Uptake and translocation of phosphate by pho2 mutant and wild-type seedlings of Arabidopsis thaliana

The pho2 mutant of Arabidopsis thaliana (L.) Heynh. accumulates excessive Pi (inorganic phosphate) concentrations in shoots compared to wild-type plants (E. Delhaize and P. Randall, 1995, Plant Physiol. 107: 207–213). In this study, a series of experiments was conducted to compare the uptake and translocation of Pi by pho2 with that of wild-type plants. The pho2 mutants had about a twofold greater Pi uptake rate than wild-type plants under P-sufficient conditions and a greater proportion of the Pi taken up accumulated in shoots of pho2. When shoots were removed, the uptake rate by roots was found to be similar for both genotypes, suggesting that the greater Pi uptake by the intact pho2 mutant is due to a greater shoot sink for Pi. Although pho2 mutants could recycle ³²Pi from shoots to roots through phloem the proportion of ³²Pi translocated to roots was less than half of that found in wild-type plants. When transferred from P-sufficient to P-deficient solutions, Pi concentrations in pho2 roots had a similar depletion rate to wild-type roots despite pho2 shoots having a fourfold greater Pi concentration than wild-type shoots throughout the experiment. We suggest that the pho2 phenotype could result from a partial defect in Pi transport in the phloem between shoots and roots or from an inability of shoot cells to regulate internal Pi concentrations. Received: 20 August 1997 / Accepted: 4 October 1997     

Characterization of a Phosphate-Accumulator Mutant of Arabidopsis thaliana

We have characterized a novel mutation of Arabidopsis thaliana at a locus designated pho2. pho2 mutants accumulated up to 3-fold more total P in leaves, mostly as inorganic phosphate (Pi), than wild-type seedlings. In addition, we isolated a mutant (locus designated pho1-2, an allelle of pho1-1 described by Y. Poirier, S. Thoma, C. Somerville, J. Schiefelbein [1991] Plant Physiol 97: 1087-1093) with low Pi concentrations in leaves. When grown under high transpiration conditions, leaves of pho2 seedlings became severely P intoxicated, whereas shoots of pho1-2 mutants were P deficient and wild-type seedlings were normal. A pho1/pho2 double mutant resulting from a cross between the single mutants was identified in the F2 generation and shown to have a pho1 phenotype. Prior to the development of P toxicity symptoms, P was the only mineral nutrient whose concentration was greater in pho2 mutants than wild-type seedlings. Compared to wild-type, pho2 mutants had greater Pi concentrations in stems, siliques, and seeds, but roots of pho2 mutants had similar or lower Pi concentrations than either pho1 mutants or wild-type seedlings. We suggest that the pho2 mutation affects a function normally involved in regulating the concentration of Pi in shoots of Arabidopsis.     

pho3: a phosphorus-deficient mutant of Arabidopsis thaliana (L.) Heynh

A novel P-deficient mutant of Arabidopsis thaliana, pho3, was isolated by screening for root acid phosphatase (APase) activity in plants grown under low-P conditions. pho3 had 30% less APase activity in roots than the wild type and, in contrast to wild-type plants, root APase activity did not increase in response to growth in low P. However, shoot APase activity was higher in pho3 than in the wild-type plants. In addition, the pho3 mutant had a P-deficient phenotype, even when grown in P-sufficient conditions. The total P content of 11-d-old pho3 plants, grown in agar media with a plentiful supply of P, was about 25% lower than the wild-type level in the shoot, and about 65% lower in the roots. In the rosette leaves of mature soil-grown pho3 plants the total P content was again reduced, to about 50% of wild-type levels. pho3 exhibited a number of characteristics normally associated with low-P stress, including severely reduced growth, increased anthocyanin content (at least 100-fold greater than the wild type in soil-grown plants) and starch accumulation. The results suggest that the mutant is unable to respond to low internal P levels, and may lack a transporter or a signalling component involved in regulating P nutrition. Received: 21 March 2000 / Accepted: 15 August 2000     

Influence of prior Cd(2+) exposure on the uptake of Cd(2+) and other elements in the phytochelatin-deficient mutant, cad1-3, of Arabidopsis thaliana

In order to test the potential effect of prior exposure to different Cd concentrations on Cd uptake and accumulation, plants of Arabidopsis thaliana, including a phytochelatin-deficient mutant, cad1-3, and the wild type, were compared. For Cd uptake experiments, plants were grown for 1 week in nutrient solution containing different Cd concentrations (0, 0.05, 0.1, 0.25, 0.5, and 1.0 microM Cd(NO(3))(2)). Thereafter they were subjected to 0.5 microM Cd labelled with (109)Cd for 2 h. Uptake experiments with (109)Cd showed that the phytochelatin-deficient mutant cad1-3, accumulated less Cd than the wild type. Both a lower proportion and lower total amount of absorbed Cd were translocated to the shoot in cad1-3 plants compared to wild-type plants. Cadmium exposure also influenced the amounts of nutrients found, whereby after exposure to high Cd concentrations (0.5, 1.0 microM) during growth, cad1-3 roots contained less Fe, K, Mg, P, and S compared to roots of the wild type. In cad1-3 these elements decreased with increasing Cd concentration. The total Cd content in roots and shoots increased significantly with increasing Cd concentration during growth, although the increase was much less in cad1-3 plants. In time-dependent experiments of Cd uptake carried out between 15 and 120 min on plants not previously exposed to Cd, no significant difference in Cd accumulation between the mutant and wild type were found, although a smaller amount of Cd was translocated to the shoot in cad1-3 plants. The possibility that the differences in Cd accumulation in mutant and wild-type lines may be due to the cytosolic Cd regulation, which is inhibited by the complexation of Cd by phytochelatins, is discussed.     

Regulatory network of microRNA399 and PHO2 by systemic signaling

Recently, we showed that microRNA399s (miR399s) control inorganic phosphate (Pi) homeostasis by regulating the expression of PHO2 encoding a ubiquitin-conjugating E2 enzyme 24. Arabidopsis (Arabidopsis thaliana) plants overexpressing miR399 or the pho2 mutant overaccumulate Pi in shoots. The association of Pi translocation and coexpression of miR399s and PHO2 in vascular tissues suggests their involvement in long-distance signaling. In this study, we used reciprocal grafting between wild-type and miR399-overexpressing transgenic plants to dissect the systemic roles of miR399 and PHO2. Arabidopsis rootstocks overexpressing miR399 showed high accumulation of Pi in the wild-type scions because of reduced PHO2 expression in the rootstocks. Although miR399 precursors or expression was not detected, we found a small but substantial amount of mature miR399 in the wild-type rootstocks grafted with transgenic scions, which indicates the movement of miR399 from shoots to roots. Suppression of PHO2 with miR399b or c was less efficient than that with miR399f. Of note, findings in grafted Arabidopsis were also discovered in grafted tobacco (Nicotiana benthamiana) plants. The analysis of the pho1 mutant provides additional support for systemic suppression of PHO2 by the movement of miR399 from Pi-depleted shoots to Pi-sufficient roots. We propose that the long-distance movement of miR399s from shoots to roots is crucial to enhance Pi uptake and translocation during the onset of Pi deficiency. Moreover, PHO2 small interfering RNAs mediated by the cleavage of miR399s may function to refine the suppression of PHO2. The regulation of miR399 and PHO2 via long-distance communication in response to Pi deficiency is discussed.     

Arabidopsis thaliana wild type, pho1, and pho2 mutant plants show different responses to exogenous cytokinins.

Despite the involvement of cytokinins in phosphate (Pi) signaling being highlighted, the physiological processes involved remain unclear. In this study, we have evaluated the effect of cytokinins on different physiological responses using wild type (wt) and two Arabidopsis mutants with altered shoot Pi content (pho1 and pho2). Physiological studies were related with those previously described as cytokinin-regulated: including hypocotyl elongation, root growth, anthocyanin accumulation, senescence and relative gene expression. Generally, pho1 mutants showed decreased sensitivity to cytokinin, whereas pho2 mutants showed increased sensitivity to the hormone. This observation applies to inhibition of hypocotyls and root growth and anthocyanin accumulation. However, this effect was not shown during senescence or in the expression of ARR6 (Arabidopsis response regulator, ARR). Interestingly, Pi content in shoot of pho1 mutants increased to wt levels after treatment with cytokinins. These results suggest that the interaction between phosphate signaling and cytokinin signaling may be bidirectional while the differential behavior in response to cytokinin is discussed further.     

Expressing ScACR3 in rice enhanced arsenite efflux and reduced arsenic accumulation in rice grains

Arsenic (As) accumulation in rice grain poses a serious health risk to populations with high rice consumption. Extrusion of arsenite [As(III)] by ScAcr3p is the major arsenic detoxification mechanism in Saccharomyces cerevisiae. However, ScAcr3p homolog is absent in higher plants, including rice. In this study, ScACR3 was introduced into rice and expressed under the control of the Cauliflower mosaic virus (CaMV) 35S promoter. In the transgenic lines, As concentrations in shoots and roots were about 30% lower than in the wild type, while the As translocation factors were similar between transgenic lines and the wild type. The roots of transgenic plants exhibited significantly higher As efflux activities than those of the wild type. Within 24 h exposure to 10 μM arsenate [As(V)], roots of ScACR3-expressing plants extruded 80% of absorbed As(V) to the external solution as As(III), while roots of the wild type extruded 50% of absorbed As(V). Additionally, by exposing the As-containing rice plants to an As-lacking solution for 24 h, about 30% of the total As derived from pre-treatment was extruded to the external solution by ScACR3-expressing plants, while about 15% of As was extruded by wild-type plants. Importantly, ScACR3 expression significantly reduced As accumulation in rice straws and grains. When grown in flooded soil irrigated with As(III)-containing water, the As concentration in husk and brown rice of the transgenic lines was reduced by 30 and 20%, respectively, compared with the wild type. This study reports a potential strategy to reduce As accumulation in the food chain by expressing heterologous genes in crops.     

Identification of mutants in phosphorus metabolism

Phosphorus availability is often limiting for plant growth. However, little is known of the pathways and mechanisms that regulate phosphorus (P) uptake and distribution in plants. We have developed a screen based on the induction of secreted root acid phosphatase activity by low‐P stress to identify mutants of Arabidopsis thaliana with defects in P metabolism. Acid phosphatase activity was detected visually in the roots of A. thaliana seedlings grown in vitro on low‐P medium, using the chromogenic substrate, 5‐bromo‐4‐chloro‐3‐indolyl‐phosphate (BCIP). In low‐P stress conditions the roots of wild‐type plants stained blue, as the induced root acid phosphatase cleaved BCIP to release the coloured product. Potential mutants were identified as having white, or pale blue, roots under these conditions. Out of approximately 79 000 T‐DNA mutagenised seedlings screened, two mutants with reduced acid phosphatase staining were further characterised. Both exhibited reduced growth and differences in their P contents when compared to wild‐type A. thaliana. The mutant with the most severe phenotype, pho3, accumulated high levels of anthocyanins and starch in a distinctive visual pattern within the leaves. The phenotypes of these mutants are distinct from two previously identified phosphorus mutants (phol and pho2) and from an acid phosphatase deficient mutant (pupl) of A. thaliana. This suggested that the screening method was robust and might lead to the identification of further mutants with the potential for increasing our understanding of P nutrition.     

Symbiotic phenotypes and translocated effector proteins of the Mesorhizobium loti strain R7A VirB/D4 type IV secretion system

The symbiosis island of Mesorhizobium loti strain R7A contains genes with strong similarity to the structural vir genes (virB1-11; virD4) of Agrobacterium tumefaciens that encode the type IV secretion system (T4SS) required for T-DNA transfer to plants. In contrast, M. loti strain MAFF303099 lacks these genes but contains genes not present in strain R7A that encode a type III secretion system (T3SS). Here we show by hybridization analysis that most M. loti strains contain the VirB/D4 T4SS and not the T3SS. Strikingly, strain R7A vir gene mutants formed large nodules containing bacteroids on Leucaena leucocephala in contrast to the wild-type strain that formed only uninfected tumour-like structures. A rhcJ T3SS mutant of strain MAFF303099 also nodulated L. leucocephala, unlike the wild type. On Lotus corniculatus, the vir mutants were delayed in nodulation and were less competitive compared with the wild type. Two strain R7A genes, msi059 and msi061, were identified through their mutant phenotypes as possibly encoding translocated effector proteins. Both Msi059 and Msi061 were translocated through the A. tumefaciens VirB/D4 system into Saccharomyces cerevisiae and Arabidopsis thaliana, as shown using the Cre recombinase Reporter Assay for Translocation (CRAfT). Taken together, these results suggest that the VirB/D4 T4SS of M. loti R7A plays an analogous symbiotic role to that of T3SS found in other rhizobia. The heterologous translocation of rhizobial proteins by the Agrobacterium VirB/D4 T4SS is the first demonstration that rhizobial effector proteins are translocated into plant cells and confirms functional conservation between the M. loti and A. tumefaciens T4SS.     

An improved grafting technique for mature Arabidopsis plants demonstrates long-distance shoot-to-root transport of phytochelatins in Arabidopsis

Phytochelatins (PCs) are peptides that function in heavy-metal chelation and detoxification in plants and fungi. A recent study showed that PCs have the ability to undergo long-distance transport in a root-to-shoot direction in transgenic Arabidopsis (Arabidopsis thaliana). To determine whether long-distance transport of PCs can occur in the opposite direction, from shoots to roots, the wheat (Triticum aestivum) PC synthase (TaPCS1) gene was expressed under the control of a shoot-specific promoter (CAB2) in an Arabidopsis PC-deficient mutant, cad1-3 (CAB2TaPCS1/cad1-3). Analyses demonstrated that TaPCS1 is expressed only in shoots and that CAB2TaPCS1/cad1-3 lines complement the cadmium (Cd) and arsenic metal sensitivity of cad1-3 shoots. CAB2TaPCS1/cad1-3 plants exhibited higher Cd accumulation in roots and lower Cd accumulation in shoots compared to wild type. Fluorescence HPLC coupled to mass spectrometry analyses directly detected PC2 in the roots of CAB2:TaPCS1/cad1-3 but not in cad1-3 controls, suggesting that PC2 is transported over long distances in the shoot-to-root direction. In addition, wild-type shoot tissues were grafted onto PC synthase cad1-3 atpcs2-1 double loss-of-function mutant root tissues. An Arabidopsis grafting technique for mature plants was modified to obtain an 84% success rate, significantly greater than a previous rate of approximately 11%. Fluorescence HPLC-mass spectrometry showed the presence of PC2, PC3, and PC4 in the root tissue of grafts between wild-type shoots and cad1-3 atpcs2-1 double-mutant roots, demonstrating that PCs are transported over long distances from shoots to roots in Arabidopsis.     

Complexation of Arsenite with Phytochelatins Reduces Arsenite Efflux and Translocation from Roots to Shoots in Arabidopsis

Complexation of arsenite [As(III)] with phytochelatins (PCs) is an important mechanism employed by plants to detoxify As; how this complexation affects As mobility was little known. We used high-resolution inductively coupled plasma-mass spectrometry and accurate mass electrospray ionization-mass spectrometry coupled to HPLC to identify and quantify As(III)-thiol complexes and free thiol compounds in Arabidopsis (Arabidopsis thaliana) exposed to arsenate [As(V)]. As(V) was efficiently reduced to As(III) in roots. In wild-type roots, 69% of As was complexed as As(III)-PC₄, As(III)-PC₃, and As(III)-(PC₂)₂. Both the glutathione (GSH)-deficient mutant cad2-1 and the PC-deficient mutant cad1-3 were approximately 20 times more sensitive to As(V) than the wild type. In cad1-3 roots, only 8% of As was complexed with GSH as As(III)-(GS)₃ and no As(III)-PCs were detected, while in cad2-1 roots, As(III)-PCs accounted for only 25% of the total As. The two mutants had a greater As mobility, with a significantly higher accumulation of As(III) in shoots and 4.5 to 12 times higher shoot-to-root As concentration ratio than the wild type. Roots also effluxed a substantial proportion of the As(V) taken up as As(III) to the external medium, and this efflux was larger in the two mutants. Furthermore, when wild-type plants were exposed to l-buthionine sulfoximine or deprived of sulfur, both As(III) efflux and root-to-shoot translocation were enhanced. The results indicate that complexation of As(III) with PCs in Arabidopsis roots decreases its mobility for both efflux to the external medium and for root-to-shoot translocation. Enhancing PC synthesis in roots may be an effective strategy to reduce As translocation to the edible organs of food crops.Arsenic (As) contamination in the environment is caused by both geogenically and/or anthropogenically derived activities. This problem is the most serious in South and Southeast Asia where As-contaminated groundwater has been extracted for drinking and for irrigating rice (Oryza sativa) crops (Brammer and Ravenscroft, 2009). As contamination in soil can cause phytotoxicity and consequently yield losses (Panaullah et al., 2009) and elevated levels of As in rice grain that may pose a significant risk to human health (Meharg and Rahman, 2003; Zhu et al., 2008; Meharg et al., 2009). To develop mitigation strategies to reduce the transfer of As to the food chain requires a better understanding of the mechanisms of As uptake, translocation, and detoxification. It is known that As accumulation varies greatly among different plant species (e.g. Raab et al., 2007) and also among different genotypes within a species (e.g. Norton et al., 2009). Since root-to-shoot translocation is often the bottleneck for the accumulation of metal(loid)s in the shoots (Zhao and McGrath, 2009), understanding what controls As translocation within plants is important for designing strategies to decrease As concentrations in the edible parts of food crops.With the exception of As hyperaccumulating plants, translocation of As from roots to shoots is generally restricted in most plant species (for review, see Zhao et al., 2009). An explanation for this limited translocation is that arsenate [As(V)] is rapidly reduced to arsenite [As(III)] in roots, followed by complexation of As(III) with phytochelatins (PCs) and subsequent sequestration in root vacuoles (Dhankher et al., 2006; Raab et al., 2007; Zhao et al., 2009). The extent of As(III) complexation may therefore determine its mobility in roots. To test this hypothesis, we used the model plant Arabidopsis (Arabidopsis thaliana) mutants defective in glutathione (GSH) or PC synthesis, as well as manipulation of thiol synthesis in wild-type plants by the use of the specific inhibitor l-buthionine sulfoximine (BSO) and sulfur (S) deprivation. Both the PC-deficient mutant cad1-3 and the GSH-deficient mutant cad2-1 were isolated by their phenotype of cadmium (Cd) sensitivity (Howden et al., 1995a, 1995b). cad1-3 is a recessive loss-of-function mutant with a mutation in the PC synthase gene (AtPCS1; Ha et al., 1999) and is unable to synthesize PCs in response to Cd exposure (Howden et al., 1995b). cad2-1 has a deletion in the gene encoding the γ-glutamylcysteine synthetase, resulting in 60% to 85% lower levels of GSH compared with the wild type and little production of PCs in response to Cd exposure (Howden et al., 1995a; Cobbett et al., 1998).As(III) has a high affinity to thiol groups, and there is strong evidence that PCs play a constitutive role in the detoxification of As through complexation of As(III) in As nonhyperaccumulator plants. As strongly induces PC synthesis (Grill et al., 1987; Sneller et al., 1999; Schmöger et al., 2000). Both cad1-3 and cad2-1 are hypersensitive to As(V) (Ha et al., 1999; Li et al., 2006). Inhibition of GSH and PC synthesis by BSO results in As hypersensitivity in a number of plant species (Schmöger et al., 2000; Hartley-Whitaker et al., 2002; Schat et al., 2002). It has been shown that overexpression of PCS enhances As tolerance in transgenic plants, but interestingly not As accumulation (Li et al., 2004; Gasic and Korban, 2007). Furthermore, a range of intact As(III)-PC complexes has been identified in sunflower (Helianthus annuus) and Thunbergia alata plants after exposure to As(V) or As(III) (Raab et al., 2005; Bluemlein et al., 2008). In contrast, As hyperaccumulators, such as Pteris vittata, appear not to rely mainly on PC-dependent strategies for As detoxification, as very small proportions of As in roots and fronds are complexed with thiols (Webb et al., 2003; Zhao et al., 2003; Raab et al., 2004; Pickering et al., 2006). Lack of As(III)-PC complexation in P. vittata may be one of the important reasons for the highly efficient translocation of As from roots to fronds (Su et al., 2008; Zhao et al., 2009).While the role of PCs in As sensitivity is well established, how they influence As mobility in plants is not clear. Gong et al. (2003) showed that PCs may be transported from roots to shoots in a study involving root-specific expression of the wheat (Triticum aestivum) PCS gene (TaPCS1) in the Arabidopsis cad3-1 mutant. Furthermore, both root-specific and ectopic expression of TaPCS1 was found to enhance long-distance transport of Cd from roots to stems and rosette leaves, suggesting that PCs may be carriers of Cd in xylem transport. However, direct measurements of the xylem sap collected from As-exposed sunflower showed only traces of nonreactive oxidized PC₂ and oxidized glutathione (GSSG) with no evidence of As-PC complexation (Raab et al., 2005). Similarly, only trace levels of PCs were detected in the xylem sap from Cd-exposed Brassica napus (Mendoza-Cózatl et al., 2008). The role of PCs in the xylem mobility of As has not been investigated in detail. Interestingly, recent studies have shown that GSH, PCs, and other thiol peptides can be transported from shoots to roots via phloem (Chen et al., 2006; Li et al., 2006). High levels of PCs, GSH, and Cd were found in the phloem sap of B. napus, suggesting that thiol peptides may be carriers of Cd in the long-distance phloem transport (Mendoza-Cózatl et al., 2008).Here, we present evidence that decreasing As(III)-PC complexation in Arabidopsis roots led to greater As mobility, manifested by enhanced As(III) efflux to the external medium and enhanced As translocation from roots to shoots.     

一种筛选拟南芥突变体的有效方法

经甲基磺酸乙酯（EMS）诱变处理的拟南芥种子,接种于MS培养基上,垂直放置培养4天后,将幼苗转移至胁迫培养基中,以倒置幼苗180°所形成的弯曲生长根作为指标筛选拟南芥耐营养胁迫突变体。利用这种方法,成功地筛选到一个耐低钾的隐性单基因拟南芥突变体。本方法同样适用于其他类型突变体的筛选。 Abstract：his paper introduces a root-bending assay for isol ation of Arabidopsis mutants tolerant to nutrition stress. Seeds of wild-ty pe Arabidopsis thaliana (ecotype Landersberg erecta) were mutagenized wi th ethyl methyl sulfide (EMS),and M2 populations were screened for mutants. Fo ur-day-old seedlings with 1-to 1.5-cm-long roots were transferred from the vertical agar plates onto to a second agar medium that was supplemented with det erminate stress. The seedlings were arranged in rows, and the plates were orient ed vertically with the roots pointing upward. After another 4 days, the root be nding seedlings were selected for putative mutants and transferred to soil to gr ow to maturity.Seeds from the putative mutants were screened again to determine the true mutants.By using this root-bending assay we have isolated a low-K+-tolerant (lkt1) mutant which is caused by single recessive nuclear mutation. F or lkt1 mutant screening,K+concentration of the medium was 100μmol/L because root growth of wild type seedlings was completely inhibited at or below this con centration.This root-bending assay is also applicable to other type of Arabid opsis mutant isolation.     

Expression of Arabidopsis phytochelatin synthase 2 is too low to complement an AtPCS1-defective Cad1-3 mutant

Phytochelatins play an important role in heavy metal detoxification in plants as well as in other organisms. The Arabidopsis thaliana mutant cad1-3 does not produce detectable levels of phytochelatins in response to cadmium stress. The hypersensitivity of cad1-3 to cadmium stress is attributed to a mutation in the phytochelatin synthase 1 (AtPCS1) gene. However, A. thaliana also contains a functional phytochelatin synthase 2 (AtPCS2). In this study, we investigated why the cad1-3 mutant is hypersensitive to cadmium stress despite the presence of AtPCS2. Northern and Western blot analyses showed that expression of AtPCS2 is weak compared to AtPCS1 in both roots and shoots of transgenic Arabidopsis. The lower level of AtPCS2 expression was confirmed by RT-PCR analysis of wild type Arabidopsis. Moreover, no tissue-specific expression of AtPCS2 was observed. Even when AtPCS2 was under the control of the AtPCS1 promoter or of the cauliflower mosaic virus 35S promoter (CaMV 35S) it was not capable of fully complementing the cad1-3 mutant for cadmium resistance.     

A metal-accumulator mutant of Arabidopsis thaliana.

A mutation designated man1 (for manganese accumulator) was found to cause Arabidopsis thaliana seedlings to accumulate a range of metals. The man1 mutation segregated as a single recessive locus located on chromosome 3. When grown on soil, mutant seedlings accumulated Mn (7.5 times greater than wild type), Cu (4.6 times greater than wild type), Zn (2.8 times greater than wild type), and Mg (1.8 times greater than wild type) in leaves. In addition to these metals, the man1 mutant accumulated 2.7-fold more S in leaves, primarily in the oxidized form, than wild-type seedlings. Analysis of seedlings grown by hydroponic culture showed a similar accumulation of metals in leaves of man1 mutants. Roots of man1 mutants also accumulated metals, but unlike leaves they accumulated 10-fold more total Fe (symplasmic and apoplasmic combined) than wild-type roots. Roots of man1 mutants possessed greater (from 1.8- to 20-fold) ferric-chelate reductase activity than wild-type seedings, and this activity was not responsive to changes of Mn nutrition in either genotype. Taken together, these results suggest that the man1 mutation disrupts the regulation of metal-ion uptake or homeostasis in Arabidopsis.     

Pseudomonas syringae HrpJ is a type III secreted protein that is required for plant pathogenesis, injection of effectors, and secretion of the HrpZ1 Harpin

The bacterial plant pathogen Pseudomonas syringae requires a type III protein secretion system (TTSS) to cause disease. The P. syringae TTSS is encoded by the hrp-hrc gene cluster. One of the genes within this cluster, hrpJ, encodes a protein with weak similarity to YopN, a type III secreted protein from the animal pathogenic Yersinia species. Here, we show that HrpJ is secreted in culture and translocated into plant cells by the P. syringae pv. tomato DC3000 TTSS. A DC3000 hrpJ mutant, UNL140, was greatly reduced in its ability to cause disease symptoms and multiply in Arabidopsis thaliana. UNL140 exhibited a reduced ability to elicit a hypersensitive response (HR) in nonhost tobacco plants. UNL140 was unable to elicit an AvrRpt2- or AvrB1-dependent HR in A. thaliana but maintained its ability to secrete AvrB1 in culture via the TTSS. Additionally, UNL140 was defective in its ability to translocate the effectors AvrPto1, HopB1, and AvrPtoB. Type III secretion assays showed that UNL140 secreted HrpA1 and AvrPto1 but was unable to secrete HrpZ1, a protein that is normally secreted in culture in relatively large amounts, into culture supernatants. Taken together, our data indicate that HrpJ is a type III secreted protein that is important for pathogenicity and the translocation of effectors into plant cells. Based on the failure of UNL140 to secrete HrpZ1, HrpJ may play a role in controlling type III secretion, and in its absence, specific accessory proteins, like HrpZ1, may not be extracellularly localized, resulting in disabled translocation of effectors into plant cells.     

Evidence for altered polar and lateral auxin transport in the gravity persistent signal (gps) mutants of Arabidopsis

Plant shoots do not respond when they are reoriented relative to gravity at 4 degrees C. However, when returned to vertical at room temperature, these organs bend in response to the previous cold gravistimulation. The inflorescence stem of the Arabidopsis thaliana gravity persistent signal (gps) mutants respond abnormally after the cold gravistimulation: gps1 does not bend when returned to room temperature, gps2 bends the wrong way and gps3 over-responds, curving past the predicted angle. In wild type and the mutants, basipetal auxin transport in the inflorescence stem was abolished at 4 degrees C but restored when plants were returned to room temperature. In gps1, auxin transport was increased; in both gps2 and gps3, no significant difference was found when compared to wild type. Expression of the auxin-inducible P(IAA2)::GUS reporter gene, indicated that auxin-induced gene expression was redistributed to the lower side of the inflorescence stem in wild type after gravistimulation at 4 degrees C. In gps1, no asymmetries in P(IAA2)::GUS expression were seen. In gps2, P(IAA2)::GUS expression was localized to the upper side of the stem and in gps3, asymmetric P(IAA2):GUS expression was extended throughout the elongation zone of the inflorescence stem. These results are consistent with altered lateral Indole-3-acetic-acid (IAA) gradients being responsible for the phenotype of each mutant.