alpha -Galactoside Uptake in Rhizobium meliloti: Isolation and Characterization of agpA, a Gene Encoding a Periplasmic Binding Protein Required for Melibiose and Raffinose Utilization

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Journal of Bacteriology, November 1998, p. 5739-5748, Vol. 180, No. 21
0021-9193/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

$alpha$ -Galactoside Uptake in Rhizobium meliloti: Isolation and Characterization of agpA, a Gene Encoding a Periplasmic Binding Protein Required for Melibiose and Raffinose Utilization

Daniel J. Gage^* and Sharon R. Long

Department of Biological Sciences, Howard Hughes Medical Institute, Stanford University, Stanford, California 94305-5020

Received 8 June 1998/Accepted 28 August 1998

	ABSTRACT

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Rhizobium meliloti can occupy at least two distinct ecological niches; it is found in the soil as a free-living saprophyte,and it also lives as a nitrogen-fixing intracellular symbiontin root nodules of alfalfa and related legumes. One approach tounderstanding how R. meliloti alters its physiology in order tobecome an integral part of a developing nodule is to identifyand characterize genes that are differentially expressed by bacterialiving inside nodules. We used a screen to identify genes underthe control of the R. meliloti regulatory protein NodD3, SyrM,or SyrA. These regulatory proteins are expressed by bacteria growinginside the root nodule. One gene isolated in this screen was mappedto pSymB and displayed complex regulation. The gene was downregulatedby the syrA gene product and also by glucose and succinate. Thisgene, referred to as agpA, encodes a periplasmic binding proteinthat is most similar to proteins from the periplasmic oligopeptidebinding protein family. It is likely that AgpA binds $alpha$ -galactosides,because $alpha$ -galactosides induce the expression of agpA, and agpAmutants cannot utilize or transport these sugars. Activity ofan agpA::TnphoA fusion was downregulated by SyrA. Because syrAis known to be expressed at high levels in intracellular symbioticR. meliloti and at low levels in the free-living bacteria, wepropose that AgpA may belong to the class of gene products whoseexpression decreases when R. meliloti becomes an intracellularsymbiont.

	INTRODUCTION

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Rhizobium meliloti is a gram-negative bacterium which can live as a saprophyte in soil or as a nitrogen-fixing symbiont insideroot nodule cells of alfalfa and related legumes. The interactionsleading to symbiosis begin when R. meliloti detects flavonoidsand other compounds released by host plants and then induces bacterialgenes required for the biosynthesis of lipooligosaccharide signalingmolecules. These compounds initiate many of the physiologicaland morphogenic changes seen in the plant early in nodulation.These changes include root hair curling, depolarization of theroot hair cell membrane, calcium oscillations in root hairs, andthe initiation of cell division in the inner root cortex, whichestablishes a nodule primordium. An infection thread, which isa plant-derived tubule filled with dividing and growing bacteria,extends down through the root hair and then traverses severalcell layers to deliver bacteria to root cells in the developingnodule. Bacteria exit the infection thread, differentiate, andfix atmospheric nitrogen, which is exported from the nodule tothe rest of the plant (5, 6, 19, 29, 33, 39, 43,47).

The R. meliloti nod genes, which are required for the synthesis of the lipooligosaccharide signaling molecules (Nod factors),are carried on a 1,500-kb plasmid, pSymA, and are upregulatedby the LysR-type transcriptional activators, NodD1, NodD2, andNodD3. NodD1 and NodD2 become active transcriptional regulatorsin the presence of specific flavonoid inducers released from hostplant roots and seeds (32, 36, 37). nodD3 is part of a clusterof three regulatory genes (nodD3, syrM, and syrA) present on pSymAabout 15 kb downstream of nodD1 (32). NodD3 upregulates syrM,and SyrM upregulates nodD3; together they form a self-amplifyingregulatory circuit which can activate the induction of the othernod genes (32, 45). The third gene, syrA, encodes a small,hydrophobic protein which upregulates the synthesis of exopolysaccharide(2, 32). Exopolysaccharide is required for R. meliloti toform nitrogen-fixing nodules (13, 23-25).

NodD3, SyrM, and SyrA are synthesized by bacteria inside alfalfa nodules (2, 42, 45). We asked whether these proteinsmight be responsible for regulating the synthesis of other genesneeded for the establishment or maintenance of the nitrogen-fixingsymbiosis. To define more fully the roles of NodD3, SyrM, andSyrA in nodulation, we developed a screen which allowed us toidentify TnphoA insertions in genes regulated by these proteins.One gene, agpA ( $alpha$ -galactoside permease), isolated in this screenmapped to the symbiotic plasmid, pSymB, and displayed intriguingpatterns of expression. agpA is similar to genes which encodeperiplasmic binding proteins of oligopeptide transport systemsin other bacteria. This study describes the isolation and initialcharacterization of this gene.

	MATERIALS AND METHODS

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Bacterial strains and growth conditions. Bacterial strains and their relevant genotypes are listed in Table 1. R. meliloti was cultured at 30°C, and growth was monitoredby measuring the optical density at 595 nm (OD₅₉₅) of 100 µl ofcell culture in a 96-well microtiter dish with a Bio-Rad 3550plate reader.

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TABLE 1. Strains and plasmids

Growth media. Bacteria were grown on Luria broth (LB), M9 minimal medium with various carbon sources, or basal medium. Basal medium is M9minimal medium containing Difco yeast extract at a concentrationof 65 µg/ml. XP (5-bromo-4-chloro-3-indolylphosphate-p-toluidine)was used at a final concentration of 60 µg/ml.

Genetic screen for loci under the control of nodD3, syrM, or syrA. R. meliloti Rm8002/pRmJT5 was randomly mutagenized with TnphoA (30) by introducing plasmid pRK609 via conjugation with Escherichiacoli MM294a/pRK609 (28). The mating mix was diluted and platedon an indicator medium, LB plus streptomycin (500 µg/ml) plusneomycin (200 µg/ml) plus XP. The plasmid pRmJT5 overexpressesthe regulatory genes nodD3, syrM (44), and syrA (2) and isunstably maintained in the absence of tetracycline selection.Therefore, TnphoA insertions into genes which were under the controlof either of these three regulatory genes gave rise to sectoredcolonies when plated on the indicator medium described above.Colonies which showed sectors were purified on LB plus streptomycin(500 µg/ml) plus neomycin (200 µg/ml) plus tetracycline (10 µg/ml)and further characterized.

DNA sequencing. DNA from the regions flanking the agpA::TnphoA insertion site was amplified by inverse PCR with primers which hybridized tothe left end and center of TnphoA (5'-GCAGAGCGGCAGTCTGATCACCCGTTAand 5'-AAGGTCGCGCGCATTCCCGATGAA, respectively) (35). The PCRfragments were used to screen an R. meliloti lambda library constructedin the vector Lambda Fix II (48). DNA from positive lambda cloneswas subcloned and sequenced by standard methods.

Alkaline phosphatase assays. Samples (0.1 to 0.5 ml each) were taken from growing cultures, pelleted, and resuspended in 0.5 ml of 1 M Tris-HCl, pH 8.0,and frozen at $-$ 80°C until all samples from an experiment had beentaken. The samples were then thawed and permeabilized with a dropof chloroform and 50 µl of 0.1% sodium dodecyl sulfate, and 180µl of this extract was added to 20 µl of a 4% solution of ortho-nitrophenylphosphateand placed in a 96-well microtiter dish. Controls containing 180µl of sample extract and 20 µl of water were also placed in thedish. Hydrolysis of ortho-nitrophenylphosphate was monitored at595 nm with a Bio-Rad 3550 plate reader. The OD₅₉₅ of the sampleswas taken every 2 to 10 min, and each reading was corrected bysubtracting the OD₅₉₅ of the respective control at each time point.The alkaline phosphatase-specific activity for each sample wasestimated by dividing the slope of the resultant curve (changein OD₅₉₅ per minute) by the amount of cell material present inthe control sample (OD₅₉₅) at the first time point and multiplyingthe result by 1,000.

Transport assays. Stationary-phase cells were harvested after 60 h, washed in M9 salts containing no added sugars, and resuspended to an OD₅₉₅of 1.0. A 0.5-ml portion of the cell suspension was added to amicrocentrifuge tube containing 10 µl of 10 mM [³H]raffinose (0.1 mCi/ml). Samples (0.1 ml each) were removed everyminute and filtered through a Millipore nitrocellulose filter(0.45-µm pore size). The filter was immediately rinsed three timeswith 5 ml of M9 salts containing no sugar and counted with a scintillationcounter.

Isolation of periplasmic proteins. Periplasmic proteins were isolated from R. meliloti by the chloroform shock method (1a). A 1.5-ml portion of an overnightculture of R. meliloti was centrifuged for 30 s in a microcentrifuge,and the supernatant was removed. Twenty microliters of chloroformwas added to the cell pellet and vortexed briefly. Following 20min of incubation at room temperature, the mixture was resuspendedin 200 µl of 0.01 M Tris-HCl and immediately spun for 30 s ina microcentrifuge. The supernatant, which contained the periplasmicproteins, was removed, and 20 µl was analyzed by sodium dodecylsulfate-polyacrylamide gel electrophoresis.

	RESULTS

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A screen for genes under the control of nodD3, syrM, or syrA. The regulatory genes nodD3, syrM, and syrA are closely linked on the symbiotic plasmid pSymA and are expressed by bacteriagrowing inside nodules. nodD3 is expressed by bacteria growingin the meristematic and infection zones of the nodule (45),and syrM and syrA are highly expressed in the older tissue, wherebacteroids are differentiating and fixing nitrogen (2, 45).These expression patterns suggested that these loci may controlgenes involved either in establishing and maintaining the symbiosisor in fixing nitrogen. In order to isolate insertions in genesencoding membrane or extracellular proteins whose expression isregulated by nodD3, syrM, or syrA, an R. meliloti strain carryingthe plasmid pRmJT5 (Tc^r), which overproduces NodD3, SyrM, and SyrA (32, 44), wasmutagenized with TnphoA. The TnphoA-mutagenized cells were platedon LB medium which contained XP and lacked tetracycline. PlasmidpRmJT5(Tc^r) is unstable in the absence of tetracycline selection. Therefore,if the TnphoA present in a strain was upregulated or downregulatedby the proteins overproduced on pRmJT5, then colonies plated onthe nonselective indicator medium should generate sectors. Thesesectors would arise from a population of cells which lost pRmJT5during colony development and therefore expressed the TnphoA fusiondifferently than neighboring cells in the colony which retainedthe plasmid. By this method, 62 independent strains were isolated.These strains gave rise to sectored colonies on nonselective platesand therefore contained insertions whose expression was dependenton the plasmid bearing nodD3, syrM, or syrA.

Strain SG1001/pRmJT5 displayed dramatic sectoring patterns when it was plated on nonselective indicator medium. The colonieswere white without sectors when they were grown on selective mediumbut white with blue sectors when they were grown on nonselectiveindicator medium (Fig. 1A and B). These results indicated thatthe gene fused to TnphoA was downregulated by genes on plasmidpRmJT5 when it was present.

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FIG. 1. Colony phenotypes of strain SG1001 (agpA::TnphoA). Strain SG1001 (agpA::TnphoA)/pRmJT5 on LB XP indicator plates with (A) and without (B) tetracycline. Plasmid pRmJT5 is not stably maintained without tetracycline, and its loss allows the generation of sectors containing bacteria which express the agpA::TnphoA fusion. (C and D) Strain SG1001 (agpA::TnphoA) and strain SG1001 (agpA::TnphoA)/pMB89 on LB XP indicator plates, respectively. syrA is overexpressed from pMB89, resulting in downregulation of the agpA::TnphoA fusion.

The TnphoA insertion in strain SG1001 is downregulated by syrA. pRmJT5 overproduces nodD3, syrM, and syrA because there are multiple copies of the plasmid per cell (2, 45). We determinedwhich of these three genes affected the expression of the TnphoAinsertion in strain SG1001 by introducing plasmids which overexpressedeach of the three proteins. The overexpression of nodD3, syrM,or syrA was achieved by placing each gene downstream of a constitutivelyactive trp promoter from Salmonella typhimurium (7). The plasmidswhich overproduced NodD3 and SyrM had minor effects on the expressionof the agpA::TnphoA fusion (data not shown). However, the plasmidwhich overproduced SyrA strongly repressed expression of the fusion(Fig. 1C and D). The minor effects of the overexpression of nodD3and syrM were probably due to the effects of the proteins on theexpression of syrA (2, 32, 45).

Cells which overproduced syrA, either from pRmJT5 or from pMB89, formed white colonies which did not sector. However, suchcolonies were often ringed with blue near the periphery (Fig.1A and D). Often, the rings formed when colonies were close toone another or close to the wall of the petri dish. This suggestedthat the rings arose in response to a local accumulation of ametabolic byproduct or to a local depletion of a substance fromthe growth medium. We were unable to differentiate between thesetwo possibilities with preliminary studies (data not shown).

Strain SG1001 contains an insertion in a gene encoding a periplasmic binding protein. Inverse PCR (35) was used to amplify DNA flanking the TnphoA insertion in strain SG1001. This DNA was then used to makea probe and map the insertion sites. Southern analysis indicatedthat the TnphoA insertion site in strain SG1001 was on the symbioticmegaplasmid pSymB (8).

Chromosomal fragments which flanked the TnphoA insertion in strain SG1001 were subcloned from a lambda library and sequenced.This revealed that the transposon had inserted into a gene encodinga 77-kDa protein similar to the periplasmic binding protein componentof the oligopeptide family of permeases (46, 49) (Fig. 2A).Bacterial permease systems typically consist of a ligand bindingprotein which is in the periplasm of gram-negative bacteria ortethered to the outer face of the cytoplasmic membrane of gram-positivebacteria by a covalently attached lipid (12) together with twodifferent transmembrane proteins and at least one protein capableof binding and hydrolyzing ATP. While the overall identity betweenAgpA and other members of the oligopeptide binding protein familyfrom S. typhimurium is only about 15%, the identity in subregionsof the protein is much higher. These highly similar subregionsare diagnostic for periplasmic binding protein components of theoligopeptide permease family of transporters (46, 49).

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FIG. 2. (A) AgpA is similar to oligopeptide binding proteins of periplasmic transport systems. The deduced amino acid sequence of AgpA was compared to the sequences of other members of the oligopeptide binding protein family with the Pileup program of the Wisconsin Genetics Computer Group sequence analysis package, Clustal W and SeqVu. The peptides used in the lineup are R. meliloti AgpA (Rm AgpA), Agrobacterium tumefaciens agrocinopine transport protein AccA (At AccT) (17), B. subtilis oligopeptide transport protein Spo0K (Bs Spo0K) (41), E. coli dipeptide transport protein DppA (Ec DppA), E. coli nickel transport protein NikA (Ec NikA) (34), Streptococcus pneumoniae oligopeptide pheromone binding protein AmiA (Sp AmiA) (1), and S. typhimurium oligopeptide binding protein OppA (St OppA) (18). The small inverted triangle indicates the location of the PhoA fusion site in R. meliloti SG1001. (B) MelA from R. meliloti is similar to MelA, an $alpha$ -galactosidase, of E. coli. The deduced amino acid sequence of R. meliloti MelA was compared to that of E. coli MelA with the Pileup program of the Wisconsin Genetics Computer Group sequence analysis package.

The agpA gene was preceded by an open reading frame which encodes a 55-kDa protein similar (31% identity) to the MelA $alpha$ -galactosidaseof E. coli (Fig. 2B) (27).

Regulation of agpA. The agpA::TnphoA fusion is induced in the central part of colonies when cells are plated on LB medium (Fig. 1C). Because thegrowth of the bacteria in this part of the colony has slowed orstopped, we tested the possibility that the TnphoA fusion wasinduced as strain SG1001 entered stationary phase. We found thatthe agpA::TnphoA fusion was induced as the growth rate slowedat the end of the exponential phase when cells were in LB medium(Fig. 3A). However, the fusion was not induced when cells grownin M9 glucose minimal medium entered stationary phase (Fig. 3B).By growing cells in M9 salts containing various components ofLB medium, we found that the agpA::TnphoA fusion was induced ascells entered stationary phase when yeast extract was includedin the medium (data not shown).

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FIG. 3. The agpA::TnphoA fusion is induced as strain SG1001 enters stationary phase when cells are grown in LB medium but not when they are grown in M9 glucose medium. Strain SG1001 was grown in LB medium (A) and M9 glucose medium (B), and the OD of the culture and the specific activity of the AgpA'::'PhoA were monitored.

While conducting experiments on the yeast extract-dependent induction of agpA, we noticed that the expression of agpA wasinfluenced by carbon sources in the medium. When cultures weregrown in basal medium (which includes a small amount of yeastextract) containing various amounts of glucose or succinate, cellyield increased with increased concentrations of the carbon source,but AgpA'::'PhoA activity decreased (Fig. 4A and B). The activityof the AgpA'::'PhoA fusion was also monitored as cultures grewin basal medium or basal medium plus glucose, and results indicatedthat increasing the amount of glucose present in the culture mediumdecreased the rate at which AgpA::PhoA activity protein accumulatedin the cells (Fig. 4C and D). Previous work has indicated thatsuccinate and glucose are preferred carbon sources for Rhizobiumspecies, as they have been shown to repress the utilization ofother carbon sources, such as lactose and myo-inositol (20,38). Our results show that succinate and glucose also downregulatethe expression of the agpA gene.

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FIG. 4. Expression of the agpA::TnphoA fusion in strain SG1001 is repressed by glucose and succinate. Cell yield and the specific activity of the AgpA'::'PhoA fusion were determined after strain SG1001 had been cultured for 96 h in basal medium containing various concentrations of glucose (A) and succinate (B). (C) Growth of strain SG1001 in M9 salts supplemented with various combinations of glucose and yeast extract. The concentrations of glucose and yeast extract of the different media are indicated on the graph. (D) Specific activity of the AgpA'::'PhoA fusion in strain SG1001 as cells grew in basal medium and basal medium supplemented with various concentrations of glucose. The specific activity data are from the cultures whose growth is shown in panel C.

The agpA gene product is involved in the transport of $alpha$ -galactosides. The agpA gene encodes a protein which is similar to those in the periplasmic oligopeptide binding protein family. Despitethe name of this family, its members are involved in the transportof a variety of substrates (46, 49). For example, besidesoligopeptides and dipeptides, family members which transport nickel(34), heme (16), and substituted sugars (17, 21) havebeen characterized.

Our initial experiments showed no evidence that the agpA gene product was involved in oligopeptide transport (data not shown).Because the agpA gene is preceded by an open reading frame whichencodes a protein similar to $alpha$ -galactosidases, we sought to determinewhether strain SG1001 is able to grow on $alpha$ -galactosides. For thisexperiment, we grew strain SG001 and its parental strain, Rm8002,overnight in a noninducing M9 glucose medium, and the next daywe diluted cells into basal media with and without the sugarsto be tested. The yeast extract in the basal medium was necessarybecause it allowed the cells to grow to a measurable density,even if they were unable to catabolize a particular sugar. Wefound that strain SG1001 was unable to use melibiose and raffinose,both $alpha$ -galactosides, as carbon sources. This strain was, however,able to catabolize glucose and galactose under the same experimentalconditions. The parental strain, Rm8002, was able to utilize allfour compounds.

We tested different sugars for their ability to induce expression of the agpA::TnphoA fusion. Cells were grown in basal mediumcontaining one of a variety of sugars at a concentration of 0.4%(wt/vol). After 96 h, the cells were harvested and the alkalinephosphatase activity arising from the AgpA'::'PhoA fusion wasmeasured. Yeast extract was included in all the media tested toensure that we had enough cells to assay for alkaline phosphataseactivity and to ensure a small but measurable amount of AgpA'::'PhoAactivity. The results from one such experiment are summarizedin Fig. 5. We found that galactose was a good inducer of the agpAgene; isomers of galactose, such as glucose, talose, and gulose,were poor inducers of the gene (Fig. 5A). $alpha$ -Galactosides werealso good inducers of the gene, even if the terminal galactoseis linked to a trisaccharide, as in stachyose (Fig. 5B). $alpha$ -Glucosides,such as isomaltose, were poor inducers of agpA (Fig. 5C). We foundthat $beta$ -galactosides can act as inducers if the moiety linked tothe terminal galactose is small. For example, $beta$ -methyl-galactosideis a good inducer of agpA, whereas lactose is not (Fig. 5D).

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FIG. 5. The agpA::TnphoA fusion in strain SG1001 is induced by $alpha$ -galactosides. Strain SG1001 was grown in basal medium supplemented with the indicated sugars. Alkaline phosphatase specific activity was determined 96 h after inoculation, when cells were in stationary phase. The supplemental sugars were present at a concentration of 0.4% (wt/vol). Specific activity of the AgpA'::'PhoA fusion when strain SG1001 was grown in the presence of galactose or isomers of galactose (A); $alpha$ -galactosides (B); the $alpha$ -galactoside melibiose or an isomer of melibiose, the $alpha$ -glucoside isomaltose (C); and $beta$ -galactosides (D).

$alpha$ -Galactosides induced the agpA gene when they were present at 0.4% (wt/vol), a concentration of about 20 mM. We sought todetermine which sugars are the most-effective inducers by calculatingthe concentrations at which they were able to induce the agpA::TnphoAfusion. We inoculated strain SG1001 into basal medium, and sugarswere added in concentrations ranging from 10 µM to 1.6 mM. Cellswere harvested after 96 h, and the specific activity of the AgpA'::'PhoAfusion was measured. The resulting dose-response curves, shownin Fig. 6, indicated that melibiose was the most-effective inducerof the fusion and that it was active at a concentration of 10µM.

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FIG. 6. Dose-response curve of agpA::TnphoA induction to various inducing galactosides. Strain SG1001 was inoculated into basal medium containing various galactosides which induce the AgpA'::'PhoA fusion and harvested for alkaline phosphatase activity assays after 96 h of growth. Sugars were present at concentrations ranging from 10 µM to 1.6 mM.

We hypothesized that the agpA gene was part of a transport system involved in $alpha$ -galactoside uptake, because the sequence ofthe agpA gene suggested that it encoded a periplasmic bindingprotein for a transport system and the experiments described abovesuggested that it was involved in the utilization of $alpha$ -galactosides.Localization of the agpA gene product and studies of raffinosetransport supported this hypothesis. Strain SG1001 and the parentalstrain, Rm8002, were grown in M9 glucose medium, which repressesagpA expression, or in M9 galactose medium, which induces agpAexpression, and periplasmic proteins were isolated and separatedby electrophoresis (Fig. 7A). When strain Rm8002 (agpA⁺) was grown in M9 galactose medium, the inducing medium, it expresseda periplasmic protein of about 80 kDa which is close to 75 kDa,the predicted size of the mature AgpA protein. This protein wasabsent from strain SG1001 (agpA::TnphoA) when it was grown underinducing conditions and from both strains when they were grownin M9 glucose. Only those cells which expressed the 80-kDa protein(i.e., strain Rm8002 grown in inducing medium) were able to transportthe $alpha$ -galactoside raffinose as assayed by uptake of [³H]raffinose (Fig. 7B). For these reasons, we believe that the80-kDa protein is mature AgpA and the periplasmic binding proteinof an $alpha$ -galactoside transport system.

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FIG. 7. AgpA is a periplasmic protein needed for transport of the $alpha$ -galactoside raffinose. (A) Periplasmic proteins from strains Rm8002 (agpA⁺) and SG1001 (agpA) grown in M9 glucose, which represses agpA expression, or in M9 galactose, which induces agpA expression. (B) Transport of raffinose by strains Rm8002 and SG1001. Raffinose uptake assays were performed with cells from the cultures used for isolating the periplasmic proteins shown in panel A.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

By screening for R. meliloti genes which are regulated by nodD3, syrM, or syrA, we have isolated and characterized a TnphoAinsertion in a gene, agpA, which encodes the binding protein componentof a periplasmic transport system. This gene is downregulatedby syrA.

The periplasmic transport systems, of which there are more than 50, cluster into seven families (46). The sequence of agpAindicates that it encodes a member of the oligopeptide permeasetransport system family. The oligopeptide permease family includestransport systems from gram-negative and gram-positive bacteriawhich transport a variety of substrates $---$ small peptides (14,18), peptide pheromones (22, 26, 41), nickel (34), heme(16), and modified sugar molecules such as aminoglycoside antibiotics(21), agrocinopine, and agrocin 84 (17).

Strain SG1001, which contains an agpA::TnphoA fusion, fails to utilize or transport $alpha$ -galactosides. In addition, the agpA::TnphoAfusion is induced by $alpha$ -galactosides, and the agpA gene is downstreamof a gene which is similar to an $alpha$ -galactosidase gene from E.coli. For these reasons, it is plausible that the agpA gene productbinds $alpha$ -galactosides such as melibiose, raffinose, and stachyosein the periplasm and is involved in their transport across thebacterial cell membrane.

The fact that the agpA::TnphoA fusion in strain SG1001 is induced by $alpha$ -galactosides despite the inability of this strain toutilize or transport $alpha$ -galactosides raises the question of howthe cells are able to sense and induce agpA in response to suchsugars. It may be that the inducing molecules cross the cell membrane,via a transport system for which they have low affinity, at arate which is too low to support growth or to be easily detectedby uptake assays but which is sufficient to allow the sugar tointeract with a regulatory protein and to induce agpA::TnphoAfusion. Alternatively, it may be that $alpha$ -galactosides are detectedextracellularly and that the information is transduced to theinternal compartment, leading to agpA induction. The agpA geneis induced to high levels by either $alpha$ -galactosides or galactose,but not by a $beta$ -galactoside such as lactose. This finding indicatesthat the molecules responsible for detecting and initiating agpAinduction in response to galactose do not have access to the galactosereleased by the hydrolysis of lactose, perhaps because $alpha$ -galactosidesand galactose are sensed in the extracellular compartment by moleculesthat do not recognize lactose. Alternatively, the sensing moleculesmay be cytoplasmic but may fail to respond to the galactose releasedduring hydrolysis of lactose because the galactose pool is smallor because the galactose is rapidly channeled into central metabolicpathways.

We were able to show that the agpA gene is downregulated by syrA. syrA encodes an 88-amino-acid protein (2) which is similarto two other small proteins found in Rhizobium species: ExoX (15,40) and Psi (4). All three of these proteins are hydrophobicin their amino-terminal halves and hydrophilic in their carboxy-terminalhalves. It has been suggested that ExoX and Psi are anchored inthe membrane by their N termini and have their hydrophilic C terminiin the cell cytoplasm (4). In addition to their similar structures,SyrA, ExoX, and Psi regulate the production of exopolysaccharides.The regulatory effects of ExoX and Psi on exopolysaccharide productionare posttranslational. It has been suggested that the proteinsinteract with other membrane proteins required for the synthesisof exopolysaccharide and inhibit their activity in some manner(15, 40, 50). If SyrA also exerts its effects posttranslationally,then the downregulation of agpA by syrA is likely to be indirectbecause SyrA overproduction results in lowered expression of theagpA::TnphoA fusion, and fusion expression is likely to be controlledat the transcriptional level. One possible scenario is that SyrAdownregulates the activity of a transport system which bringsin the $alpha$ -galactosides which induce the agpA gene, or perhaps SyrAinterferes with proteins involved in sensing or responding to $alpha$ -galactosides.

Recent work has shown that the syrA gene is highly expressed by R. meliloti inside nodule cells (2). Therefore, it maybe that the $alpha$ -galactoside transport system, of which agpA is apart, is downregulated in these intercellular bacteria. We haveshown that succinate and glucose also downregulate the expressionof the agpA gene. Succinate and other dicarboxylic acids are presentin nodule cells and are used by bacteroids to fuel nitrogen fixation(3, 9, 10). These acids may also act to downregulate agpAinside nodule cells. Whether or not repression of agpA by succinateand glucose is dependent on syrA is currently unknown.

The $alpha$ -galactoside transport system may be expressed by bacteria growing in the rhizosphere of host plants, because $alpha$ -galactosidessuch as raffinose and stachyose, both of which induce agpA, arepresent at high levels in many legume seeds and thus may alsobe present in the rhizosphere of germinating seeds or young plants.Such sugars are catabolized by R. meliloti, and their utilizationmay have a role in growth and survival of these bacteria in therhizosphere of their host plants. Whether subsequent downregulationof the $alpha$ -galactoside transport system occurs when R. melilotiis growing inside nodule cells and whether this regulation relatesto metabolism or to other aspects of symbiosis may be revealedin further studies.

	ACKNOWLEDGMENTS

S.R.L. is an investigator at the Howard Hughes Medical Institute. This research was additionally supported by NIH researchservice award GM16211 to D.J.G. and by DOE grant DE-FG-03-90ER20010to S.R.L.

We thank the members of our laboratory for useful suggestions and discussion. In particular, we thank Mike Willits for theR. meliloti lambda library and Melanie Barnett for providing informationon syrA prior to publication.

	FOOTNOTES

^* Corresponding author. Present address: University of Connecticut, Department of Molecular and Cell Biology, 75 N. EaglevilleRd., U-44, Storrs, CT 06269. Phone: (860) 486-5923. Fax: (860)486-1784. E-mail: Gage{at}uconnvm.uconn.edu.

REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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12. Gilson, E., G. Alloing, T. Schmidt, J. P. Claverys, R. Dudler, and M. Hofnung. 1988. Evidence for high affinity binding-protein dependent transport systems in Gram positive bacteria and in Mycoplasma. EMBO J. 7:3971-3974[Medline].

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22. Koide, A., and J. A. Hoch. 1994. Identification of a second oligopeptide transport system in Bacillus subtilis and determination of its role in sporulation. Mol. Microbiol. 13:417-426[Medline].

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1.	Alloing, G., M. C. Trombe, and J. P. Claverys. 1990. The ami locus of the gram-positive bacterium Streptococcus pneumoniae is similar to binding protein-dependent transport operons of gram-negative bacteria. Mol. Microbiol. 4:633-644[Medline].
1a.	Ames, G. F., C. Prody, and S. Kustu. 1983. Simple, rapid, and quantitative release of periplasmic proteins by chloroform. J. Bacteriol. 160:1181-1183.
2.	Barnett, M. J., J. A. Swanson, and S. R. Long. 1998. Multiple genetic controls on Rhizobium meliloti syrA, a regulator of exopolysaccharide abundance. Genetics 148:19-32[Abstract/Free Full Text].
3.	Bolton, E., B. Higgisson, A. Harrington, and F. O'Gara. 1986. Dicarboxylic acid transport in Rhizobium meliloti: isolation of mutants and cloning of dicarboxylic acid transport gene. Arch. Microbiol. 144:142-146.
4.	Borthakur, D., J. A. Downie, A. W. B. Johnston, and J. W. Lamb. 1985. psi, a plasmid-linked Rhizobium-phaseoli gene that inhibits exopolysaccharide production and which is required for symbiotic nitrogen fixation. Mol. Gen. Genet. 200:278-282.
5.	Brewin, N. J. 1991. Development of the legume root nodule. Annu. Rev. Cell Biol. 7:191-226.
6.	Denarie, J., F. Debelle, and J. C. Prome. 1996. Rhizobium lipo-chitooligosaccharide nodulation factors: signaling molecules mediating recognition and morphogenesis. Annu. Rev. Biochem. 65:503-535[Medline].
7.	Egelhoff, T. T., and S. R. Long. 1985. Rhizobium meliloti nodulation genes: identification of nodDABC gene products, purification of nodA protein, and expression of nodA in Rhizobium meliloti. J. Bacteriol. 164:591-599[Abstract/Free Full Text].
8.	Eiken, P. 1996. Stanford University honors thesis, Stanford, Calif .
9.	Finan, T. M., I. Oresnik, and A. Bottacin. 1988. Mutants of Rhizobium meliloti that are defective in succinate metabolism. J. Bacteriol. 170:3396-3403[Abstract/Free Full Text].
10.	Finan, T. M., J. M. Wood, and D. C. Jordan. 1983. Symbiotic properties of C₄-dicarboxylic acid transport mutants of Rhizobium leguminosarum. J. Bacteriol. 154:1403-1413[Abstract/Free Full Text].
11.	Friedman, A. M., S. R. Long, S. E. Brown, W. J. Buikema, and F. M. Ausubel. 1982. Use of a cos derivative of pRK290 in constructing a clone bank of Rhizobium meliloti DNA. Gene 18:289-296[Medline].
12.	Gilson, E., G. Alloing, T. Schmidt, J. P. Claverys, R. Dudler, and M. Hofnung. 1988. Evidence for high affinity binding-protein dependent transport systems in Gram positive bacteria and in Mycoplasma. EMBO J. 7:3971-3974[Medline].
13.	Gonzalez, J. E., G. M. York, and G. C. Walker. 1996. Rhizobium meliloti polysaccharides: synthesis and symbiotic function. Gene 179:141-146[Medline].
14.	Goodwin, E. W., and C. F. Higgins. 1987. Uptake of cell wall peptides by Salmonella typhimurium and Escherichia coli. J. Bacteriol. 169:3861-3865[Abstract/Free Full Text].
15.	Gray, J. X., M. A. Djordjevic, and B. G. Rolfe. 1990. Two genes that regulate exopolysaccharide production in Rhizobium sp. strain NGR234: DNA sequences and resultant phenotypes. J. Bacteriol. 172:193-203[Abstract/Free Full Text].
16.	Hanson, M. S., C. Slaughter, and E. J. Hansen. 1992. The hbpA gene of Haemophilus influenzae type b encodes a heme-binding protein conserved among heme-dependent Haemophilus species. Infect. Immun. 60:2257-2266[Abstract/Free Full Text].
17.	Hayman, G. T., S. B. von Bodman, H. Kim, P. Jiang, and S. K. Farrand. 1993. Genetic analysis of the agrocinopine catabolic region of Agrobacterium tumefaciens Ti plasmid pTiC58, which encodes genes required for opine and agrocin 84 transport. J. Bacteriol. 175:5575-5584[Abstract/Free Full Text].
18.	Hiles, I. D., and C. F. Higgins. 1986. Peptide uptake by Salmonella typhimurium. Eur. J. Biochem. 158:561-567[Medline].
19.	Hirsch, A. M. 1992. Developmental biology of legume nodulation. New Phytol. 122:211-237.
20.	Jelesko, J. G., and J. A. Leigh. 1994. Genetic characterization of a Rhizobium meliloti lactose utilization locus. Mol. Microbiol. 11:165-173[Medline].
21.	Kashiwagi, K., A. Miyaji, S. Ikeda, T. Tobe, C. Sasakawa, and K. Igarashi. 1992. Increase of sensitivity to aminoglycoside antibiotics by polyamine-induced protein (oligopeptide-binding protein) in Escherichia coli. J. Bacteriol. 174:4331-4337[Abstract/Free Full Text].
22.	Koide, A., and J. A. Hoch. 1994. Identification of a second oligopeptide transport system in Bacillus subtilis and determination of its role in sporulation. Mol. Microbiol. 13:417-426[Medline].
23.	Leigh, J. A., J. W. Reed, J. F. Hanks, A. M. Hirsch, and G. C. Walker. 1987. Rhizobium meliloti mutants that fail to succinylate their calcofluor-binding exopolysaccharide are defective in nodule invasion. Cell 51:579-587[Medline].
24.	Leigh, J. A., E. R. Signer, and G. C. Walker. 1985. Exopolysaccharide-deficient mutants of Rhizobium meliloti that form ineffective nodules. Proc. Natl. Acad. Sci. USA 82:6231-6235[Abstract/Free Full Text].
25.	Leigh, J. A., and G. C. Walker. 1994. Exopolysaccharides of Rhizobium: synthesis, regulation and symbiotic function. Trends Genet. 10:63-67[Medline].
26.	Leonard, B. A. B., A. Podbielski, P. J. Hedberg, and G. M. Dunny. 1996. Enterococcus faecalis pheromone binding protein, PrgZ, recruits a chromosomal oligopeptide permease system to import sex pheromone cCF10 for induction of conjugation. Proc. Natl. Acad. Sci. USA 93:260-264[Abstract/Free Full Text].
27.	Liljestrom, P. L., and P. Liljestrom. 1987. Nucleotide sequence of the melA gene, coding for alpha-galactosidase in Escherichia coli K-12. Nucleic Acids Res. 15:2213-2220[Abstract/Free Full Text].
28.	Long, S., S. McCune, and G. C. Walker. 1988. Symbiotic loci of Rhizobium meliloti identified by random TnphoA mutagenesis. J. Bacteriol. 170:4257-4265[Abstract/Free Full Text].
29.	Long, S. R. 1996. Rhizobium symbiosis: Nod factors in perspective. Plant Cell 8:1885-1898[Medline].
30.	Manoil, C., and J. Beckwith. 1985. TnphoA: a transposon probe for protein export. Proc. Natl. Acad. Sci. USA 82:8129-8133[Abstract/Free Full Text].
31.	Meade, H. M., S. R. Long, G. B. Ruvkun, S. E. Brown, and F. M. Ausubel. 1982. Physical and genetic characterization of symbiotic and auxotrophic mutants of Rhizobium meliloti induced by transposon Tn5 mutagenesis. J. Bacteriol. 149:114-122[Abstract/Free Full Text].
32.	Mulligan, J. T., and S. R. Long. 1989. A family of activator genes regulates expression of Rhizobium meliloti nodulation genes. Genetics 122:7-18[Abstract/Free Full Text].
33.	Mylona, P., K. Pawlowski, and T. Bisseling. 1995. Symbiotic nitrogen fixation. Plant Cell 7:869-885[Medline].
34.	Navarro, C., L.-F. Wu, and M. A. Mandrand-Berthelot. 1993. The nik operon of Escherichia coli encodes a periplasmic binding protein-dependent transport system for nickel homologous to the peptide permease family. Mol. Microbiol. 9:1181-1191[Medline].
35.	Ochman, H., A. S. Gerber, and D. L. Hartl. 1988. Genetic applications of an inverse polymerase chain reaction. Genetics 120:621-623[Abstract/Free Full Text].
36.	Philips, D. A., J. Wery, C. M. Joseph, A. D. Jones, and L. R. Teuber. 1995. Release of flavonoids and betaines from seeds of seven Medicago species. Crop Sci. 35:805-808. [Abstract/Free Full Text]
37.	Phillips, D. A. 1994. Synthesis, release and transmission of alfalfa signals to rhizobial symbionts. Plant Soil 161:69-80.
38.	Poole, P. S., A. Blyth, C. J. Reid, and K. Walters. 1994. myo-Inositol catabolism and catabolite repression in Rhizobium leguminosarum bv. viciae. Microbiology 140:2787-2795.
39.	Pueppke, S. G. 1996. The genetic and biochemical basis for nodulation of legumes by rhizobia. Crit. Rev. Biotechnol. 16:1-51[Medline].
40.	Reed, J. W., M. Capage, and G. C. Walker. 1991. Rhizobium meliloti exoG and exoJ mutations affect the ExoX-ExoY system for modulation of exopolysaccharide production. J. Bacteriol. 173:3776-3788[Abstract/Free Full Text].
41.	Rudner, D. Z., J. R. LeDeaux, K. Ireton, and A. D. Grossman. 1991. The spo0K locus of Bacillus subtilis is homologous to the oligopeptide permease locus and is required for sporulation and competence. J. Bacteriol. 173:1388-1398[Abstract/Free Full Text].
42.	Sharma, S. B., and E. R. Signer. 1990. Temporal and spatial regulation of the symbiotic genes of Rhizobium meliloti in planta revealed by transposon Tn5-gusA. Genes Dev. 4:344-356[Abstract/Free Full Text].
43.	Spaink, H. P. 1995. The molecular basis of infection and nodulation by rhizobia: the ins and outs of sympathogenesis. Annu. Rev. Phytopathol. 33:345-368.
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