Root border cells take up and release glucose-C

BACKGROUND AND AIMS: Border cells are released from the root tips of many plant species, and can remain viable in the rhizosphere for 1 week. Whether border cells are capable of controlled glucose exchange with their environment was investigated. METHODS: Border cells were removed from Zea mays L. root tips, and immersed in (14)C-labelled D-glucose. In one experiment, the hexose transport inhibitor, phlorizin, was used to investigate active glucose uptake from a range of glucose concentrations. In another experiment, glucose efflux from border cells was monitored over time. KEY RESULTS: Glucose uptake by the border cells increased with increasing glucose concentration from 0.2 to 20 mm. At 0.2 mm glucose, uptake was mainly active, as evidenced by the approx. 60 % inhibition with phlorizin. At 2 and 20 mm glucose, however, uptake was mainly via diffusion, as phlorizin inhibition was negligible. Glucose efflux increased with time for live border cells in both 2 and 20 mm glucose. There was no clear efflux/time pattern for heat-killed border cells. CONCLUSIONS: Border cells actively take up glucose, and also release it. Under our experimental conditions, glucose uptake and efflux were of similar order of magnitude. In the rhizosphere net glucose exchange will almost certainly depend on local soil conditions.     

Cyclic beta-glucans of members of the family Rhizobiaceae.

Cyclic beta-glucans are low-molecular-weight cell surface carbohydrates that are found almost exclusively in bacteria of the Rhizobiaceae family. These glucans are major cellular constituents, and under certain culture conditions their levels may reach up to 20% of the total cellular dry weight. In Agrobacterium and Rhizobium species, these molecules contain between 17 and 40 glucose residues linked solely by beta-(1,2) glycosidic bonds. In Bradyrhizobium species, the cyclic beta-glucans are smaller (10 to 13 glucose residues) and contain glucose linked by both beta-(1,6) and beta-(1,3) glycosidic bonds. In some rhizobial strains, the cyclic beta-glucans are unsubstituted, whereas in other rhizobia these molecules may become highly substituted with moieties such as sn-1-phosphoglycerol. To date, two genetic loci specifically associated with cyclic beta-glucan biosynthesis have been identified in Rhizobium (ndvA and ndvB) and Agrobacterium (chvA and chvB) species. Mutants with mutations at these loci have been shown to be impaired in their ability to grow in hypoosmotic media, have numerous alterations in their cell surface properties, and are also impaired in their ability to infect plants. The present review will examine the structure and occurrence of the cyclic beta-glucans in a variety of species of the Rhizobiaceae. The possible functions of these unique molecules in the free-living bacteria as well as during plant infection will be discussed.     

Nodulation of acacia species by fast- and slow-growing tropical strains of Rhizobium

Thirteen Acacia species were classified into three groups according to effective nodulation response patterns with fast- and slow-growing tropical strains of Rhizobium. The first group nodulated effectively with slow-growing, cowpea-type Rhizobium strains; the second, with fast-growing Rhizobium strains; and the third, with both fast- and slow-growing Rhizobium strains. The Rhizobium requirements of the Acacia species of the second group were similar to those of Leucaena leucocephala.     

Intestinal handling of a glucose gavage by the rat

An oral gavage of either 3, 1 or 0.1 mmoles of ¹⁴C-labelled glucose was given to rats under standard feeding conditions or food deprived for 24 hr. The fate of the glucose label was determined at 10, 15, 30 and 60 min after gavage; at 60 min 40% of the glucose was absorbed in fed rats (60% in food deprived). The portal vein blood flows were determined and the levels of glucose, lactate, alanine and pyruvate, and their radioactivity, as well as that of CO, were measured in both portal and arterial blood.The net computed glucose and 3-carbon carriers (lactate, alanine and pyruvate) actually released into the portal system by the intestine was lower than the amount of glucose taken up from the intestinal lumen in one hour. Oxidation to ¹⁴CO₂ accounted for a 12–15% of the absorbed glucose. The size of the gavage deeply affected the proportion of glucose released into the portal blood (c. 50% with a 3 mmoles gavage and practically nil with a 0.1 mmoles gavage), but it affected much less the generation of lactate and other 3 C carriers. In fed rats, the net intestinal balance of non-radioactive glucose was negative, and that of lactate positive; when radioactive glucose was considered, the pattern was inverted. In starved rats, both glucose and lactate were released in large proportions by the intestine, but alanine efflux was lower.It can be concluded that the intestine consumes a considerable proportion of glucose in the fed state. Glucose handling by the intestine is compartmentalized in two functional circuits: glucose is taken up from the arterial blood and used for intestinal metabolism and lactate production, luminal glucose is absorbed mainly unaltered and transferred to the portal blood. Thus, the generation of lactate is mainly related to the availability of arterial glucose. In addition to the release of the ingested glucose as 3 C carriers or glucose, an extraportal pathway for glucose transfer into the bloodstream is postulated.     

Indole acetic acid production by a Rhizobium species from root nodules of a leguminous shrub, Cajanus cajan

A Rhizobium sp. isolated from the root nodules of a leguminous pulse-yielding shrub, Cajanus cajan, was found to produce high amounts (99.7 microg/ml) of indole acetic acid (IAA) during growth in basal medium supplemented with L-tryptophan. The Rhizobium sp. was a fast growing species which reached its stationary phase at 28 h. The IAA production could be increased upto 653.3% over control by supplementing the carbon-free incubation medium with glucose (5 g/l), NiCl2 (10 microg/ml) and glutamic acid (0.5 g/l). The possible role of rhizobial IAA on the rhizobia-legume symbiosis is discussed.     

Isolation of Rhizobium leguminosarum (biovar trifolii) Strains from Ethiopian Soils and Symbiotic Effectiveness on African Annual Clover Species

Strains of Rhizobium leguminosarum (biovar trifolii) isolated from two Ethiopian soils or obtained from a commercial source were evaluated for symbiotic effectiveness on five African annual clover species. Numerous Rhizobium trifolii strains that exhibited varying levels of symbiotic effectiveness were isolated from both soils (a nitosol and a vertisol), and it was possible to identify strains that were highly effective for each clover species. The soil isolates were, as a group, superior to the strains from the commercial source. Several R. trifolii strains were found to be effective on more than one clover species, and there appeared to be at least two and possibly three distinct cross-inoculation effectiveness groups.     

Comparative properties of glutamine synthetases I and II in Rhizobium and Agrobacterium spp

Some properties of glutamine synthetase I (GSI) and GSII are described for a fast-growing Rhizobium sp. (Rhizobium trifolii T1), a slow-growing Rhizobium sp. (Rhizobium japonicum USDA 83), and Agrobacterium tumefaciens C58. GSII of the fast-growing Rhizobium sp. and GSII of the Agrobacterium sp. were considerably more heat labile than GSII of the slow-growing Rhizobium sp. As previously shown in R. japonicum 61A76, GSI became adenylylated rapidly in all species tested in response to ammonium. GSII activity disappeared within one generation of growth in two of the strains, but the disappearance of GSII activity required two generations in another. Isoactivity points for transferase assay, which were derived from the pH curves of adenylylated GSI and deadenylylated GSI, were approximately pH 7.8 for both R. trifolii and A. tumefaciens. No isoactivity point was found for R. japonicum under the standard assay conditions used. When the feedback inhibitor glycine was used to inhibit differentially the adenylylated GSI and deadenylylated GSI of R. japonicum, an isoactivity point was observed at pH 7.3. Thus, the transferase activity of GSI could be determined independent of the state of adenylation. A survey of 23 strains of bacteria representing 11 genera indicated that only Rhizobium spp. and Agrobacterium spp. contained GSII. Thus, this enzyme appears to be unique for the Rhizobiaceae.     

Identification of Rhizobium-specific intergenic mosaic elements within an essential two-component regulatory system of Rhizobium species.

Analysis of the DNA regions upstream of the phosphoenolpyruvate carboxykinase gene (pckA) in Rhizobium meliloti and Rhizobium sp. strain NGR234 identified an open reading frame which was highly homologous to the Agrobacterium tumefaciens chromosomal virulence gene product ChvI. A second gene product, 500 bp downstream of the chvI-like gene in R. meliloti, was homologous to the A. tumefaciens ChvG protein. The homology between the R. meliloti and A. tumefaciens genes was confirmed, because the R. meliloti chvI and chvG genes complemented A. tumefaciens chvI and chvG mutants for growth on complex media. We were unable to construct chvI or chvG insertion mutants of R. meliloti, whereas mutants carrying insertions outside of these genes were readily obtained. A 108-bp repeat element characterized by two large palindromes was identified in the chvI and chvG intergenic regions of both Rhizobium species. This element was duplicated in Rhizobium sp. strain NGR234. Another structurally similar element with a size of 109 bp was present in R. meliloti but not in Rhizobium sp. strain NGR234. These elements were named rhizobium-specific intergenic mosaic elements (RIMEs), because their distribution seems to be limited to members of the family Rhizobiaceae. A homology search in GenBank detected six more copies of the first element (RIME1), all in Rhizobium species, and three extra copies of the second element (RIME2), only in R. meliloti. Southern blot analysis with a probe specific to RIME1 showed the presence of several copies of the element in the genome of R. meliloti, Rhizobium sp. strain NGR234, Rhizobium leguminosarum, and Agrobacterium rhizogenes, but none was present in A. tumefaciens and Bradyrhizobium japonicum.     

Mechanism of regulation of glucose transport in Rhizobium leguminosarum.

Multiple glucose transport systems were distinguished in Rhizobium leguminosarum. We found nonlinear Lineweaver-Burk plots for the uptake of glucose, 2-deoxy-D-glucose, and alpha-methyl-D-glucoside, and this implied the existence of at least two uptake mechanisms. Different patterns of inhibition of 2-deoxy-D-glucose uptake and alpha-methyl-D-glucoside uptake at 0.1 mM by various carbohydrates revealed differences in the stereospecificities of the transport systems. Osmotic shock treatment abolished transport activities, and two independent glucose-binding activities were detected in the supernatants. Induction of glucose transport was repressed strongly by L-malate, even in the presence of excess D-glucose. Rhizobium bacteroids showed no significant glucose uptake activity at different oxygen concentrations. These results suggested that glucose transport is repressed by dicarboxylic acids during R. leguminosarum symbiosis.     

Structure of rigid-layer of Rhizobium cell wall. I. Purification on the peptidoglycan from the cellulose microfibrils

The bag shaped peptidoglycan layer of Rhizobium cell wall was isolated from intact cells after treatment with sodium dodecylsulfate and trypsin, chymotrypsin or pepsin digestion. Results of chemical analysis of acid hydrolyzed peptidoglycan revealed beside two amino sugars: glucosamine and muramic acid, three major amino acids; alanine, glutamic acid and 2,6-diaminopimelic acid and also significant amount of glucose. Evidence were provided that the polyglucose found in peptidoglycan preparations of three strains of Rhizobium trifolii, one of Rhizobium leguminosarum and one of Rhizobium meliloti consist of cellulose microfibrils. The content of cellulose present in Rhizobium peptidoglycans ranged from 60 to 80%. Methods of peptidoglycan purification from the cellulose microfibrils are described.     

Compositional studies on succinoglycan-like extracellular water-soluble Rhizobium polysaccharides

This study reports structural information on extracellular, water-soluble polysaccharides from 5 different strains of Rhizobium, viz. R. trifolii J60, R. meliloti J1017, 202, 204 and 207. All the 5 polysaccharides had glucose and galactose in approximate molar ratio of 7:1. Methylation analysis revealed that the polysaccharides contained (1 leads to 3), (1 leads to 6), (1 leads to 4), (1 leads to 4, 1 leads to 6)-linked D-glucose residues, (1 leads to 3)-linked D-galactose and non-reducing terminal D-glucose attached to pyruvate. This structure was found to be exactly the same as that of succinoglycan, a succinic acid containing water-soluble polysaccharide elaborated by Alcaligenes faecalis var. myxogenes 10C3. The similarity of the structure of polysaccharides of two different Rhizobium species and also to the polysaccharide produced by Alcaligenes are discussed in terms of host specificity.     

Diversity of 16S rDNA sequences of Rhizobium spp. implications for species determinations

Comparative analysis of 70 16S rDNA sequences representing 20 Rhizobium species (including pathogenic Agrobacterium spp.) was conducted using Maximum Likelihood to establish relationships of species using multiple sequences. There is no significant internal division of the Rhizobium clade to suggest that it represents more than one genus. Plant pathogenic (Agrobacterium) species are distributed within the genus. The analysis supported the synonymy of some species (Rhizobium gallicum and Rhizobium mongolense) and the need for comparative investigations of the tumorigenic and nodulating properties of Rhizobium tropici and Rhizobium rhizogenes. Misidentification of some sequences may conceal one or more putative novel species. Some sequences appear to be misidentified because of faulty sequencing or incomplete or inadequate analysis.     

Metabolic Adaptations to Dexamethasone‐Induced Insulin Resistance in Healthy Volunteers

Objective : Insulin resistance is observed in individuals with normal glucose tolerance. This indicates that increased insulin secretion can compensate for insulin resistance and that additional defects are involved in impaired glucose tolerance or type 2 diabetes. The objective of this study was to evaluate a procedure aimed at assessing the compensatory mechanisms to insulin resistance. Research Methods and Procedures : Eight healthy nonobese female patients were studied on two occasions, before and after administration of 2 mg/d dexamethasone for 2 days during a two‐step hyperglycemic clamp. Insulin secretion was assessed from plasma insulin concentrations. Insulin sensitivity was assessed from the ratio of whole‐body glucose use (6, 6 ²H₂ glucose) to plasma insulin concentrations. This procedure is known to induce a reversible impairment of glucose tolerance and insulin resistance. Results : In all subjects, dexamethasone induced a decrease in insulin sensitivity and a proportionate increase in first‐phase insulin secretion and in insulin concentrations at both steps of glycemia. The resulting hyperinsulinemia allowed the restoration of normal whole‐body glucose uptake and the suppression of plasma free fatty acids and triglycerides. In contrast, the suppression of endogenous glucose production was impaired after dexamethasone (p < 0.01). Discussion : Increased insulin secretion fully compensates dexamethasone‐induced insulin resistance in skeletal muscle and adipose tissue but not in the liver. This suggests that failure to overcome hepatic insulin resistance can impair glucose tolerance. The compensatory insulin secretion in response to insulin resistance can be assessed by means of a hyperglycemic clamp after a dexamethasone challenge.     

Effect of Aldrin on Growth and Oxidative Metabolism of Rhizobia

At 500 μg ml⁻¹ of aldrin, Rhizobium sp. Bengal gram ( Cicer arietinum ) and Rhizobium sp. Green gram (Vigna radiata ) showed a lag of about 12 h after which the growth returned to normal. The lag period was extended at concentrations above 500 μg ml⁻¹ of aldrin and it was more in the case of Rhizobium sp. Green gram than Rhizobium sp. Bengal gram. However, at high concentrations of aldrin, after the lag, the growth rate was very slow. On the seventh day, Rhizobium sp. Bengal gram showed 72, 81 and 84° inhibition while Rhizobium sp. Green gram exhibited 74, 85 and 88° inhibition of growth at 1000, 1500 and 2000 μg ml⁻¹ of aldrin, respectively. In general, oxidative activity of both of the Rhizobium spp. on pentoses, hexoses and TCA cycle intermediates was more strongly inhibited in aldrin grown cells than normal cells. The inhibitory effect of aldrin on the oxidative activity of rhizobia was partially released with a high concentration of glucose.     

Isolation of the replication DNA region from a Rhizobium plasmid and examination of its potential as a replicon for Rhizobiaceae cloning vectors

The DNA region essential for replication and stability of a native plasmid (pTM5) from Rhizobium sp. (Hedysarum) has been identified and isolated within a 5.4-kb PstI restriction fragment. The isolation of this region was accomplished by cloning endonuclease-restricted pTM5 DNA into a ColE1-type replicon and selecting the recombinant plasmids containing the pTM5 replicator (pTM5 derivative plasmids) by their ability to replicate in Rhizobium. DNA homology studies revealed that pTM5-like replicons are present in cryptic plasmids from some Rhizobium sp. (Hedysarum) strains but not in plasmids from strains of other Rhizobium species or Agrobacterium tumefaciens. The pTM5 derivative plasmids were able to replicate in Escherichia coli and A. tumefaciens and in a wide range of Rhizobium species. On the basis of stability assays in the absence of antibiotic selective pressure, the pTM5 derivative plasmids were shown to be highly stable in both free-living and symbiotic cells of Rhizobium sp. (Hedysarum). The stability of these plasmids in other species of Rhizobium and in A. tumefaciens varied depending on the host and on the plasmid. Most pTM5 derivative plasmids tested showed significantly higher symbiotic stability than RK2 derivative plasmids pRK290 and pAL618 in Rhizobium sp. (Hedysarum), R. meliloti, and R. leguminosarum by. phaseoli. Consequently, we consider that the constructed pTM5 derivative plasmids are potentially useful as cloning vectors for Rhizobiaceae.     

Nitrate reductase activities of rhizobia and the correlation between nitrate reduction and nitrogen fixation.

All species of Rhizobium except R. lupini had nitrate reductase activity. Only R. lupini was incapable of growth with nitrate as the sole source of nitrogen. However, the conditions necessary for the induction of nitrate reductase varied among species of Rhizobium. Rhizobium japonicum and some Rhizobium species of the cowpea strains expressed nitrate reductase activities both in the root nodules of appropriate leguminous hosts and when grown in the presence of nitrate. Rhizobium trifolii, R. phaseoli, and R. leguminosarum did not express nitrate reductase activities in the root nodules, but they did express them when grown in the presence of nitrate. In bacteroids of R. japonicum and some strains of cowpea Rhizobium, high N2 fixation activities were accompanied by high nitrate reductase activities. In bacteroids of R. trifolii, R. leguminosarum, and R. phaseoli, high N2 fixation activities were not accompanied by high nitrate reductase activities.     

The sweet life: diet sugar concentration influences paracellular glucose absorption

Small birds and bats face strong selection pressure to digest food rapidly in order to reduce digesta mass carried during flight. One mechanism is rapid absorption of a high proportion of glucose via the paracellular pathway (transfer between epithelial cells, not mediated by transporter proteins). Intestinal paracellular permeability to glucose was assessed for two nectarivorous passerines, the Australian New Holland honeyeater (Phylidonyris novaehollandiae) and African white-bellied sunbird (Cinnyris talatala) by measuring the bioavailability of radiolabelled, passively absorbed l -glucose. Bioavailability was high in both species and increased with diet sugar concentration (honeyeaters, 37 and 81% and sunbirds, 53 and 71% for 250 and 1000mmoll-1 sucrose diets, respectively). We conclude that the relative contribution of paracellular to total glucose absorption increases with greater digesta retention time in the intestine, and paracellular absorption may also be modulated by factors such as intestinal lumen osmolality and interaction with mediated glucose uptake. The dynamic state of paracellular absorption should be taken into account in future studies.     

Nitrogen fixation (C2H2 reduction) by Medicago nodules and bacteroids under sodium chloride stress

Medicago ciliaris (L.) All., a salt-tolerant legume, was not nodulated by Rhizobium meliloti (2011), a strain commonly used for field inoculation of alfalfas. A strain of Rhizobium meliloti (ABS7) was isolated from saline Algerian soils. It is generally more salt-resistant than strain 2011, exhibits a higher rate of growth and induces the formation of nodules on M. ciliaris . C₂H₂ reduction activity of M. ciliaris nodules was inhibited by 50% in the presence of 200 m M NaCl in the culture medium. whereas 100 m M NaCl was sufficient to inhibit the activity of nodules of M. sativa (L. cv. Europe). C₂H₂ reduction by bacteroids, isolated from nodules of the two species of alfalfa, was directly inhibited by the presence of NaCl in the incubation medium. In both cases, glucose could support bacteroid nitrogen fixation, but only in a narrow range of O₂ tensions. Bacteriods from M. ciliaris were more tolerant to salt than M. sativa ones. The salt resistance of bacteroids from nodules of plants watered with NaCl solutions was not improved in either species. Salt directly added to the incubation mixture of bacteroids or to the culture medium of plants inhibited O₂ uptake of bacteroids isolated from nodules of both M. ciliaris and M. sativa . The depressive effect of NaCl on bacteroid C₂H₂ reduction could be directly related to the drop in bacteroid respiration. The nitrogen fixation capacity of the M. ciliaris-Rhizobium meliloti (ABS7) symbiosis under saline conditions leads us to recommend the introduction of this association in salt-troubled areas.     

Fructose 1,6-bisphosphate aldolase activity ofRhizobium species

FDP aldolase was found to be present in the cell-free extracts of Rhizobium leguminosarum, Rhizobium phaseoli, Rhizobium trifolii, Rhizobium meliloti, Rhizobium lupini, Rhizobium japonicum and Rhizobium species from Arachis hypogaea and Sesbania cannabina. The enzyme in 3 representative species has optimal activity at pH 8.4 in 0.2M veronal buffer. The enzyme activity was completely lost by treatment at 60 degrees C for 15 min. The Km values were in the range from 2.38 to 4.55 X 10(-6)M FDP. Metal chelating agents inhibited enzyme activity, but monovalent or bivalent metal ions failed to stimulate the activity. Bivalent metal ions in general were rather inhibitory.     

Screening of glucose isomerase-producing microorganisms

The ability to convert D-glucose into D-fructose was found in 14 out of 74 species of actinomycetes and bacteria tested. High intracellular glucose isomerase activity was displayed by Arthrobacter sp. and actinomycetes Streptomyces viridobrunneus, Streptomyces sp. 1 and Streptomyces sp. 32. The first showed maximal glucose-converting potential when cultured in both glucose and xylose media, while glucose isomerase activity of Streptomyces species could be found solely in medium supplemented with xylose. The ketose enzymatically formed from D-glucose was identified as D-fructose.