木麻黄根瘤共生放线菌——Frankia的研究

用根瘤切片培养法,从细枝木麻黄野生根瘤中分离出具有侵染能力的Frankia sp. FSCc01菌株。该菌株在多种常用放线菌培养基上生长缓慢,产生孢囊孢子,顶囊只在无氮培养基上大量出现。在一些培养基上,菌丝分化产生孢于囊状结构(sLs)。用纯培养物接种水培细枝木麻黄幼苗,2一{周后即能形成典型的木麻黄根瘤,并表现出较强的乙炔还原能力。在较强的光照下,FsCcol菌株的宿主结瘤早,瘤数量多,固氮能力强。能在8·qppm的NH+态N存在下使宿主结癌和固氮,pH变化在5．8—7．0范围内对结瘤没有明显影响。对’~Cc01菌株共生特性的进一步研究将有助于阐明其应用的可能。     

一株木麻黄根瘤内生菌的培养条件研究

1982年,Diem等人从木麻黄根瘤中分离出Frankia菌株DI_1和G_2,虽然纯培养的形态与典型Frankia菌株相似,但回接原宿主未获成功,而在沙棘上回接成功结瘤。同年,他又获得了CjI-82菌株,回接木麻黄结瘤并固氮。1985年,蒋建德与朱宝琴报道从木麻黄根瘤中分离到IFS 020601菌株,并回接成功。作者用四氧化锇法处理木麻黄根瘤,接种于     

Frankia菌同功酶图谱分析和分类

利用同功酶图谱的差异性对Frankia菌进行分类识别是一种非常有效的方法,不同的Frankia菌株具有不同的同功酶(过氧化物酶和酯酶)图谱。根据图谱之间的相似性,可以将20株Frankia菌分成三大组,即赤杨组、木麻黄组和胡颓子组,这与其它分类结果基本符合,只是细枝木麻黄菌株Cc01的过氧化物酶图谱与其它菌株完全不同。从同种植物根瘤中分离的内生菌具有不同的同功酶图谱,进一步证实了遗传结构不完全相同的菌株可以同时共生于同种根瘤内,同时根据二种同功酶的电泳分布率,说明了Frankia菌株遗传信息的广泛分布性。     

木麻黄根瘤内FRANKIA的分离培养与回接结瘤条件

木麻黄(Casuarina equisetifolia L.)属被子植物,是能结瘤固氮的非豆科树木。生长在我国南方沿海一带。我们于1982年10月从其根瘤中分得内生菌,经纯培养,形态特征观察,与Callaham等1978年从香蕨木(Comptonia peregrina)根瘤中分离的内生菌有相似的特点,符合报导的Frankio菌属的标准。1981年以来,由木麻黄根瘤中分离出Frankia内生菌,已先后有成功的报导。我们把所纯培养的Frankia sp.Cecl4菌株回接于宿主木麻黄根系上,侵染结瘤,获得成功。     

几株不同种属来源的木麻黄植物根瘤共生放线菌-Frankia的研究

用根瘤切片法,从长骨木麻黄(C. glauca Sieb.)、鸡冠木麻黄(C. cristata)和海滨木麻黄(A. littoralis)野生根瘤中分离出具有侵染能力的Frankia sp、NNCG01、NNCCR03和NNACL05菌株,它们都具有Frankia的典型形态特征,在无氮培养条件下,形成大量的顶囊和孢子囊。各菌株对简单碳源和氮源的利用比对复杂碳源和氮源的利用更好,而且都具有较高的耐盐(NaC1)能力,在0.2M盐浓度中,生长受到的影响很小,在盐浓度为0.5M时,也有一定生长。这三株Frankia菌株都能交叉感染木麻黄属(Casuarina)和异木麻黄属(Allocasuarina)中的一些放线菌结瘤植物,因此,从木麻黄属植物根瘤分离的Frankia菌株和从异木麻黄属植物根瘤分离的Frankia菌株属于同一个互接种簇。这三株Frankia的自生固氮活性与它们的共生固氮活性呈正比,而且同一菌株与不同种木麻黄植物共生固氮的效率没有明显的差异,为初步筛选高效共生固氮的Frankia菌株提供了一个快速简便的方法,具有重要的实际意义。     

氮沉降对温带森林土壤甲烷氧化菌的影响

大量研究显示氮沉降影响森林甲烷吸收量,但其中的微生物驱动机制仍缺乏研究。基于长白山典型温带森林长期氮沉降模拟实验平台样地,采用定量PCR和克隆测序技术,研究了长期施加不同形态氮((NH_4)_2SO_4、NH_4Cl和KNO_3)处理下森林土壤甲烷氧化菌的数量和群落组成随季节变化的特征。结果表明,夏季,森林土壤甲烷氧化菌pmo A基因丰度在不同施氮处理之间无显著性差异(每克干土1.54×10~6-3.20×10~6拷贝数);秋季,pmo A基因丰度在施加NH_4Cl和(NH_4)_2SO_4处理小区(每克干土1.93×10~5-7.6×10~5拷贝数)与对照(每克干土(4.03×10~6±1.2×10~6)拷贝数)相比有所降低,尤其在(NH_4)_2SO_4处理小区(每克干土(4.61×10~5±2.61×10~5)拷贝数)显著降低;无论夏季还是秋季,施加不同形态氮处理土壤甲烷氧化菌均以Type I型为主(相对丰度在70.6%-85.4%之间),并以Methylobacter-group(Type I)为优势类群,占Type I型的55.1%-91.7%;Methylobacter-group(Type I)的相对丰度在夏季不同形态氮处理土壤样品中无显著差异,但秋季样品中在施加(NH_4)_2SO_4(52.7%±6.5%)和NH_4Cl(56.1%±8.9%)的处理显著低于对照土壤(77.0%±2.9%),Methylococcus-group(Type I)的相对丰度则在(NH_4)_2SO_4和NH_4Cl处理土壤呈增加的趋势。这些结果表明铵态氮肥添加对温带森林土壤甲烷氧化菌的生长具有抑制作用并导致其群落结构发生改变,受夏季温度和水分的影响,这种抑制作用在秋季表现更明显,而NO_3~--N添加对土壤甲烷氧化菌的群落组成和丰度无显著影响。这些结果解释了以往观测到的施铵态氮肥显著降低秋季温带林地土壤甲烷净吸收量,而在夏季无显著影响的观测结果,解释了长期氮沉降影响森林土壤甲烷吸收的微生物机制。     

沙棘——弗氏放线菌共生固氮体系研究——Ⅰ环境因子影响沙棘结瘤和生长

环境因子包括盐度、pH值、化合氮和磷素供给显著影响了Frankia菌株Hr32对水培沙棘小苗的侵染结瘤。沙棘能在0.8％盐度下生长但受抑,0.2％盐度下开始有根瘤发生,0.1％盐度下结瘤较好。Hr32纯培养下耐盐力不强,0.5％盐度下已不能生长,导致了高盐浓度下不能结瘤。pH=7.0—8.0为沙棘结瘤最佳范围,pH值高至9.0或低至4.2,沙棘不能结瘤。低磷供给限制了根瘤发生,当供给10ppm或更高的磷时,沙棘成功结瘤。低于6ppm化合氮供给促进结瘤,当供给16ppm化合氮时,结瘤完全抑制。结瘤使沙棘获得近二倍的增长效果,水培条件下人工根瘤活性低于自然生境根瘤。结瘤使沙棘的落叶延迟。     

木麻黄和桤木离体根瘤和立地土壤的固氮酶与N2O还原酶活性的研究

为了解非豆科固氮树种的固氮酶和N_2O还原酶(Nos)活性,采用乙炔还原法和乙炔抑制技术对细枝木麻黄(Casuarina cunninghamiana)和江南桤木(Alnus trabeculosa)离体根瘤及立地土壤的两种酶活性进行了研究。结果表明,离体根瘤只在厌氧条件下有固氮酶活性,在好氧条件下有Nos活性。根瘤区根际土和非根瘤区根际土的固氮酶活性在好氧条件大于厌氧条件,Nos活性只表现在厌氧条件下。在好氧条件下,根瘤区根际土和非根瘤区根际土的固氮酶活性无显著差异;根瘤区根际土的Nos活性显著大于非根瘤区根际土。除离体根瘤在好氧条件下不表现固氮酶活性外,细枝木麻黄和桤木的离体根瘤、根瘤区根际土和非根瘤区根际土的固氮酶活性均都大于Nos活性。好氧条件下根瘤区根际土的固氮酶活性与非根瘤区根际土的呈极显著正相关,而厌氧条件下根瘤的固氮酶活性与好氧条件下根瘤区根际土和非根瘤区根际土固氮酶活性、好氧条件下根瘤的Nos活性与厌氧条件下根瘤区根际土和非根瘤区根际土Nos活性均呈极显著负相关。这为研究弗兰克氏菌结瘤植物共生固氮体系对N2O汇强度的影响和调控奠定基础。     

根瘤菌结瘤因子的结构和功能

结瘤因子是根瘤菌分泌的寡糖,它作为外在信号,诱发宿主植物根部各种生理反应。引起根毛变形,诱导皮层细胞分裂,形成根瘤原基,作者主要就这一早期结瘤过程中结瘤因子的结构和功能作一综述。     

色赤杨光合作用与根瘤氮代谢的关系

在放线菌结瘤植物(Actinorhizal plants)与放线菌Frankia的共生体系中,固氮酶(N_2ase)活性与所提供的光合产物的量密切相关。通过在同一天的不同对间内,对同株色赤杨光合作用和根瘤中的N_2ase比活、NH_4~ 含量、还原糖含量以及总氮量的变化所做的同步测定结果表明,N_2ase比活的最高峰迟后于光合强度的最高峰;在根瘤内部,NH_4~ 含量和还原糖含量都与N_2ase比活呈负相关,而总氮量则与N_2ase比活呈正相关。本文对这一现象进行了讨论,并且推测还原糖作为光合作用产物的衍生物,直接影响根瘤的固氮作用,它不仅为N.2ase提供固氮所需的能量,而且为固氮产物NH_4~ 提供受体。     

Regulation of nodulation in the absence of N2 is different in actinorhizal plants with different infection pathways

Root nodulation in actinorhizal plants, like Discaria trinervis and Alnus incana, is subject to feedback regulatory mechanisms that control infection by Frankia and nodule development. Nodule pattern in the root system is controlled by an autoregulatory process that is induced soon after inoculation with Frankia. The final number of nodules, as well as nodule biomass in relation to plant biomass, are both modulated by a second mechanism which seems to be related to the N status of the plant. Mature nodules are, in part, involved in the latter process, since nodule excision from the root system releases the inhibition of infection and nodule development. To study the effect of N(2) fixation in this process, nodulated D. trinervis and A. incana plants were incubated under a N(2)-free atmosphere. Discaria trinervis is an intercellularly infected species while A. incana is infected intracellularly, via root hairs. Both symbioses responded with an increment in nodule biomass, but with different strategies. Discaria trinervis increased the biomass of existing nodules without significant development of new nodules, while in A. incana nodule biomass increased due to the development of nodules from new infections, but also from the release of arrested infections. It appears that in D. trinervis nodules there is an additional source for inhibition of new infections and nodule development that is independent of N(2) fixation and nitrogen assimilation. It is proposed here that the intercellular Frankia filaments commonly present in the D. trinervis nodule apex, is the origin for the autoregulatory signals that sustain the blockage of initiated nodule primordia and prevent new roots from infections. When turning to A. incana plants, it seems likely that this signal is related to the early autoregulation of nodulation in A. incana seedlings and is no longer present in mature nodules. Thus, actinorhizal symbioses belonging to relatively distant phylogenetic groups and displaying different infection pathways, show different feedback regulatory processes that control root nodulation by Frankia.     

The cell-cycle promoter cdc2aAt from Arabidopsis thaliana is induced in the lateral roots of the actinorhizal tree Allocasuarina verticillata during the early stages of the symbiotic interaction with Frankia

The symbiosis between the actinorhizal tree Allocasuarina verticillata and the actinomycete Frankia leads to the formation of root nodules inside which bacteria fix atmospheric nitrogen. Actinorhizal nodule organogenesis starts with the induction of cell divisions in the root cortex and in the pericycle cells opposite protoxylem poles near Frankia -infected root hairs. To study the ability of Frankia to induce progression through the cell cycle, we monitored the expression of the β-glucuronidase ( gus ) gene driven by the promoter from cdc2aAt , an Arabidopsis cyclin-dependent kinase gene that displays competence for cell division, during plant growth and nodule ontogenesis. In non-symbiotic tissues, the gus gene was mainly expressed in primary and secondary meristems of roots and shoots. Auxins and cytokinins were found to induce reporter gene activity in the root system of whole plants, showing that the promoter cdc2aAt displayed the same regulation by hormones in Allocasuarina as that reported in Arabidopsis . In transgenic nodules, gus expression was found to be restricted to the phellogen. During the early stages of the interaction between Frankia and the plant root system, cdc2aAt was strongly induced in the lateral roots surrounded by hyphae of the actinomycete. Histochemical analysis of β-glucuronidase activity revealed that cells from the pericycle opposite protoxylem poles were very deeply stained. These data indicate that upon Frankia infection, cells from the lateral roots, and notably pericycle cells that can give rise to a nodule or a root primordium, prepare to re-enter the cell cycle.     

Effect of inoculation and leaf litter amendment on establishment of nodule-forming Frankia populations in soil

High-N(2)-fixing activities of Frankia populations in root nodules on Alnus glutinosa improve growth performance of the host plant. Therefore, the establishment of active, nodule-forming populations of Frankia in soil is desirable. In this study, we inoculated Frankia strains of Alnus host infection groups I, IIIa, and IV into soil already harboring indigenous populations of infection groups (IIIa, IIIb, and IV). Then we amended parts of the inoculated soil with leaf litter of A. glutinosa and kept these parts of soil without host plants for several weeks until they were spiked with [(15)N]NO(3) and planted with seedlings of A. glutinosa. After 4 months of growth, we analyzed plants for growth performance, nodule formation, specific Frankia populations in root nodules, and N(2) fixation rates. The results revealed that introduced Frankia strains incubated in soil for several weeks in the absence of plants remained infective and competitive for nodulation with the indigenous Frankia populations of the soil. Inoculation into and incubation in soil without host plants generally supported subsequent plant growth performance and increased the percentage of nitrogen acquired by the host plants through N(2) fixation from 33% on noninoculated, nonamended soils to 78% on inoculated, amended soils. Introduced Frankia strains representing Alnus host infection groups IIIa and IV competed with indigenous Frankia populations, whereas frankiae of group I were not found in any nodules. When grown in noninoculated, nonamended soil, A. glutinosa plants harbored Frankia populations of only group IIIa in root nodules. This group was reduced to 32% +/- 23% (standard deviation) of the Frankia nodule populations when plants were grown in inoculated, nonamended soil. Under these conditions, the introduced Frankia strain of group IV was established in 51% +/- 20% of the nodules. Leaf litter amendment during the initial incubation in soil without plants promoted nodulation by frankiae of group IV in both inoculated and noninoculated treatments. Grown in inoculated, amended soils, plants had significantly lower numbers of nodules infected by group IIIa (8% +/- 6%) than by group IV (81% +/- 11%). On plants grown in noninoculated, amended soil, the original Frankia root nodule population represented by group IIIa of the noninoculated, nonamended soil was entirely exchanged by a Frankia population belonging to group IV. The quantification of N(2) fixation rates by (15)N dilution revealed that both the indigenous and the inoculated Frankia populations of group IV had a higher specific N(2)-fixing capacity than populations belonging to group IIIa under the conditions applied. These results show that through inoculation or leaf litter amendment, Frankia populations with high specific N(2)-fixing capacities can be established in soils. These populations remain infective on their host plants, successfully compete for nodule formation with other indigenous or inoculated Frankia populations, and thereby increase plant growth performance.     

Isolation of an effective strain of Frankia from nodules of Discaria trinervis (Rhamnaceae)

Frankia strain BCU110501 was isolated from root nodules of the native Patagonian actinorhizal plant Discaria trinervis. The strain was grown on BAP medium with sodium propionate or glucose as carbon sources. Colonies grown in nitrogen-free medium showed branched hyphae bearing polymorphic sporangia and vesicles, which were capable of nitrogen fixation. Old cultures produced a red pigment. The infectivity and effectivity of a Frankia strain isolated from Discaria on its own host, D. trinervis and also in D. chacaye, is reported for the first time. Frankia BCU110501 has physiological properties that are intermediate between categories proposed by Lechevalier et al. (1983) to classify Frankia.     

Characterization of the anomalous infection and nodulation of subterranean clover roots by Rhizobium leguminosarum 1020

Anomalous nodulation of Trifolium subterraneum (subterranean clover) roots by Rhizobium leguminosarum 1020 was examined as a model of modified host-specificity in a Rhizobium-legume symbiosis. Consistent with previous reports, these nodules (i) appeared most often at sites of secondary root emergence, (ii) were ineffective in nitrogen fixation and (iii) were as numerous as nodules formed by an effective Rhizobium trifolii strain. R. leguminosarum 1020, grown on agar plates or in the clover root environment, did not bind the white clover lectin, trifoliin A. This strain did not attach in high numbers, and did not induce shepherd's crooks or infection threads, in subterranean clover root hairs. However, R. leguminosarum 1020 did cause branching, moderate curling and other deformations of root hairs. The bacteria probably entered the clover root through breaks in the epidermis at sites of lateral root emergence. The anomalous nodulation was inhibited by nitrate. Only trace amounts of leghaemoglobin were detected in the nodules by Western blot analysis. The nodules were of the meristematic type and initially contained well-developed infection, bacteroid and senescent zones. Infection threads were readily found in the infection zone of the nodule. However, the bacteroid-containing tissue senesced more rapidly than in the effective symbiosis between subterranean clover and R. trifolii 0403. This anomalous nodulation of subterranean clover by R. leguminosarum 1020 suggests a naturally-occurring alternative route of infection that allows Rhizobium to enlarge its host range.     

Frankia与链霉菌融合子特性的研究

将Frankia菌株CcOl与金色链霉菌GL原生质体融合,得到3株融合子,均具有GL生长快的特性与CcOl的结瘤固氮能力.固体培养时,3株融合子呈现出与GL不同的颜色;且均具有Frankia菌的顶囊形态,以及链霉菌的链状孢子丝结构.与两亲本相同,3株融合子均对大肠杆菌有抗性,其中F4与GL的抗菌谱基本相同.在传10代之后,它们仍具有结瘤与固氮能力.血清学分析表明,F1与F6兼具两亲本的特异抗原,而F4仅具有GL的特异抗原,融合子F1、F6较F4在遗传上更为稳定.     

Evidence that some Frankia sp. strains are able to cross boundaries between Alnus and Elaeagnus host specificity groups.

Phenotypic and genotypic methods were used to prove the existence of Frankia strains isolated from an Elaeagnus sp. that are able to cross the inoculation barriers and infect Alnus spp. also. Repeated cycles of inoculation, nodulation, and reisolation were performed under axenic conditions. Frankia wild-type strain UFI 13270257 and three of its coisolates did exhibit complete infectivity and effectiveness on Elaeagnus spp. and Hippophaë rhamnoides and variable infectivity on Alnus spp. Microscopical observation of host plant roots showed that these strains are able to infect Alnus spp. by penetrating deformed root hairs. Reisolates obtained from nodules induced on monoxenic Alnus glutinosa, Alnus incana, and Elaeagnus angustifolia resembled the parent strains in host infectivity range, in planta and in vitro morphophysiology, isoenzymes, and nif and rrn restriction fragment length polymorphisms, thus fulfilling Koch's postulates on both host plant genera. Alnus and Elaeagnus group-specific polymerase chain reaction DNA amplifications, DNA-DNA hybridizations, and partial gene sequences coding for 16S rRNA provided evidence for the genetic uniformity of wild-type strains and their inclusion into one and the same genomic species, clearly belonging to the Elaeagnus group of Frankia species.     

Evidence that some Frankia sp. strains are able to cross boundaries between Alnus and Elaeagnus host specificity groups.

Phenotypic and genotypic methods were used to prove the existence of Frankia strains isolated from an Elaeagnus sp. that are able to cross the inoculation barriers and infect Alnus spp. also. Repeated cycles of inoculation, nodulation, and reisolation were performed under axenic conditions. Frankia wild-type strain UFI 13270257 and three of its coisolates did exhibit complete infectivity and effectiveness on Elaeagnus spp. and Hippopha? rhamnoides and variable infectivity on Alnus spp. Microscopical observation of host plant roots showed that these strains are able to infect Alnus spp. by penetrating deformed root hairs. Reisolates obtained from nodules induced on monoxenic Alnus glutinosa, Alnus incana, and Elaeagnus angustifolia resembled the parent strains in host infectivity range, in planta and in vitro morphophysiology, isoenzymes, and nif and rrn restriction fragment length polymorphisms, thus fulfilling Koch's postulates on both host plant genera. Alnus and Elaeagnus group-specific polymerase chain reaction DNA amplifications, DNA-DNA hybridizations, and partial gene sequences coding for 16S rRNA provided evidence for the genetic uniformity of wild-type strains and their inclusion into one and the same genomic species, clearly belonging to the Elaeagnus group of Frankia species.     

Effects of phosphorus and nitrogen on nodulation are seen already at the stage of early cortical cell divisions in Alnus incana

BACKGROUND AND AIMS: The present work aimed to study early stages of nodulation in a chronological sequence and to study phosphorus and nitrogen effects on early stages of nodulation in Alnus incana infected by Frankia. A method was developed to quantify early nodulation stages in intact root systems in the root hair-infected actinorhizal plant A. incana. Plant tissue responses were followed every 2 d until 14 d after inoculation. Cortical cell divisions were already seen 2 d after inoculation with Frankia. Cortical cell division areas, prenodules, nodule primordia and emerging nodules were quantified as host responses to infection. METHODS: Seedlings were grown in pouches and received different levels of phosphorus and nitrogen. Four levels of phosphorus (from 0.03 to 1 mM P) and two levels of nitrogen (0.71 and 6.45 mM N) were used to study P and N effects on these early stages of nodule development. KEY RESULTS: P at a medium concentration (0.1 mM) stimulated cell divisions in the cortex and a number of prenodules, nodule primordia and emerging nodules as compared with higher or lower P levels. A high N level inhibited early cell divisions in the cortex, and this was particularly evident when the length of cell division areas and presence of the nodulation stages were related to root length. CONCLUSIONS: Extended cortical cell division areas were found that have not been previously shown in A. incana. The results show that effects of P and N are already expressed at the stage when the first cortical cell divisions are induced by Frankia.