The AGC Kinase MtIRE: A Link to Phospholipid Signaling During Nodulation?

The development of nitrogen fixing root nodules is complex and involves an interplay of signaling processes. During maturation of plant host cells and their endocytosed rhizobia in symbiosomes, host cells and symbiosomes expand. This expansion is accompanied by a large quantity of membrane biogenesis. We recently characterized an AGC kinase gene, MtIRE, that could play a role in this expansion. MtIRE''s expression coincides with host cell and symbiosome expansion in the proximal side of the invasion zone in developing Medicago truncatula nodules. MtIRE''s closest homolog is the Arabidopsis AGC kinase family IRE gene, which regulates root hair elongation. AGC kinases are regulated by phospholipid signaling in animals and fungi as well as in the several instances where they have been studied in plants. Here we suggest that a phospholipid signaling pathway may also activate MtIRE activity and propose possible upstream activators of MtIRE protein''s presumed AGC kinase activity.Key Words: AGC kinase, nitrogen fixation, nodulation, Medicago truncatula, Sinorhizobium meliloti, infection zone, 3-phosphoinositide-dependent kinase, root hair elongationDuring symbiotic nitrogen-fixing nodule development, both plant cells and rhizobia undergo cell division and expansion.^1–3 In legume roots, nodule organogenesis is triggered by rhizobial Nod factor at the emerging root hair zone. In the indeterminate Medicago-Sinorhizobium symbiosis, inner cortical cell divisions form nodule primordia which emerge from the root and differentiate into complex nodule structures. Rhizobia enter the nodules through plant derived conduits, the infection threads (ITs). ITs begin in curled root hairs, grow through several cell layers and end at nodule primordia where rhizobia are deposited into host cell symbiosomes.² In mature nodules, the meristematic zone I at the nodule apex contains dividing cells. Rhizobia from ITs infect these cells as they exit zone I and enter the infection zone, zone II. The newly released rhizobia, now termed bacteroids, are rod-shaped. In the distal part of zone II, bacteroids divide along with the symbiosome membrane (also called the peribacteroid membrane) that contains them.⁴ As the plant cells with their internalized bacteroids progress toward the proximal end of zone II, bacteroid division ceases. Bacteroid elongation and expansion of the surrounding symbiosome space and membrane is a feature of the proximal side of zone II.⁴ Enormous membrane biogenesis accompanies progression through zone II. As the cells exit zone II, both host cells and bacteroids stop expanding. Interzone II-III is characterized by starch accumulation and zone III is where nitrogen fixation takes place.Members of the protein kinase AGC (for cAMP dependent, cGMP dependent, and protein kinase C) family have been shown to be important in yeast and mammalian signal transduction. The interaction of growth factors with their receptors leads to the activation of phosphatidylinositol (PtdIns) 3-kinase and the phosphorylation of PtdIns species.⁵ These then activate PDK1 enzymes, 3-phosphoinositide-dependent kinases, also AGC kinases,⁵ which then phosphorylate and activate downstream AGC kinases. Several plant AGC kinases have important roles in development and defense,^6–8 although most plant AGC kinases'' functions are still to be discovered.⁹ Two Arabidopsis AGC kinases, IRE and AGC2-1 have been shown to have roles regulating root hair elongation.^10,11We recently cloned and characterized a Medicago IRE-like AGC kinase gene MtIRE,¹² possibly orthologous to the Arabidopsis IRE gene, AtIRE.¹⁰ Because of MtIRE''s homology to AtIRE we thought it might function during infection, because infection threads can be viewed as inward root hair growth. However, MtIRE''s expression is novel. It is expressed only in nodules and flowers and not in roots or root hairs. During nodule development, its initial expression correlates with the onset of host cell and symbiosome expansion. Expression studies with nodulation mutants demonstrate that MtIRE expression correlates with mutant nodules'' abilities to support host cell and symbiosome expansion.¹² An MtIRE promoter-gusA reporter construct (Fig. 1A) shows expression in the proximal part of zone II, the site of continued host cell expansion and bacteroid and symbiosome elongation. RNA interference experiments were unfortunately inconclusive,¹² probably because of closely related more ubiquitously expressed IRE homologs.Open in a separate windowFigure 1(A) Localization of pMtIRE-gusA expression in wild-type nodulated roots. Composite M. truncatula plants with transgenic roots were grown in the presence of S. meliloti and stained with X-Gluc (blue) for the localization of MtIRE promoter activity. The arrow points to the X-Gluc staining in the proximal side of zone II in a 15 dpi nodule. The arrowhead points to root hairs in which no staining was observed. Bar = 100 µM. (B) Phospholipid signaling pathway that may activate MtIRE protein''s presumed kinase activity.We predict that MtIRE is part of a signal pathway regulating an aspect of host cell expansion or symbiosome elongation, or both. The CCS52A gene has a demonstrated role in host cell expansion, mediating endoreduplication.¹³ In contrast to MtIRE, its expression is found throughout zone II, as well as zone I, where it acts in cell division. One might expect other genes that regulate host cell expansion to also be expressed throughout zone II, which MtIRE is not. A unique feature of the region expressing MtIRE is symbiosome elongation.⁴ Because of MtIRE''s temporal and spatial expression patterns, we favor it having a role in symbiosome expansion, although we cannot rule out a role in the latter stages of host cell expansion.Signaling pathway for MtIRE activation is speculative (Fig. 1B) and based on AGC kinase signaling in other systems. AGC kinases are activated by phosphorylation by phosphoinositide-dependent kinase (PDK1) enzymes, also AGC kinases.⁹ We found 4 tentative consensus sequences (TCs) in the DFCI index (compbio.dfci.harvard.edu) that correspond to PDK1 genes of which 3, TC107355, TC94724 and TC94899, were isolated from expression libraries from roots with developing or mature nodules. PDKs are activated by interaction with lipids. The Arabidopsis PDK1 binds to several signaling lipids, including phosphatidylinositol 3-phosphate (PtdIns3P) and phosphatidic acid (PA).¹⁴ Phosphatidylinositol 3-kinase (PI3K) activity produces PtdIns3P and PI3K genes have been observed to be induced during nodule organogenesis in soybean¹⁵ and in M. truncatula.¹⁶ In soybean, two PI3K genes were identified with one specifically expressed during the early stages of nodulation when membrane biogenesis takes place. This gene''s predicted protein has potential phosphorylation sites for cAMP dependent kinases and Ca/calmodulin-dependent kinases.¹⁵ In soybean, PI3K enzymatic activity correlated with membrane proliferation during nodulation.¹⁵ More generally, PI3Ks are implicated in vesicular trafficking and cytoskeletal organization;¹⁷ both are required for host cell and symbiosome elongation. We suggest a model where MtIRE kinase activity is activated by PDK1, which is itself regulated by PI3K through the production of PtdIns3P. More speculatively, PI3K could be under the control of the Nod factor signaling pathway Ca/calmodulin-dependent kinase DMI3.^18,19 DMI3 is induced during nodulation, with highest expression levels found in the distal side of the infection zone,²⁰ before expression of MtIRE. Expression could persist to the proximal side of this zone, similar to the expression of another Nod factor signaling component, DMI2.²¹ Alternatively, MtIRE could be activated by PA in a PDK1-dependent manner similar to Arabidopsis AGC2-1.¹¹ PA can be produced by phospholipase C (PLC) or phospholipase D (PLD) pathways, both of which have been implicated in transducing Nod factor signals.^22–26 Either of these models includes Nod factor signaling in proximal zone II, which has not been well-studied. Expression of rhizobial nod genes has been observed in zone II,²⁷ making Nod factor signaling in this zone plausible. Further examination of zone II and predicted upstream regulators of MtIRE will address this model.     

A putative transporter is essential for integrating nutrient and hormone signaling with lateral root growth and nodule development in Medicago truncatula

Legume root architecture involves not only elaboration of the root system by the formation of lateral roots but also the formation of symbiotic root nodules in association with nitrogen‐fixing soil rhizobia. The Medicago truncatula LATD/NIP gene plays an essential role in the development of both primary and lateral roots as well as nodule development. We have cloned the LATD/NIP gene and show that it encodes a member of the NRT1(PTR) transporter family. LATD/NIP is expressed throughout the plant. pLATD/NIP‐GFP promoter–reporter fusions in transgenic roots establish the spatial expression of LATD/NIP in primary root, lateral root and nodule meristems and the surrounding cells. Expression of LATD/NIP is regulated by hormones, in particular by abscisic acid which has been previously shown to rescue the primary and lateral root meristem arrest of latd mutants. latd mutants respond normally to ammonium but have defects in responses of the root architecture to nitrate. Taken together, these results suggest that LATD/NIP may encode a nitrate transporter or transporter of another compound.     

Control of root architecture and nodulation by the LATD/NIP transporter

The Medicago truncatula LATD/NIP gene is essential for the development of lateral and primary root and nitrogen-fixing nodule meristems as well as for rhizobial invasion of nodules. LATD/NIP encodes a member of the NRT1(PTR1) nitrate and di-and tri-peptide transporter family, suggesting that its function is to transport one of these or another compound(s). Because latd/nip mutants can have their lateral and primary root defects rescued by ABA, ABA is a potential substrate for transport. LATD/NIP expression in the root meristem was demonstrated to be regulated by auxin, cytokinin and abscisic acid, but not by nitrate. LATD/NIP''s potential function and its role in coordinating root architecture and nodule formation are discussed.Key words: nodule development, lateral root development, root architecture, symbiotic nitrogen fixation, Medicago truncatula, NRT1(PTR) gene familyUnlike most other plants, legumes form two kinds of lateral root organs: lateral roots and nitrogen-fixing root nodules that form in conjunction with compatible symbiotic rhizobium bacteria. Although the morphology and function of these two root organs is distinct, both require the function of the LATD/NIP gene, indicating shared genetic components for these two developmental processes and providing support for a model in which legume nodules evolved from a lateral root blueprint. Both lateral roots and nodules initiate in previously differentiated root cells in response to environmental and developmental cues mediated by hormones. Interestingly, regulation of nodules and lateral roots by hormones is often opposite, allowing formation of one organ or another depending on the conditions.     

nip, a symbiotic Medicago truncatula mutant that forms root nodules with aberrant infection threads and plant defense-like response

To investigate the legume-Rhizobium symbiosis, we isolated and studied a novel symbiotic mutant of the model legume Medicago truncatula, designated nip (numerous infections and polyphenolics). When grown on nitrogen-free media in the presence of the compatible bacterium Sinorhizobium meliloti, the nip mutant showed nitrogen deficiency symptoms. The mutant failed to form pink nitrogen-fixing nodules that occur in the wild-type symbiosis, but instead developed small bump-like nodules on its roots that were blocked at an early stage of development. Examination of the nip nodules by light microscopy after staining with X-Gal for S. meliloti expressing a constitutive GUS gene, by confocal microscopy following staining with SYTO-13, and by electron microscopy revealed that nip initiated symbiotic interactions and formed nodule primordia and infection threads. The infection threads in nip proliferated abnormally and very rarely deposited rhizobia into plant host cells; rhizobia failed to differentiate further in these cases. nip nodules contained autofluorescent cells and accumulated a brown pigment. Histochemical staining of nip nodules revealed this pigment to be polyphenolic accumulation. RNA blot analyses demonstrated that nip nodules expressed only a subset of genes associated with nodule organogenesis, as well as elevated expression of a host defense-associated phenylalanine ammonia lyase gene. nip plants were observed to have abnormal lateral roots. nip plant root growth and nodulation responded normally to ethylene inhibitors and precursors. Allelism tests showed that nip complements 14 other M. truncatula nodulation mutants but not latd, a mutant with a more severe nodulation phenotype as well as primary and lateral root defects. Thus, the nip mutant defines a new locus, NIP, required for appropriate infection thread development during invasion of the nascent nodule by rhizobia, normal lateral root elongation, and normal regulation of host defense-like responses during symbiotic interactions.     

Increased epidermal growth factor receptor in an estrogen-responsive,adriamycin-resistant MCF-7 cell line

We examined the expression of the estrogen and epidermal growth factor (EGF) receptors in a drug-resistant subline of MCF-7 cells in order to study potential alterations in hormone dependence or in the growth factor pathway that could be related to the development of drug resistance in human breast cancer. The drug-resistant subline was derived from MCF-7 cells by selection with Adriamycin in the presence of the P-giycoprotein antagonist, verapamil, to prevent acquisition of the classical multidrug resistance phenotype. The Adriamycin-resistant cells retain estrogen-binding, estrogen-responsive monolayer growth, and estrogen-dependent tumorigenesis. Estrogen-binding studies demonstrate 1.4 × 10⁶ sites per cell with unaltered affinity when compared to parental MCF-7 cells, which have 2.7 × 10⁵ sites per cell. An increase in expression of EGF receptor, eight to 12-fold, occurred early in the selection for drug resistance, and appears to be unrelated to verapamil exposure, since cells maintained in Adriamycin without verapamil also have increased EGF receptor expression. Partially drug-sensitive revertants carried a verapamil, but out of Adriamycin, demonstrate a decline in EGF receptor expression. We postulate that activation of growth factor pathways in drug-resistant cells may enhance mechanisms of drug resistance, or provide mitogenic stimuli for cells to recover after damage by drug exposure. © 1993 Wiley-Liss, Inc.     

Detection of ligand-induced perturbations affecting the biotinyl group of mammalian acetyl-coenzyme A carboxylase by using biotin-binding antibodies

Biotin-binding antibodies were raised in rabbits by injecting biotin-bovine serum albumin conjugate. Neither the protomer nor the polymer of rat mammary-gland acetyl-CoA carboxylase formed precipitin bands with the anti-biotin. By virtue of its ability to bind biotin (apparent binding constant for free biotin about 1mum), the anti-biotin inhibited the carboxylase activity under certain conditions. This property of the antibody was employed to detect the ligand-induced changes affecting the biotinyl group in different conformational states of mammalian carboxylase. Depending on the ligand present, the biotinyl group in the protomeric form was either accessible or inaccessible to the antibody. The biotinyl group of the protomer generated by a relatively high concentration of NaCl (0.5m) reacted with the antibody, and the antibody-carboxylase complex could not be converted into active enzyme by citrate. Further experiments showed that citrate failed to induce polymerization in this protomer-antibody complex and that anti-biotin could be displaced rapidly from this complex with excess of biotin. The resulting protomer was converted into the polymeric state on citrate addition, with parallel regain of enzyme activity. In the presence of ADP+Mg(2+), ATP+Mg(2+) or ATP+Mg(2+)+HCO(3) (-), however, the enzyme remained as a protomer, but its configuration was such that the biotinyl group was essentially inaccessible to the antibody. Likewise, the biotinyl group of the different polymeric forms of the carboxylase (s approximately 30-45S) engendered by phosphate, malonyl-CoA, acetyl-CoA or citrate remained essentially inaccessible, since their activity was minimally affected by the anti-biotin. In the presence of 0.15m-NaCl, the phosphate-induced polymer reverted to a approximately 19S form with concomitant appearance of anti-biotin-sensitivity, whereas the other polymeric forms remained unaffected under similar experimental conditions.     

Automated three-dimensional detection and shape classification of dendritic spines from fluorescence microscopy images

A fundamental challenge in understanding how dendritic spine morphology controls learning and memory has been quantifying three-dimensional (3D) spine shapes with sufficient precision to distinguish morphologic types, and sufficient throughput for robust statistical analysis. The necessity to analyze large volumetric data sets accurately, efficiently, and in true 3D has been a major bottleneck in deriving reliable relationships between altered neuronal function and changes in spine morphology. We introduce a novel system for automated detection, shape analysis and classification of dendritic spines from laser scanning microscopy (LSM) images that directly addresses these limitations. The system is more accurate, and at least an order of magnitude faster, than existing technologies. By operating fully in 3D the algorithm resolves spines that are undetectable with standard two-dimensional (2D) tools. Adaptive local thresholding, voxel clustering and Rayburst Sampling generate a profile of diameter estimates used to classify spines into morphologic types, while minimizing optical smear and quantization artifacts. The technique opens new horizons on the objective evaluation of spine changes with synaptic plasticity, normal development and aging, and with neurodegenerative disorders that impair cognitive function.     

Interactions between Pseudomonas syringae pv. tabaci and Two Rhizosphere Hosts, Medicago sativa and Avena sativa

The interactions between Pseudomonas syringae pv. tabaci and either nodulating alfalfa (Medicago sativa) or oat (Avena sativa) seedlings were examined to further our understanding of this rhizosphere association. P. syringae pv. tabaci produces and releases a toxin, tabtoxinine-β-lactam (TβL), that inactivates glutamine synthetase (GS). Sinorhizobium meliloti grew well in the presence of TβL in culture and on alfalfa roots. The alfalfa symbiont, S. meliloti, and its bacteroids contained TβL-sensitive glutamine synthetases and TβL detoxifying-β-lactamase. The GS of alfalfa leaves is also sensitive to TβL, but GS activity was unaffected in infested plants. Toxin production was apparently suppressed in the alfalfa and nitrate-fed oat rhizospheres since these plants survived and retained significant amounts of leaf GS activity. The water-soluble extracts of these rhizospheres inhibited TPL production in culture and the inhibition was correlated with the amount of reduced nitrogen present. Furthermore, representative mixtures of pure ammonium and amino acids inhibited TβL production in culture in a concentration dependent manner. Thus, a bi-directional interaction occurs between the nitrogen metabolism of alfalfa and oat and TβL production by P. syringae pv. tabaci.     

The Auxin Transport Inhibitor N-(1-Naphthyl)phthalamic Acid Elicits Pseudonodules on Nonnodulating Mutants of White Sweetclover

The collection of symbiotic (sym) mutants of white sweetclover (Melilotus alba Desr.) provides a developmental sequence of mutants blocked early in infection or nodule organogenesis. Mutant phenotypes include non-nodulating mutants that exhibit root-hair deformations in response to Rhizobium meliloti, mutants that form ineffective nodules lacking infection threads, and mutants that form infection threads and ineffective nodules. Mutant alleles from both the sym-1 and the sym-3 loci exhibited a non-nodulating phenotype in response to R. meliloti, although one allele in the sym-1 locus formed ineffective nodules at a low frequency. Spot-inoculation experiments on a non-nodulating allele in the sym-3 locus indicated that this mutant lacked cortical cell divisions following inoculation with R. meliloti. The auxin transport inhibitor N-(1-naphthyl)phthalamic acid elicited development of pseudonodules at a high frequency on all of the sweetclover sym mutants, including the non-nodulating mutants, in which the early nodulin ENOD2 was expressed. This suggests that N-(1-naphthyl)phthalamic acid activates cortical cell divisions by circumventing a secondary signal transduction event that is lacking in the non-nodulating sweetclover mutants. The sym-3 locus and possibly the sym-1 locus appear to be essential to early host plant responses essential to nodule organogenesis.