Feedback regulation of nodule formation in Hippophaë rhamnoides

Seedlings of Hippophaë rhamnoides possessing two equally infectible root systems (split roots) were used in conjunction with specific Frankia strains to investigate plant control over nodulation. When a wild-type Frankia strain was inoculated onto both root systems simultaneously or 1, 2, 4, or 8 weeks apart, an inhibitory response occurred which retarded nodulation on the root exposed to the delayed inoculum. Similar suppressive responses were also observed when two different wild-type Frankia inocula were applied onto opposite sides of a split-root system at different times. The depressed response shown by the delayed inoculum was more pronounced as the delay period was increased. The roots exposed to the delayed inoculum displayed a complete lack of nodulation when the delay was 4 or 8 weeks. The nodulation response on the root inoculated first depended on subsequent inoculation of the second root system of the plant, so that maximum nodulation of the first root was observed when the second root was unnodulated. These results provide evidence that sea buckthorn has an active, systemic mechanism for feedback control of nodulation that suppresses further nodule formation and prevents excessive nodulation. The significance of these results to the understanding of nodule ontogeny is discussed.     

Non-photosynthetic effects of red and far-red light on root-nodule formation by leguminous plants

Summary Nodulation of pea and broad bean plants grown in the light was found to be reduced when the roots were exposed to far-red light for 5–15 minutes daily during 5 consecutive days following inoculation with nodule bacteria. Similar results were obtained following a single exposure to far-red light during a period of 15 minutes at the 3rd or 4th day after inoculation. When the roots were exposed to far-red light either before inoculation or during the first two days afterwards there were either no effects or only slight effects on nodulation The inhibitory effect of far-red light on nodulation was partly reduced by subsequent exposure to red light, provided that the same part of the plant was exposed to both red and far-red light,viz either the root or the shoot. When different parts of the plant were exposed to red and far-red light respectively, there was no interaction between the two kinds of light on nodulation. Plants whose roots were exposed to far-red light did not subsequently show stem elongation.Nodules were found to develop on the roots of pea plants grown in the dark, provided that the plants were kept at or below 22°C. At 25°C nodulation was almost absent. Nodulation was decreased by addition of kinetin and IAA. In contrast to plants grown in the light pea plants grown in the dark, inoculated with either an effective or ineffective strain of Rhizobium, developed equal numbers of nodules. Exposure to red light slightly increased the percentage of nodulated plants but decreased the number of nodules per plant. Exposure to far-red light slightly decreased both the percentage of nodulated plants and the number of nodules per plant. The effect of far-red light was counteracted by red light andvice versa.     

Carbohydrate binding activities of Bradyrhizobium japonicum III. Lectin expression, bacterial binding, and nodulation efficiency

In previous studies, evidence that the Bradyrhizobium japonicum lectin, designated BJ38, mediated the observed carbohydrate-specific binding activities of the bacteria, including the saccharide-specific adhesion to soybean root cells was presented. In the present study, it is found that both B. japonicum, as well as the purified BJ38, bind predominantly to young emergent root hairs of soybean roots and, to a much lesser extent, to the root cap, mature root hairs, epicotyl or hypocotyl regions. Thus, the region of preferential binding for both the bacteria and the isolated lectin coincide with the region of the soybean root most susceptible to B. japonicum infection. The importance of bacterial binding for the nodulation process was studied by comparing the nodulation efficiency of binding-deficient mutants N4 and N6 to the wild-type. These mutants had been shown to be defective in carbohydrate recognition, as represented by their diminished ability to bind to soybean roots. BJ38 was immunolocalized to one pole of the cell surface of wild-type B. japonicum, but no surface labeling could be detected on either mutant. Moreover, both N4 and N6 showed a substantial decrease in nodulation activity, relative to the wild-type. These results provide additional evidence that the carbohydrate binding activity of B. japonicum, most probably mediated by BJ38, may play an important role(s) in the initial phases of the infection process.     

EFFECTS OF LIGHT INTENSITY ON DIVISION RATE,STIMULABLE BIOLUMINESCENCE AND CELL SIZE OF THE OCEANIC DINOFLAGELLATES DISSODINIUM LUNULA,PYROCYSTIS FUSIFORMIS AND P. NOCTILUCA12

Preadapted cultures were grown in a 12:12 LD cycle at a series of light intensities under cool-white, fluorescent lamps. Pyrocystis fusiformis Murray maintained high division rates at low light intensities at the expense of cell size. In contrast, Dissodinium lunula (Schuett) Taylor had relatively lower division rates at low light intensities with little concomitant decrease in size. The response of P. noctiluca Murray was intermediate between these two species. For all three, cell numbers did not increase above an intensity of 5–10 μEin·m^?2·sec^?1 and division rate was saturated at ca. 30, 60, and 60μEin·m^?2·sec^?1 for P. fusiformis, P. noctiluca, and D. lunula, respectively. The capacity for stimulable bioluminescence was saturated at light intensities of 0.15 μEin·m^?2·day in short-term (2-day) experiments. In cultures of P. fusiformis and P. noctiluca, maintained for at least one month at lower intensities than needed to saturate division rate, a decrease in the capacity for stimulable bioluminescence was accompanied by a reduction in cell size. Our results suggest that cell size and bioluminescent capacity may prove to be a potentially useful indication of the history of exposure of natural populations of Pyrocystis spp. to ambient intensities.     

Devising an <Emphasis Type="Italic">in vitro</Emphasis> nodulation system for two actinorhizal plants: <Emphasis Type="Italic">Allocasuarina verticillata</Emphasis> (Lam.) L. Johnson and <Emphasis Type="Italic">Casuarina glauca</Emphasis> sieb. ex spreng (Casuarinaceae)

Summary The purpose of this study was to establish an efficient in vitro nodulation device for producing actinorhizal root nodules on Allocasuarina verticillata and Casuarina glauca. Seeds from the two species were germinated aseptically and seedlings with at least two photosynthetic branchlets and a 3–5 cm long root system were transferred into Petri dishes containing a biphasic (solid/liquid) medium. To assess the nodulation capacity, four different culture media were tested. As soon as the root system developed and spread adequately on the surface of the medium, plants were deprived of nitrogen for at least 1 wk and inoculated with the Frankia strain. The time course nodulation for A. verticillata showed that the basal Hoagland medium supplemented with CaCO₃ and KNO₃ was most efficient, with 83% of plantlets forming nodules, while the medium supplemented with CaCO₃ reached 100% nodulation for C. glauca. This procedure can provide a valuable tool for the study of early events of actinorhizal nodulation and spatio-temporal expression of symbiotic genes in transgenic Casuarinaceae.     

Effect of nutrient medium pH on symbiotic nitrogen fixation byRhizobium leguminosarum andPisum sativum

Summary Experiments were performed to measure the pH-sensitive steps in nodulation and symbiotic fixation byPisum sativum and isolate RP-212-1 ofRhizobium leguminosarum. An aeroponic system with rigorous pH control was used to obtain numerous effective nodules. After exposure to various pH levels, the following responses were measured: (1) legume root growth and development, (2) survival and growth rate of a single effective bacterial isolate, (3) degree of nodulation, (4) rate of nitrogen fixation, (5) plant biomass, and (6) nitrogen content of plants. Both bacterial growth and root development were adequate at all pH levels from 4.4 to 6.6, but efficient nodulation and nitrogen fixation did not occur at pH 4.8 and below. The processes required for symbiosis were about 10 times as sensitive to acidity as either bacterial growth or root growth alone. Nodulation was the most acid-sensitive step.     

Studies on the Physiology of Nodule Formation: IX. The Influence of Combined Nitrogen, Glucose, Light Intensity and Day Length on Root-hair Infection in Clover

Small amounts of nitrate or nitrite salts (10 µg N/plant)in the root medium of Trifolium glomeratum or T. repens delayednodulation, prolonged the initial rapid phase of root infectionand slightly stimulated lateral root formation, whereas equivalentquantities of ammonium sulphate or urea did not. Growth of rootsand root hairs was unaffected by any of these substances at10 µg N/plant. Altering the carbohydrate status of the clover seedlings byadding glucose to the root medium, or by changing day lengthor light intensity, influenced neither the stimulation of root-hairinfection nor the delay in nodulation induced by nitrate at10 fig N/plant, except that plants grown in total darkness hadfewer hairs infected when the root medium contained small amountsof nitrate. The nitrogenous compounds at 100 µg to 1,000 µg N/plant generally delayed and decreased nodulation,increased lateral root formation, slowed hair infection, andincreased root growth.     

Yield,root morphology and chemical composition of two pasture legumes as affected by lime and phosphorus applications to an acid soil

Summary Effects of increasing rates of lime (0, 900, 1725, and 3000 kg Ca(OH)₂/ha producing soil pH of 4.0, 4.7, 5.1 and 5.6) and P (50, 150, 250 and 350 kg P/ha) on top and root yield, root morphology and chemical composition of lotus (Lotus pedunculatus Cav.) and white clover (Trifolium repens L.), were studied, using an acid soil in a greenhouse experiment. Increasing rates of applied lime and phosphate resulted in substantial increases in top yields of both species but concomitant increases in root yield were small. In the unlimed soil, lotus out-yielded (tops and roots) white clover at all P levels. However, in the three limed treatments, white clover clearly out-yielded lotus. Yield response curves to applied P levelled off at the two highest lime rates for lotus but not for white clover. Nodulation and N content of white clover increased significantly with increasing lime applications, but for lotus there was a significant decrease in nodulation at the highest lime rate. Increased P rates had a small stimulatory effect on nodulation in both species. Of the total root weight, the percentage contribution of the tap and primary lateral root fractions was smaller and that of the secondary plus tertiary lateral roots was greater for lotus than for white clover although root length per unit weight tended to be larger for white clover at the two highest lime rates. Furthermore, lotus possessed longer and more numerous root hairs than white clover. Lime applications significantly decreased the percentage contribution of the tap and primary lateral roots to the total root weight and increased the percentage contribution of the secondary plus tertiary lateral roots. Al and Mn contents of tops and roots of both species decreased with increasing lime rates. There was a highly significant negative correlation between relative yield and Al content of lotus and white clover tops. In comparison with the limed treatments, in the unlimed treatments a greater percentage of total P, Al, Mn and N content accumulated in the roots of both species. In addition, lotus accumulated a much greater percentage Al in its roots than white clover.     

Germintion,nodulation and early growth response of a hard-seeded legume,Lathyrus sylvestris L. (flatpea)

Summary Flatpea (Lathyrus sylvestris L.) requires seed scarification for rapid germination and specificRhizobium leguminosarum strain for nodulation. Methods of inoculation were investigated to determine which would be effective for at least two weeks after seeding. Application of powdered peat to wet seeds was inadequate. Lime pelleting and granular soil implants were effective inoculants, but there appears to be a different advantage to seedling for earch metod. Granular soil implant caused nodulation to a greater depth on the tap root, and lime pelleting caused plants to exhibit higher acetylene reduction activity.     

Rhizobium nodulation genes involved in root hair curling (Hac) are functionally conserved

Summary Five specific transposon-induced nodulation defective (Nod⁻) mutants from different fast-growing species ofRhizobium were used as the recipients for the transfer of each of several endogenous Sym(biosis) plasmids or for recombinant plasmids that encode early nodulation and host-specificity functions. The Nod⁻ mutants were derived fromR. trifolii, R. meliloti and from a broad-host-rangeRhizobium strain which is able to nodulate both cowpea (tropical) legumes and the non-legumeParasponia. These mutants had several common features (a), they were Nod⁻ on all their known plant hosts, (b), they could not induce root hair curling (Hac⁻) and (c), the mutations were all located on the endogenous Sym-plasmid of the respective strain. Transfer to these mutants of Sym plasmids (or recombinant plasmids) encoding heterologous information for clover nodulation (pBR1AN, pRt032, pRt038), for pea nodulation (pJB5JI, pRL1JI::Tn1831), for lucerne nodulation (pRmSL26), or for the nodulation of both tropical legumes and non-legumes (pNM4AN), was able to restore root hair curling capacity and in most cases, nodulation capacity of the original plant host(s). This demonstrated a functional conservation of at least some genes involved in root hair curling. Positive hybridization between Nod DNA sequences fromR. trifolii and from a broad-host-rangeRhizobium strain (ANU240) was obtained to other fast-growingRhizobium strains. These results indicate that at least some of the early nodulation functions are common in a broad spectrum ofRhizobium strains.     

Inibizione della nodulazione radicale nel pisello meteor come conseguenza del trattamento nictofasico intermittente con luce rosso-estrema

Abstract

INHYBITION OF NODULATION IN METEOR PEA, BY NICTOPHASIC TREATMENT WITH FAR-RED RADIATION. — A remarkable inhybiting effect of far-red light (given to the aerial part of the plants as a flash befor and during the nictophase) on Pea root nodulation, has been achivied through some preliminary experiments. The relations between irradiated aerial parts and the activities of the underground organs in general, are being studied in the picture of photo-chromoperiodism.

Relations with the action of gibberellic acid (GA) are preliminary attempted. The inhibiting action of GA is far less striking in comparison with that of far-red radiation. Kinetin favores, at some extent, the nodulation process.     

Monoxenic nodulation process of Acacia mangium (Mimosoideae, Phyllodineae) by Bradyrhizobium sp

Acacia mangium Willd., a native tree in Australia and Papua New Guinea, has been introduced to countries in Asia and South America where plantations have been established that cover several hundred thousand ha. The present study investigated the early stages of the nodulation process in A. mangium using an homologous Australian Bradyrhizobium strain. After optimizing the axenic nodulation, histological and cytological studies were conducted using light and electron microscopy. These documented the proliferation of Bradyrhizobium, the lysis of mucilage at the root surface, root hair deformation and initiation, as well as the development and growth of multiple infection threads. A belt of tannin-filled cells was shown to surround the central nodular fixation zone. The nodules were of the indeterminate type and the bacteroids had a rod shape, without size modification and with few polyhydroxybutyrate (PHB) granules. Several bacteroids can share the same symbiosome. A. mangium exhibits both classical and novel features in its nodulation.     

The nodulation and nitrogen fixation of isolated roots of Phaseolus vulgaris L.

Summary The exposure of isolated bean roots to white light immediately before inoculation with nodule bacteria stimulated nodulation during a subsequent 7-day dark period. Strong white light applied to inoculated roots for 3 days or longer suppressed nodulation except when the light was applied immediately after inoculation and the duration of the light period did not exceed 3 days. Alternating periods of 12 hours light and 12 hours darkness were almost as inhibitory to nodulation as a continuous exposure to light. A combination of blue and far-red light inhibited nodule formation more than a combination of red and far-red light. Light treatments that inhibited nodulation also suppressed the production of lateral roots, but to a lesser extent. The effect of light on nodulation and lateral root formation was not influenced by the presence or absence of an attached hypocotyl segment in the explant.     

Root temperature and root-hair infection ofTrifolium subterraneum L. cv. Cranmore

Summary The infection of root hairs and nodulation ofT. subterraneum L. cv. Cranmore byRhizobium trifolii strain TA1 was extremely sensitive to root temperature. Within the range 11°–19°C infection was progressively delayed as root temperature decreased but at 7°C no root hairs were infected by 40 days. At 7°C lateral root formation was stimulated in the root zone where nodules formed at 19°C.     

DEVELOPMENTAL ANATOMY OF LIGHT-INDUCED ROOT NODULATION BY ZAMIA PUMILA L. SEEDLINGS IN STERILE CULTURE

The developmental anatomy of Zamia pumila L. root apices was studied during light-induced nodulation. Dark-grown roots had an apical organization identical to that of other cycads and similar to that of other gymnosperms. A distinct protoderm was not observed in these roots, which had a large open meristem and a root cap with a well-defined columella. During nodulation, the meristem became reduced in size, and its constituent cells became vacuolate until all but a few resembled ground tissue. The root cap senesced during nodulation, and a recognizable root cap was absent from mature nodules. A file of densely cytoplasmic cells with centrally positioned nuclei developed in the nodule cortex. This layer was continuous across the nodule apex, and was identical to the presumptive algal-zone described previously by other authors. Light-induced nodules branched dichotomously and were identical to algal-free nodules described by other authors. In dichotomously branched nodules, each lobe was covered by a parenchymatous mantle analogous to a root cap. A unicellular layer similar to the presumptive algal zone spanned the gap between opposite nodule lobes, and extended beneath each lobe before terminating in the cortex. Typical meristematic regions were not observed in these nodules. Based on cell sizes and patterns, a meristematic zone was thought to exist between the mantle and the inner cortex.     

SUN-SHADE ECOTYPES OF A BLUEGREEN ALGA IN A HOT SPRING1,2

Clone cultures of the thermophilic alga Plectonema notatum Schmidle were established from cells collected from the high and low light intensity regions of the algal mat which developed in Jerry Johnson Hot Spring, Idaho. Clones isolated from cither high, or low light intensify zones were grown at light intensities of 8000 and 400 ft-c. The existence of specialized and genetically fixed sun or shade ecotypes was evidenced, by the ability of low light intensity clones to synthesize more light harvesting chlorophyll a when grown under low light conditions than the high light clones. High light clones showed light saturation of photosynthesis at higher light intensities with higher carboxylating enzyme activities and less chlorophyll a than low light clones when both were cultured at 8000 ft-c. These clones displayed infraspecific variation along the light intensity gradient and therefore exist as a mosaic of light, intensity ecotypes.     

Root exuded nod-gene inducing signals limit the nodulation capacity of different alfalfa varieties with Rhizobium meliloti

Summary Different nodulation capacities were found among nine different varieties of alfalfa, cultivated in the Central region of Mexico, by Rhizobium meliloti 2011. A correlation between nodulation capacity and foliar dry weight was observed, which points to a genotype dependance on these parameters. A correlation between the nodulation capacity and the R. meliloti nod-gene inducing activity of the root exudates from the different varieties, as measured by -galactosidase induction in a test system consisting of a R. meliloti nodC-lacZ strain incubated with each root exudate, was established. When the root exudate from the best nodulating variety was added to the four poorest nodulating varieties, an increase in nodule formation was observed. We conclude that root exuded nod-gene inducing signals are a symbiotically-limiting component in natural populations of the poorest nodulating varieties of alfalfa.     

氮肥和水分条件对长喙田菁生长、结瘤和固氮的影响

 盆栽试验研究了长喙田菁(Sesbania rostrata) 茎瘤固氮根瘤菌（Azorhizobium caulinodans）共生体系在不同水分和无机氮肥条件下的生长、结瘤和氮积累。水分处理为: 不浸水、浅浸水(土壤水分为田间持水量)和深浸水, 氮肥处理分别为每千克土施加无机氮肥10 mg、20 mg和40 mg。结果表明,水分条件对共生体系有较大影响, 浸水环境虽然抑制了根瘤的形成, 却促进了茎瘤的结瘤作用和长喙田菁根系的生长, 田间持水量状态下共生体系能获得最大的生物量和氮累积量; 无机氮肥对共生体系的影响受水分供应的影响较大,实验氮肥施用浓度范围内,长喙田菁的结瘤作用对复合态氮无负敏感反应,明显有别于一般根瘤体系的复合态氮反应。