitrospira spp. were the dominant NOB in all reactors, although Nitrosospira and Nitrobacter were also detected at lower levels. Reactors operated with the shortest aeration time (30 min) showed the highest Nitrosospira rRNA levels, and reactors operated with the longest anoxic periods (3 and 4 h) showed the lowest levels of Nitrobacter, compared to the other reactors. Nitrosomonas sp. strain Nm107 was detected in all reactors, regardless of the reactor's performance. Close relatives of Nitrosomonas europaea, Nitrosomonas sp. strain ENI-11, and Nitrosospira multiformis were occasionally detected in all reactors. Biomass fractions of AOB and effluent ammonia concentrations were not significantly different among the reactors. NOB were more sensitive than AOB to long nonaeration periods, as nitrite accumulation and lower total NOB rRNA levels were observed for an ANA of 1 h:4 h. The reactor with the longest nonaeration time of 4 h performed partial nitrification, followed by denitrification via nitrite, whereas the other reactors removed nitrogen through traditional nitrification and denitrification via nitrate. Superior ammonia removal efficiencies were not associated with levels of specific AOB species or with higher AOB species diversity.     

First exploration of Nitrobacter diversity in soils by a PCR cloning-sequencing approach targeting functional gene nxrA

Nitrite oxidoreductase (NXR) is the key enzyme responsible for the oxidation of NO(2)(-) to NO(3)(-) in nitrite-oxidizing bacteria. For the first time a molecular approach for targeting the nxrA gene was developed, encoding the catalytic subunit of the NXR, to study diversity of Nitrobacter-like organisms based on the phylogeny of nxrA gene sequences in soils. NxrA sequences of the Nitrobacter strains analysed (Nitrobacter hamburgensis, Nitrobacter vulgaris, Nitrobacter winogradskyi, Nitrobacter alkalicus) by PCR, cloning and sequencing revealed the occurrence of multiple copies of nxrA genes in these strains. The copy number and similarity varied among strains. The diversity of Nitrobacter-like nxrA sequences was explored in three soils (a French permanent pasture soil, a French fallow soil, and an African savannah soil) using a cloning and sequencing approach. Most nxrA sequences found in these soils (84%) differed from nxrA sequences obtained from Nitrobacter strains. Moreover, the phylogenetic distribution and richness of nxrA-like sequences was extremely variable depending on soil type. This nxrA tool extends the panel of functional genes available for studying bacteria involved in the nitrogen cycle.     

Nitrosomonas Nm143-like ammonia oxidizers and Nitrospira marina-like nitrite oxidizers dominate the nitrifier community in a marine aquaculture biofilm

Zero-discharge marine aquaculture systems are an environmentally friendly alternative to conventional aquaculture. In these systems, water is purified and recycled via microbial biofilters. Here, quantitative data on nitrifier community structure of a trickling filter biofilm associated with a recirculating marine aquaculture system are presented. Repeated rounds of the full-cycle rRNA approach were necessary to optimize DNA extraction and the probe set for FISH to obtain a reliable and comprehensive picture of the ammonia-oxidizing community. Analysis of the ammonia monooxygenase gene (amoA) confirmed the results. The most abundant ammonia-oxidizing bacteria (AOB) were members of the Nitrosomonas sp. Nm143-lineage (6.7% of the bacterial biovolume), followed by Nitrosomonas marina-like AOB (2.2% of the bacterial biovolume). Both were outnumbered by nitrite-oxidizing bacteria of the Nitrospira marina-lineage (15.7% of the bacterial biovolume). Although more than eight other nitrifying populations were detected, including Crenarchaeota closely related to the ammonia-oxidizer 'Nitrosopumilus maritimus', their collective abundance was below 1% of the total biofilm volume; their contribution to nitrification in the biofilter is therefore likely to be negligible.     

Development and application of a PCR-denaturing gradient gel electrophoresis tool to study the diversity of Nitrobacter-like nxrA sequences in soil

A new PCR-denaturing gel gradient electrophoresis (DGGE) tool based on the functional gene nxrA encoding the catalytic subunit of the nitrite oxidoreductase in nitrite-oxidizing bacteria (NOB) has been developed. The first aim was to determine if the primers could target representatives of NOB genera: Nitrococcus and Nitrospira. The primers successfully amplified nxrA gene sequences from Nitrococcus mobilis, but not from Nitrospira marina. The second aim was to develop a PCR-DGGE tool to characterize NOB community structure on the basis of Nitrobacter-like partial nrxA gene sequences (Nb-nxrA). We tested (1) the ability of this tool to discriminate between Nitrobacter strains, and (2) its ability to reveal changes in the community structure of NOB harbouring Nb-nrxA sequences induced by light grazing or intensive grazing in grassland soils. The DGGE profiles clearly differed between the four Nitrobacter strains tested. Differences in the structure of NOB community were revealed between grazing regimes. Phylogenetic analysis of the sequences corresponding to different DGGE bands showed that Nb-nxrA sequences did not group in management-specific clusters. Most of the nxrA sequences obtained from soils differed from nxrA sequences of NOB strains. Along with existing tools for characterizing the community structure of nitrifiers, this new approach is a significant step forward to performing comprehensive studies on nitrification.     

Seasonal changes in nitrogen-cycle gene abundances and in bacterial communities in acidic forest soils

The abundance of genes related to the nitrogen biogeochemical cycle and the microbial community in forest soils (bacteria, archaea, fungi) were quantitatively analyzed via real-time PCR using 11 sets of specific primers amplifying nifH, bacterial amoA, archaeal amoA, narG, nirS, nirK, norB, nosZ, bacterial 16S rRNA gene, archaeal 16S rRNA gene, and the ITS sequence of fungi. Soils were sampled from Bukhan Mountain from September of 2010 to July of 2011 (7 times). Bacteria were the predominant microbial community in all samples. However, the abundance of archaeal amoA was greater than bacterial amoA throughout the year. The abundances of nifH, nirS, nirK, and norB genes changed in a similar pattern, while narG and nosZ appeared in sensitive to the environmental changes. Clone libraries of bacterial 16S rRNA genes were constructed from summer and winter soil samples and these revealed that Acidobacteria was the most predominant phylum in acidic forest soil environments in both samples. Although a specific correlation of environmental factor and gene abundance was not verified by principle component analysis, our data suggested that the combination of biological, physical, and chemical characteristics of forest soils created distinct conditions favoring the nitrogen biogeochemical cycle and that bacterial communities in undisturbed acidic forest soils were quite stable during seasonal change.     

西藏米拉山土壤古菌16S rRNA及amoA基因多样性?分析

摘要：【目的】硝化作用在全球土壤氮循环中具有重要的作用,虽然细菌一度被认为单独负责催化这个过程的限速步骤,但是最近一些研究结果表明泉古菌具有氨氧化的能力。本文通过构建古菌16S rRNA 基因克隆文库和氨氧化古菌amoA基因文库,分析西藏米拉山高寒草甸土壤中古菌及氨氧化古菌群落结构组成情况,为揭示青藏高原高寒草甸土壤古菌的多样性提供理论基础。【方法】采用未培养技术直接从土壤中提取微生物总DNA,分别利用通用引物构建古菌16S rRNA 基因和氨氧化古菌amoA基因克隆文库。【结果】通过构建系统发育树,表明古菌16S rRNA 基因克隆文库包括泉古菌门和未分类的古菌两大类,并且所有泉古菌均属于热变形菌纲。氨氧化古菌amoA基因克隆文库中序列均为泉古菌。通过DOTUR软件分析,古菌16S rRNA基因和古菌amoA基因克隆文库分别包括64个OTUs和 75个OTUs。【结论】西藏米拉山高寒草甸土壤中古菌多样性比较丰富,表明古菌在高寒草甸土壤的氮循环中可能具有重要的作用。所获得的一些序列与已知环境中土壤、淡水及海洋沉积物中获得的一些序列具有很高的相似性,其古菌及氨氧化古菌来自不同环境的可能性比较大,可能与青藏高原的地质历史变迁过程有关。米拉山古菌及氨氧化古菌与陆地设施土壤中相似性最高,说明与西藏米拉山高寒草甸土壤的退化有关。