Frankia alni proteome under nitrogen-fixing and nitrogen-replete conditions

Frankia alni induces root nodules on Alnus , in which the bacterium differentiates into nitrogen (N)-fixing cells called vesicles. In culture, F. alni also undergoes major morphological changes as it alternates between N-replete and N-fixing conditions. Lack of biologically available N induces the synthesis of vesicles in which nitrogenase is protected from molecular oxygen by a thick lipid hopanoid envelope. Very little is known about the molecular basis of Frankia –host interaction as well as Frankia cell differentiation. The recent determination of the complete genome sequence of F. alni strain ACN14a has permitted us to characterize its proteome, particularly in the extracellular compartment, which could be involved in Frankia –host interaction, and in the switch from N-replete to N-fixing conditions. To that end, 126 bacterial proteins were analyzed by two-dimensional protein gel electrophoresis and identified by matrix-assisted laser desorption/ionization time of flight fingerprinting using a F. alni proteome database. Interestingly, the extracellular fraction contains some glycolytic enzymes lacking secretion signals, already reported to be extracellularly localized in some streptococci, as well as some abundant stress-resistance proteins. As expected, several proteins involved in N assimilation and oxidative defense system were upregulated in F. alni grown under N-fixing vs N-replete conditions. Furthermore, two Raf kinase inhibitor protein homologs that could play a role in cellular signaling, and a hemoglobin-like protein HbN that could be involved in detoxification of nitric oxide were also upregulated. More surprising, a succinate dehydrogenase was strongly downregulated, which could be linked to the need of pyruvate for the biosynthesis of hopanoids or to reduced oxygen diffusion in vesicles.     

Lipid composition and nitrogenase activity of symbioticFrankia (Alnus incana) in response to different oxygen concentrations

Summary The role ofFrankia vesicle envelope lipids in regulating oxygen diffusion of symbiotic nitrogen fixation inAlnus incana was examined. Total lipids of symbioticFrankia (vesicle clusters) that had been adapted to oxygen tensions of 5,21, or 40 kPa were analyzed with a normal phase HPLC system. During the oxygen treatment, nitrogenase activity was measured as hydrogen evolution in an open flow-through system. When plants were transferred to low oxygen (5 kPa) or high oxygen (40 kPa), nitrogenase activity dropped initially. Activity recovered in both treatments with a rate comparable to the controls (21 kPa O₂). Both lipid content and lipid composition of vesicle clusters were affected by the oxygen treatments. With increasing oxygen tension, the vesicle cluster lipid content increased. This correlated with structural data (fluorescence microscopy and TEM) which showed a thicker vesicle envelope at higher oxygen tension. Three hopanoid lipids, bacteriohopanetetrol (bht) and two isomers of phenylacetyl monoester of bht, made up approximately 80% of the vesicle cluster lipids. With changing oxygen concentrations, the ratio of the two bht esters changed whereas the relative proportion of bht remained fairly constant. Therefore, in theFrankia-Alnus incana symbiosis, adaptation to different ambient oxygen tensions occurs at least partly by increasing the thickness of theFrankia vesicle envelope and by changing its lipid composition.Abbreviations dw dry weight - bht bacteriohopanetetrol - SE standard error - TEM transmission electron microscopy Dedicated to the memory of Professor John G. Torrey     

Significant natural product biosynthetic potential of actinorhizal symbionts of the genus frankia, as revealed by comparative genomic and proteomic analyses

Bacteria of the genus Frankia are mycelium-forming actinomycetes that are found as nitrogen-fixing facultative symbionts of actinorhizal plants. Although soil-dwelling actinomycetes are well-known producers of bioactive compounds, the genus Frankia has largely gone uninvestigated for this potential. Bioinformatic analysis of the genome sequences of Frankia strains ACN14a, CcI3, and EAN1pec revealed an unexpected number of secondary metabolic biosynthesis gene clusters. Our analysis led to the identification of at least 65 biosynthetic gene clusters, the vast majority of which appear to be unique and for which products have not been observed or characterized. More than 25 secondary metabolite structures or structure fragments were predicted, and these are expected to include cyclic peptides, siderophores, pigments, signaling molecules, and specialized lipids. Outside the hopanoid gene locus, no cluster could be convincingly demonstrated to be responsible for the few secondary metabolites previously isolated from other Frankia strains. Few clusters were shared among the three species, demonstrating species-specific biosynthetic diversity. Proteomic analysis of Frankia sp. strains CcI3 and EAN1pec showed that significant and diverse secondary metabolic activity was expressed in laboratory cultures. In addition, several prominent signals in the mass range of peptide natural products were observed in Frankia sp. CcI3 by intact-cell matrix-assisted laser desorption-ionization mass spectrometry (MALDI-MS). This work supports the value of bioinformatic investigation in natural products biosynthesis using genomic information and presents a clear roadmap for natural products discovery in the Frankia genus.     

Isolation and structure of the lipid envelopes from the nitrogen-fixing vesicles of Frankia sp. strain CpI1.

Frankia vesicles are differentiated during nitrogen starvation; they contain nitrogenase whether produced by free-living frankiae or by frankiae in actinorhizal root nodules. Vesicles are surrounded by envelopes of several monolayers of uncharacterized lipid. It has been suggested that the envelope limits diffusion of O2 into the vesicle cytoplasm, thereby preventing inactivation of nitrogenase. Whole vesicles were prepared on sucrose gradients and sonicated, and vesicle envelopes were isolated on top of a cushion of 40% sucrose. Transmission electron microscopy of potassium permanganate-fixed envelopes confirmed the purity of these preparations. Only the outer and inner envelope layers were visible in permanganate-fixed intact vesicles; the laminae were not visible in aldehyde-osmium-fixed, lead citrate-uranyl acetate-stained whole vesicles. However, the laminated nature of the envelope was clearly evident in sonicated vesicles and in envelope fragments fixed with KMnO4. The observations indicate that partial disruption of the vesicle envelope enables its visualization with permanganate fixation, and these observations open the way for further studies on the relationship of the vesicle surface to environmental conditions.     

Novel hopanoids from Frankia spp. and related soil bacteria. Squalene cyclization and significance of geological biomarkers revisited.

Three series of hopanoids, differing by their configurations at C-17 and C-21, have been identified in several Frankia spp. and other related soil bacteria. The widespread bacterial hopanoids of the 17beta(H),21beta(H) series were accompanied by their isomers of the 17beta(H),21alpha(H) (moretane) and 17alpha(H), 21beta(H) series. The latter series has not previously been found in living organisms and is considered to be a result of the abiotic isomerization of the thermodynamically less stable 17beta(H),21beta(H) hopanoids. This simultaneous presence of three isomeric hopanoid series highlights intriguing problems in the biogenesis of the bacteriohopane skeleton and partly questions the significance of hopanic biomarkers in sediments.     

Capacity for hexose respiration in symbiotic Frankia from Alnus incana

Frankia vesicle clusters were prepared from Alnus incana (L.) Moench root nodules containing a local source of Frankia by an improved homogenization-filtration procedure. The capacity of the vesicle clusters to metabolize hexoses was investigated by respirometric and enzymological studies. The vesicle clusters could utilize glucose, glucose-6-phosphate and 6-phosphogluconate provided that appropriate cofactors were added to the preparations. The enzymes hexokinase (EC 2.7.1.1), NADP⁺: glucose-6-phosphate dehydrogenase (EC 1.1.1.49) and NAD⁺;6-phosphogluconate dehydrogenase (EC 1.1.1.44) were found in cell-free extracts of the vesicle clusters and kinetic constants for the enzymes were determined. Hexokinase had a lower K_m for glucose than for fructose. Extracts from both symbiotic and propionate grown Frankia AvcII also showed activity of these hexose-degrading enzymes, indicating that their presence is not necessarily dependent on sugars as carbon source. The NAD⁺- dependent 6-phosphogluconate dehydrogenase was only present in Frankia cells and not in alder root cells, which makes this enzyme a useful Frankia -specific marker in these symbiotic systems.     

Identification and characterization of Rhodopseudomonas palustris TIE-1 hopanoid biosynthesis mutants

Hopanes preserved in both modern and ancient sediments are recognized as the molecular fossils of bacteriohopanepolyols, pentacyclic hopanoid lipids. Based on the phylogenetic distribution of hopanoid production by extant bacteria, hopanes have been used as indicators of specific bacterial groups and/or their metabolisms. However, our ability to interpret them ultimately depends on understanding the physiological roles of hopanoids in modern bacteria. Toward this end, we set out to identify genes required for hopanoid biosynthesis in the anoxygenic phototroph Rhodopseudomonas palustris TIE-1 to enable selective control of hopanoid production. We attempted to delete 17 genes within a putative hopanoid biosynthetic gene cluster to determine their role, if any, in hopanoid biosynthesis. Two genes, hpnH and hpnG, are required to produce both bacteriohopanetetrol and aminobacteriohopanetriol, whereas a third gene, hpnO, is required only for aminobacteriohopanetriol production. None of the genes in this cluster are required to exclusively synthesize bacteriohopanetetrol, indicating that at least one other hopanoid biosynthesis gene is located elsewhere on the chromosome. Physiological studies with the different deletion mutants demonstrated that unmethylated and C(30) hopanoids are sufficient to maintain cytoplasmic but not outer membrane integrity. These results imply that hopanoid modifications, including methylation of the A-ring and the addition of a polar head group, may have biologic functions beyond playing a role in membrane permeability.     

Time course of nodule development in the Discaria trinervis (Rhamnaceae) –Frankia symbiosis

The time course of initiation and development of root nodules was investigated in the South American actinorhizal shrub Discaria trinervis (Rhamnaceae). A local strain of Frankia (BCU110501) which was isolated from D. trinervis nodules, was used as inoculum. Inoculated seedlings were periodically studied under the light microscope after clearing with aqueous NaClO. In parallel, semithin and ultrathin sections were analysed by light and electron microscopy. Infection by Frankia BCU110501 involved intercellular penetration among epidermal and cortical root cells. Nodule primordia were detected from 6 d after inoculation, while bacteria were progressing through intercellular spaces of the outer layers of cortical cells. Invasion of host cells by the symbiont occurred 7–9 d after inoculation, and hypertrophy of the primordium cells was associated with Frankia penetration. Root hairs were not deformed during the early events of nodule formation. From 13 to 16 d after inoculation, the proximal cellular zone of the primordia behaved differently from the other tissues after NaClO treatment and remained darkly pigmented. At the same time, differentiation of Frankia vesicles started to occur inside already infected cells. By 16 d after inoculation, spherical vesicles of BCU110501 were homogeneously distributed in the host cells. These vesicles were septate and surrounded by void space. Frankia spores or sporangia were not observed in the nodule tissue. This study has clarified the mode of Frankia penetration in D. trinervis , one of the Rhamnaceae which also includes Ceanothus . The events involved in infection, nodule induction, host-cell infection and vesicle differentiation have been characterized and identified as time-segregated developmental processes in the ontogeny of D. trinervis root nodules.     

Purity of Frankia preparations from root nodules of Alnus incana

Frankia vesicle clusters were prepared from Alnus incana (L.) Moench root nodules by a homogenization-filtration procedure. The preparation was examined by transmission electron microscopy and computerized picture analysis to quantify contamination from the host plant. Special attention was paid to plant mitochondria. Mitochondria were only found in 30% of the 50 sections of clusters examined. In sections containing mitochondria the mean number of mitochondria per cluster section was 1.5. The relative volume of all objects found in the vesicle clusters was calculated. More than 98% of the volume of a preparation consisted of Frankia vesicles and hyphae, while only 0.4% of the volume was host plant mitochondria. The frequency of mitochondria in a preparation could be further decreased by osmotic shock. It is concluded that Frankia vesicle clusters, prepared from Alnus incana by the homogenization-filtration technique used here, are sufficiently pure to be used for studies of Frankia metabolism.     

Gas vesicles in actinomycetes: old buoys in novel habitats?

Gas vesicles are gas-filled prokaryotic organelles that function as flotation devices. This enables planktonic cyanobacteria and halophilic archaea to position themselves within the water column to make optimal use of light and nutrients. Few terrestrial microbes are known to contain gas vesicles. Genome sequences that have become available recently for many bacteria from non-planktonic habitats reveal gas vesicle gene clusters in members of the actinomycete genera Streptomyces, Frankia and Rhodococcus, which typically live in soils and sediments. Remarkably, there is an additional level of complexity in cluster number and gene content. Here, we discuss whether putative gas vesicle proteins in these actinomycetes might actually be involved in flotation or whether they might fulfil other cellular functions.     

Symbiosis between Frankia and actinorhizal plants: root nodules of non-legumes

In actinorhizal symbioses, filamentous nitrogen-fixing soil bacteria of the genus Frankia induce the formation of nodules on the roots of a diverse group of dicotyledonous plants representing trees or woody shrubs, with one exception, Datisca glomerata. In the nodules, Frankia fixes nitrogen and exports the products to the plant cytoplasm, while being supplied with carbon sources by the host. Possibly due to the diversity of the host plants, actinorhizal nodules show considerable variability with regard to structure, oxygen protection mechanisms and physiology. Actinorhizal and legume-rhizobia symbioses are evolutionary related and share several features.     

Amplification of 16S rRNA genes from Frankia strains in root nodules of Ceanothus griseus, Coriaria arborea, Coriaria plumosa, Discaria toumatou, and Purshia tridentata.

To study the global diversity of plant-symbiotic nitrogen-fixing Frankia strains, a rapid method was used to isolate DNA from these actinomycetes in root nodules. The procedure used involved dissecting the symbiont from nodule lobes; ascorbic acid was used to maintain plant phenolic compounds in the reduced state. Genes for the small-subunit rRNA (16S ribosomal DNA) were amplified by the PCR, and the amplicons were cycle sequenced. Less than 1 mg (fresh weight) of nodule tissue and fewer than 10 vesicle clusters could serve as the starting material for template preparation. Partial sequences were obtained from symbionts residing in nodules from Ceanothus griseus, Coriaria arborea, Coriaria plumosa, Discaria toumatou, and Purshia tridentata. The sequences obtained from Ceonothus griseus and P. tridentata nodules were identical to the sequence previously reported for the endophyte of Dryas drummondii. The sequences from Frankia strains in Coriaria arborea and Coriaria plumosa nodules were identical to one another and indicate a separate lineage for these strains. The Frankia strains in Discaria toumatou nodules yielded a unique sequence that places them in a lineage close to bacteria that infect members of the Elaeagnaceae.     

Nitrogenase activity decay and energy supply in Frankia after addition of ammonium to the host plant Alnus incana

A clone of Alnus incana (L.) Moench was grown in symbiosis with a local source of Frankia or with Frankia Ar14. Seven to 9-week-old plants were given 20 m M NH₄Cl (20 m M KCl = control) for 3 days. Nitrogenase activity of intact plants decreased gradually within the 3 days of treatment to about 10% of the initial rates. Hydrogen evolution in air and total nitrogenase activity responded similarly to the treatment. Relative efficiency of nitrogenase thus remained the same throughout the study period. Control plants were not affected. Measurements of nitrogenase activity in root nodule homogenates (in vitro measurements) indicated loss of active nitrogenase rather than shortage of energy for nitrogenase activity in Frankia from ammonium-treated plants. Shoots were exposed to ¹⁴CO₂ and translocation of ¹⁴C to Frankia vesicle clusters prepared from root nodules was studied. Frankia vesicle clusters from ammonium-treated plants contained about half as much ¹⁴C as those of control plants during all 3 days studied. One explanation for the observed effects is that a reduced supply of carbon to Frankia vesicles in the root nodules caused a reduced metabolic rate, including reduced protein synthesis and synthesis of nitrogenase.     

The occurrence of hopanoid lipids in Bradyrhizobium bacteria

Abstract Lipid extraction procedures followed by GLC and GLC-MS analysis were used to investigate the triterpenoid content in Bradyrhizobium and Rhizobium bacteria. Unlike the tested strains of Rhizobium bacteria, a range of triterpenoids e.g., squalene and different classes of hopanoid derivatives were detected in bacteria from all Bradyrhizobium strains investigated (different strains from Bradyrhizobium japonicum, Bradyrhizobium elkanii as well as Bradyrhizobium sp.). Furthermore, related compounds were identified from some hopanoid lipids (e.g., diplopterol) that carried an additional methyl group in their molecular structure. The hopanoid content was high in some strains and accounted for more than 40% of the total lipid fraction (e.g., in strains Bradyrhizobium japonicum USDA 110 and USDA 31), while other strains contained only about a tenth of that amount (e.g., Bradyrhizobium japonicum ATCC 10324 and Bradyrhizobium sp. ( Lupinus ) ATCC 10319).     

Hopanoid production is required for low-pH tolerance, antimicrobial resistance, and motility in Burkholderia cenocepacia

Hopanoids are pentacyclic triterpenoids that are thought to be bacterial surrogates for eukaryotic sterols, such as cholesterol, acting to stabilize membranes and to regulate their fluidity and permeability. To date, very few studies have evaluated the role of hopanoids in bacterial physiology. The synthesis of hopanoids depends on the enzyme squalene-hopene cyclase (Shc), which converts the linear squalene into the basic hopene structure. Deletion of the 2 genes encoding Shc enzymes in Burkholderia cenocepacia K56-2, BCAM2831 and BCAS0167, resulted in a strain that was unable to produce hopanoids, as demonstrated by gas chromatography and mass spectrometry. Complementation of the Δshc mutant with only BCAM2831 was sufficient to restore hopanoid production to wild-type levels, while introducing a copy of BCAS0167 alone into the Δshc mutant produced only very small amounts of the hopanoid peak. The Δshc mutant grew as well as the wild type in medium buffered to pH 7 and demonstrated no defect in its ability to survive and replicate within macrophages, despite transmission electron microscopy (TEM) revealing defects in the organization of the cell envelope. The Δshc mutant displayed increased sensitivity to low pH, detergent, and various antibiotics, including polymyxin B and erythromycin. Loss of hopanoid production also resulted in severe defects in both swimming and swarming motility. This suggests that hopanoid production plays an important role in the physiology of B. cenocepacia.     

Biology of Frankia strains, actinomycete symbionts of actinorhizal plants.

Frankia strains are N2-fixing actinomycetes whose isolation and cultivation were first reported in 1978. They induce N2-fixing root nodules on diverse nonleguminous (actinorhizal) plants that are important in ecological successions and in land reclamation and remediation. The genus Frankia encompasses a diverse group of soil actinomycetes that have in common the formation of multilocular sporangia, filamentous growth, and nitrogenase-containing vesicles enveloped in multilaminated lipid envelopes. The relatively constant morphology of vesicles in culture is modified by plant interactions in symbiosis to give a diverse array of vesicles shapes. Recent studies of the genetics and molecular genetics of these organisms have begun to provide new insights into higher-plant-bacterium interactions that lead to productive N2-fixing symbioses. Sufficient information about the relationship of Frankia strains to other bacteria, and to each other, is now available to warrant the creation of some species based on phenotypic and genetic criteria.     

Recent advances in the biogeography and genecology of symbiotic Frankia and its host plants

Molecular phylogenetic approaches have begun to outline the origin, distribution and diversity of actinorhizal partners. Geographic isolation of Frankia and its host plants resulting from shifting continents and dispersal patterns have apparently led to the development of Frankia genotypes with differing affinities for host genera, even within the same plant family. Actinorhizal plant genera of widespread global distribution tend to nodulate readily even outside their native ranges. These taxa may maintain infective Frankia populations of considerable diversity on a broad scale. Arid environments seem to have distinctive actinorhizal partnerships, with smaller and more specific sets of Frankia symbionts. This has led to the hypothesis that some host families have taxa that are evolving towards narrow strain specificity, perhaps because of drier habitats where fewer Frankia strains would be able to survive. Harsh conditions such as water-saturated soils near lakes, swamps or bogs that are typically acidic and low in oxygen may similarly lessen the diversity of Frankia strains present in the soil, perhaps limiting the pool of frankiae available for infection locally and, at a larger scale, for natural selection of symbiotic partnerships with host plants. Recent molecular ecological studies have also provided examples of Frankia strain sorting by soil environment within higher order cluster groupings of Frankia host specificity. Future frontiers for ecological research on Frankia and actinorhizal plants include the soil ecosystem and the genome of Frankia and its hosts.     

Bacterial triterpenoids of the hopane series as biomarkers for the chemotaxonomy of Burkholderia, Pseudomonas and Ralstonia spp

Hopanoid fingerprints allowed to differentiate bacteria formerly connected to the genus Pseudomonas. Whereas all strains related to Pseudomonas and Ralstonia were devoid of any detectable hopanoid, these pentacyclic triterpenoids were found in the Burkholderia species and in related soil isolates, which contained as main hopanoid a bacteriohopanetetrol carbapseudopentose ether, accompanied by significant amounts of its novel Delta(6) unsaturated homologue. Unsaturated hopanoids represent an extremely rare feature in soil bacteria and the only known indication for a catabolism of this pentacyclic carbon skeleton in bacteria.