Functional,structural and phylogenetic analysis of domains underlying the Al sensitivity of the aluminum‐activated malate/anion transporter,TaALMT1

Triticum aestivum aluminum‐activated malate transporter (TaALMT1) is the founding member of a unique gene family of anion transporters (ALMTs) that mediate the efflux of organic acids. A small sub‐group of root‐localized ALMTs, including TaALMT1, is physiologically associated with in planta aluminum (Al) resistance. TaALMT1 exhibits significant enhancement of transport activity in response to extracellular Al. In this study, we integrated structure–function analyses of structurally altered TaALMT1 proteins expressed in Xenopus oocytes with phylogenic analyses of the ALMT family. Our aim is to re‐examine the role of protein domains in terms of their potential involvement in the Al‐dependent enhancement (i.e. Al‐responsiveness) of TaALMT1 transport activity, as well as the roles of all its 43 negatively charged amino acid residues. Our results indicate that the N‐domain, which is predicted to form the conductive pathway, mediates ion transport even in the absence of the C‐domain. However, segments in both domains are involved in Al³⁺ sensing. We identified two regions, one at the N‐terminus and a hydrophobic region at the C‐terminus, that jointly contribute to the Al‐response phenotype. Interestingly, the characteristic motif at the N‐terminus appears to be specific for Al‐responsive ALMTs. Our study highlights the need to include a comprehensive phylogenetic analysis when drawing inferences from structure–function analyses, as a significant proportion of the functional changes observed for TaALMT1 are most likely the result of alterations in the overall structural integrity of ALMT family proteins rather than modifications of specific sites involved in Al³⁺ sensing.     

Role of TaALMT1 malate-GABA transporter in alkaline pH tolerance of wheat

Malate exudation through wheat (Triticum aestivum L) aluminium-activated malate transporter 1 (TaALMT1) confers Al³⁺ tolerance at low pH, but is also activated by alkaline pH, and is regulated by and facilitates significant transport of gamma-aminobutyric acid (GABA, a zwitterionic buffer). Therefore, TaALMT1 may facilitate acidification of an alkaline rhizosphere by promoting exudation of both malate and GABA. Here, the performance of wheat near isogenic lines ET8 (Al⁺³-tolerant, high TaALMT1 expression) and ES8 (Al⁺³-sensitive, low TaALMT1 expression) are compared. Root growth (at 5 weeks) was higher for ET8 than ES8 at pH 9. ET8 roots exuded more malate and GABA at high pH and acidified the rhizosphere more rapidly. GABA and malate exudation was enhanced at high pH by the addition of aluminate in both ET8 and transgenic barley expressing TaALMT1. Xenopus laevis oocytes expressing TaALMT1 acidified an alkaline media more rapidly than controls corresponding to higher GABA efflux. TaALMT1 expression did not change under alkaline conditions but key genes involved in GABA turnover changed in accordance with a high rate of GABA synthesis. We propose that TaALMT1 plays a role in alkaline tolerance by exuding malate and GABA, possibly coupled to proton efflux.     

Phosphorylation at S384 regulates the activity of the TaALMT1 malate transporter that underlies aluminum resistance in wheat

In this study we examined the role of protein phosphorylation/dephosphorylation in the transport properties of the wheat ( Triticum aestivum ) root malate efflux transporter underlying Al resistance, TaALMT1. Pre-incubation of Xenopus laevis oocytes expressing TaALMT1 with protein kinase inhibitors (K252a and staurosporine) strongly inhibited both basal and Al³⁺-enhanced TaALMT1-mediated inward currents (malate efflux). Pre-incubation with phosphatase inhibitors (okadaic acid and cyclosporine A) resulted in a modest inhibition of the TaALMT1-mediated currents. Exposure to the protein kinase C (PKC) activator, phorbol 12-myristate 13-acetate (PMA), enhanced TaALMT1-mediated inward currents. Since these observations suggest that TaALMT1 transport activity is regulated by PKC-mediated phosphorylation, we proceeded to modify candidate amino acids in the TaALMT1 protein in an effort to identify structural motifs underlying the process regulating phosphorylation. The transport properties of eight single point mutations (S56A, S183A, S324A, S337A, S351-352A, S384A, T323A and Y184F) generated in amino acid residues predicted to be phosphorylation sites and examined electrophysiologically. The basic transport properties of mutants S56A, S183A, S324A, S337A, S351-352A, T323A and Y184F were not altered relative to the wild-type TaALMT1. Likewise the sensitivity of these mutants to staurosporine resembled that observed for the wild-type transporter. However, the mutation S384A was noticeable, as in oocytes expressing this mutant protein TaALMT1-mediated basal and Al-enhanced currents were significantly inhibited, and the currents were insensitive to staurosporine or PMA. These findings indicate that S384 is an essential residue regulating TaALMT1 activity via direct protein phosphorylation, which precedes Al³⁺ enhancement of transport activity.     

Several lanthanides activate malate efflux from roots of aluminium‐tolerant wheat

Many elements of the lanthanide series exist as trivalent cations in solution below pH 6. The present study was carried out to investigate whether lanthanides could stimulate malate efflux from wheat (Triticum aestivum L.) roots, as has been found for trivalent aluminium (Al) cations. Excised root apices treated with 100 µm of each of seven different lanthanide elements (lanthanum, praseodymium, europium, gadolinium, terbium, erbium, and ytterbium) stimulated malate efflux, with five‐ to fifty‐fold more malate being released from an Al‐tolerant wheat line than from a near‐isogenic Al‐sensitive line. As erbium stimulated the greatest malate efflux of the lanthanides tested, this response was characterized further. The characteristics of the erbium‐activated efflux were similar to the Al‐activated efflux described previously suggesting that both of these ions activate the same transport mechanism. The capacity for erbium‐activated malate efflux cosegregated with Al tolerance in wheat seedlings derived from a cross between Al‐sensitive and Al‐tolerant near‐isogenic lines. This is the first study to identify cations, other than Al, which can activate malate release from wheat roots. It also provides additional evidence that malate efflux from root apices is the primary mechanism for Al tolerance in wheat.     

AtALMT12 represents an R‐type anion channel required for stomatal movement in Arabidopsis guard cells

Stomatal pores formed by a pair of guard cells in the leaf epidermis control gas exchange and transpirational water loss. Stomatal closure is mediated by the release of potassium and anions from guard cells. Anion efflux from guard cells involves slow (S‐type) and rapid (R‐type) anion channels. Recently the SLAC1 gene has been shown to encode the slow, voltage‐independent anion channel component in guard cells. In contrast, the R‐type channel still awaits identification. Here, we show that AtALMT12, a member of the aluminum activated malate transporter family in Arabidopsis, represents a guard cell R‐type anion channel. AtALMT12 is highly expressed in guard cells and is targeted to the plasma membrane. Plants lacking AtALMT12 are impaired in dark‐ and CO₂‐induced stomatal closure, as well as in response to the drought‐stress hormone abscisic acid. Patch‐clamp studies on guard cell protoplasts isolated from atalmt12 mutants revealed reduced R‐type currents compared with wild‐type plants when malate is present in the bath media. Following expression of AtALMT12 in Xenopus oocytes, voltage‐dependent anion currents reminiscent to R‐type channels could be activated. In line with the features of the R‐type channel, the activity of heterologously expressed AtALMT12 depends on extracellular malate. Thereby this key metabolite and osmolite of guard cells shifts the threshold for voltage activation of AtALMT12 towards more hyperpolarized potentials. R‐Type channels, like voltage‐dependent cation channels in nerve cells, are capable of transiently depolarizing guard cells, and thus could trigger membrane potential oscillations, action potentials and initiate long‐term anion and K⁺ efflux via SLAC1 and GORK, respectively.     

Engineering greater aluminium resistance in wheat by over-expressing TaALMT1

MethodsParticle bombardment was used to transform wheat with TaALMT1, the Al³⁺ resistance gene from wheat, using the maize ubiquitin promoter to drive expression. TaALMT1 expression, malate efflux and Al³⁺ resistance were measured in the T₁ and T₂ lines and compared with the parental line and an Al³⁺-resistant reference genotype, ET8.ConclusionsThe Al³⁺ resistance of wheat was increased by enhancing TaALMT1 expression with biotechnology. This is the first report of a major food crop being stably transformed for greater Al³⁺ resistance. Transgenic strategies provide options for increasing food supply on acid soils.     

Enhanced exudation of malate in the rhizosphere due to AtALMT1 overexpression in blackgram (Vigna mungo L.) confers increased aluminium tolerance

• Worldwide, 50% of soil is acidic, which induces aluminium (Al) toxicity in plants, as the phyto‐availability of Al³⁺ increases in acidic soil. Plants responds to Al³⁺ toxicity by exuding organic acids into the rhizosphere. The organic acid responsible for Al³⁺ stress response varies from species to species, which in the case of blackgram (Vigna mungo L.) is citrate.
• In blackgram, an Arabidopsis malate transporter, AtALMT1, was overexpressed with the motive of inducing enhanced exudation of malate. Transgenics were generated using cotyledon node explants through Agrobacterium tumefaciens‐mediated transformation. The putative transgenics were initially screened by AtALMT1‐specific genomic DNA PCR, followed by quantitative PCR. Two independent transgenic events were identified and functionally characterized in the T₃ generation.
• The transgenic lines, Line 1 and 2, showed better root growth, relative water content and chlorophyll content under Al³⁺ stress. Both lines also accounted for less oxidative damage, due to reduced accumulation of ROS molecules. Photosynthetic efficiency, as measured in terms of F_v/F_m, NPQ and Y(II), increased when compared to the wild type (WT). Relative expression of genes (VmSTOP1, VmALS3, VmMATE) responsible for Al³⁺ stress response in blackgram showed that overexpression of a malate transporter did not have any effect on their expression. Malate exudation increased whereas citrate exudation did not show any divergence from the WT. A pot stress assay found that the transgenics showed better adaptation to acidic soil.
• This report demonstrates that the overexpression of a malate transporter in a non‐malate exuding species improves adaptation to Al³⁺ toxicity in acidic soil without effecting its stress response mechanism.

     

Crystal structure of Streptococcus pneumoniae Sp1610, a putative tRNA methyltransferase,in complex with S‐adenosyl‐L‐methionine

Streptococcus pneumoniae Sp1610, a Class‐I fold S‐adenosylmethionine (AdoMet)‐dependent methyltransferase, is a member of the COG2384 family in the Clusters of Orthologous Groups database, which catalyzes the methylation of N¹‐adenosine at position 22 of bacterial tRNA. We determined the crystal structure of Sp1610 in the ligand‐free and the AdoMet‐bound forms at resolutions of 2.0 and 3.0 Å, respectively. The protein is organized into two structural domains: the N‐terminal catalytic domain with a Class I AdoMet‐dependent methyltransferase fold, and the C‐terminal substrate recognition domain with a novel fold of four α‐helices. Observations of the electrostatic potential surface revealed that the concave surface located near the AdoMet binding pocket was predominantly positively charged, and thus this was predicted to be an RNA binding area. Based on the results of sequence alignment and structural analysis, the putative catalytic residues responsible for substrate recognition are also proposed.     

Senescence Retarding Effect of Metal Ions: Pigment and Protein Contents and Photochemical Activities of Detached Primary Leaves of Wheat

Al³⁺ significantly delayed the loss of chlorophyll (Chl), protein, and carotenoids when compared to K⁺ and Mg²⁺ during dark-induced senescence of detached primary leaves of Triticum aestivum. Thylakoid membranes isolated from Al³⁺ - treated leaves showed a better retention of photosystem (PS) 2, PS1, and whole chain electron transport activities than thylakoids of K⁺- or Mg²⁺-treated leaves. These ions protected the electron transport activities and restored the DCMU-dependent fluorescence increase of thylakoid membranes in a valency-dependent manner. Al³⁺ also delayed the change of excitation energy distribution during senescence.     

The tomato I gene for Fusarium wilt resistance encodes an atypical leucine‐rich repeat receptor‐like protein whose function is nevertheless dependent on SOBIR1 and SERK3/BAK1

We have identified the tomato I gene for resistance to the Fusarium wilt fungus Fusarium oxysporum f. sp. lycopersici (Fol) and show that it encodes a membrane‐anchored leucine‐rich repeat receptor‐like protein (LRR‐RLP). Unlike most other LRR‐RLP genes involved in plant defence, the I gene is not a member of a gene cluster and contains introns in its coding sequence. The I gene encodes a loopout domain larger than those in most other LRR‐RLPs, with a distinct composition rich in serine and threonine residues. The I protein also lacks a basic cytosolic domain. Instead, this domain is rich in aromatic residues that could form a second transmembrane domain. The I protein recognises the Fol Avr1 effector protein, but, unlike many other LRR‐RLPs, recognition specificity is determined in the C‐terminal half of the protein by polymorphic amino acid residues in the LRRs just preceding the loopout domain and in the loopout domain itself. Despite these differences, we show that I/Avr1‐dependent necrosis in Nicotiana benthamiana depends on the LRR receptor‐like kinases (RLKs) SERK3/BAK1 and SOBIR1. Sequence comparisons revealed that the I protein and other LRR‐RLPs involved in plant defence all carry residues in their last LRR and C‐terminal LRR capping domain that are conserved with SERK3/BAK1‐interacting residues in the same relative positions in the LRR‐RLKs BRI1 and PSKR1. Tyrosine mutations of two of these conserved residues, Q922 and T925, abolished I/Avr1‐dependent necrosis in N. benthamiana, consistent with similar mutations in BRI1 and PSKR1 preventing their interaction with SERK3/BAK1.     

Vacuolar malate uptake is mediated by an anion-selective inward rectifier

Electrophysiological studies using the patch‐clamp technique were performed on isolated vacuoles from leaf mesophyll cells of the crassulacean acid metabolism (CAM) plant Kalanchoë daigremontiana to characterize the malate transport system responsible for nocturnal malic acid accumulation. In the presence of malate on both sides of the membrane, the current–voltage relations of the tonoplast were dominated by a strongly inward‐rectifying anion‐selective channel that was active at cytoplasmic‐side negative voltages. Rectification of the macroscopic conductance was reflected in the voltage‐dependent gating of a 3‐pS malate‐selective ion channel, which showed a half‐maximal open probability at ?43 mV. Also, the time‐averaged unitary currents following a step to a negative voltage corresponded to the time‐dependent kinetics of the macroscopic currents, suggesting that the activity of this channel underlies the anion‐selective inward rectifier. The inward rectifier showed saturation kinetics with respect to malate (apparent K_m of 2.5 mm malate^2? activity), a selectivity sequence of fumarate^2? > malate^2? > Cl^? > maleate^2– ≈ citrate^3–, and greater activity at higher pH values (with an apparent pK of 7.1 and maximum activity at around pH 8.0). All these properties were in close agreement with the characteristics of malate transport observed in isolated tonoplast vesicles. Further, 100 µm niflumate reversibly blocked the activity of the 3‐pS channel and inhibited both macroscopic currents and malate transport into tonoplast vesicles to the same extent. The macroscopic current densities recorded at physiological voltages and the estimated channel density of 0.2 µm^?2 are sufficient to account for the observed rates of nocturnal malic acid accumulation in this CAM plant, suggesting that the 3‐pS, inward‐rectifying, anion‐selective channel represents the principal pathway for malate influx into the vacuole.     

Novel Ca2+‐independent carbohydrate recognition of the C‐type lectins,SPL‐1 and SPL‐2, from the bivalve Saxidomus purpuratus

Novel Ca²⁺‐independent C‐type lectins, SPL‐1 and SPL‐2, were purified from the bivalve Saxidomus purpuratus. They are composed of dimers with either identical (SPL‐2 composed of two B‐chains) or distinct (SPL‐1 composed of A‐ and B‐chains) polypeptide chains, and show affinity for N‐acetylglucosamine (GlcNAc)‐ and N‐acetylgalactosamine (GalNAc)‐containing carbohydrates, but not for glucose or galactose. A database search for sequence similarity suggested that they belong to the C‐type lectin family. X‐ray crystallographic analysis revealed definite structural similarities between their subunits and the carbohydrate‐recognition domain (CRD) of the C‐type lectin family. Nevertheless, these lectins (especially SPL‐2) showed Ca²⁺‐independent binding affinity for GlcNAc and GalNAc. The crystal structure of SPL‐2/GalNAc complex revealed that bound GalNAc was mainly recognized via its acetamido group through stacking interactions with Tyr and His residues and hydrogen bonds with Asp and Asn residues, while widely known carbohydrate‐recognition motifs among the C‐type CRD (the QPD [Gln‐Pro‐Asp] and EPN [Glu‐Pro‐Asn] sequences) are not involved in the binding of the carbohydrate. Carbohydrate‐binding specificities of individual A‐ and B‐chains were examined by glycan array analysis using recombinant lectins produced from Escherichia coli cells, where both subunits preferably bound oligosaccharides having terminal GlcNAc or GalNAc with α‐glycosidic linkages with slightly different specificities.     

Calcium‐ and potassium‐permeable plasma membrane transporters are activated by copper in Arabidopsis root tips: linking copper transport with cytosolic hydroxyl radical production

Transition metals such as copper can interact with ascorbate or hydrogen peroxide to form highly reactive hydroxyl radicals (OH^?), with numerous implications to membrane transport activity and cell metabolism. So far, such interaction was described for extracellular (apoplastic) space but not cytosol. Here, a range of advanced electrophysiological and imaging techniques were applied to Arabidopsis thaliana plants differing in their copper‐transport activity: Col‐0, high‐affinity copper transporter COPT1‐overexpressing (C1^OE) seedlings, and T‐DNA COPT1 insertion mutant (copt1). Low Cu concentrations (10 µm ) stimulated a dose‐dependent Gd³⁺ and verapamil sensitive net Ca²⁺ influx in the root apex but not in mature zone. C1^OE also showed a fivefold higher Cu‐induced K⁺ efflux at the root tip level compared with Col‐0, and a reduction in basal peroxide accumulation at the root tip after copper exposure. Copper caused membrane disruptions of the root apex in C1^OE seedlings but not in copt1 plants; this damage was prevented by pretreatment with Gd³⁺. Our results suggest that copper transport into cytosol in root apex results in hydroxyl radical generation at the cytosolic side, with a consequent regulation of plasma membrane OH^?‐sensitive Ca²⁺ and K⁺ transport systems.     

Structural and biochemical characterization of a metagenome‐derived esterase with a long N‐terminal extension

The genes encoding six novel esterolytic/lipolytic enzymes, termed LC‐Est1～6, were isolated from a fosmid library of a leaf‐branch compost metagenome by functional screening using tributyrin agar plates. These enzymes greatly vary in size and amino acid sequence. The highest identity between the amino acid sequence of each enzyme and that available from the database varies from 44 to 73%. Of these metagenome‐derived enzymes, LC‐Est1 is characterized by the presence of a long N‐terminal extension (LNTE, residues 26–283) between a putative signal peptide (residues 1–25) and a C‐terminal esterase domain (residues 284–510). A putative esterase from Candidatus Solibacter usitatus (CSu‐Est) is the only protein, which shows the significant amino acid sequence identity (46%) to the entire region of LC‐Est1. To examine whether LC‐Est1 exhibits activity and its LNTE is important for activity and stability of the esterase domain, LC‐Est1 (residues 26–510), LC‐Est1C (residues 284–510), and LC‐Est1C* (residues 304–510) were overproduced in E. coli, purified, and characterized. LC‐Est1C* was only used for structural analysis. The crystal structure of LC‐Est1C* highly resembles that of the catalytic domain of Thermotoga maritima esterase, suggesting that LNTE is not required for folding of the esterase domain. The enzymatic activity of LC‐Est1C was lower than that of LC‐Est1 by 60%, although its substrate specificity was similar to that of LC‐Est1. LC‐Est1C was less stable than LC‐Est1 by 3.3°C. These results suggest that LNTE of LC‐Est1 rather exists as an independent domain but is required for maximal activity and stability of the esterase domain.     

Novel properties of the wheat aluminum tolerance organic acid transporter (TaALMT1) revealed by electrophysiological characterization in Xenopus Oocytes: functional and structural implications

Many plant species avoid the phytotoxic effects of aluminum (Al) by exuding dicarboxylic and tricarboxylic acids that chelate and immobilize Al(3+) at the root surface, thus preventing it from entering root cells. Several novel genes that encode membrane transporters from the ALMT and MATE families recently were cloned and implicated in mediating the organic acid transport underlying this Al tolerance response. Given our limited understanding of the functional properties of ALMTs, in this study a detailed characterization of the transport properties of TaALMT1 (formerly named ALMT1) from wheat (Triticum aestivum) expressed in Xenopus laevis oocytes was conducted. The electrophysiological findings are as follows. Although the activity of TaALMT1 is highly dependent on the presence of extracellular Al(3+) (K(m1/2) of approximately 5 microm Al(3+) activity), TaALMT1 is functionally active and can mediate ion transport in the absence of extracellular Al(3+). The lack of change in the reversal potential (E(rev)) upon exposure to Al(3+) suggests that the "enhancement" of TaALMT1 malate transport by Al is not due to alteration in the transporter's selectivity properties but is solely due to increases in its anion permeability. The consistent shift in the direction of the E(rev) as the intracellular malate activity increases indicates that TaALMT1 is selective for the transport of malate over other anions. The estimated permeability ratio between malate and chloride varied between 1 and 30. However, the complex behavior of the E(rev) as the extracellular Cl(-) activity was varied indicates that this estimate can only be used as a general guide to understanding the relative affinity of TaALMT1 for malate, representing only an approximation of those expected under physiologically relevant ionic conditions. TaALMT1 can also mediate a large anion influx (i.e. outward currents). TaALMT1 is permeable not only to malate but also to other physiologically relevant anions such as Cl(-), NO(3)(-), and SO(4)(2-) (to a lesser degree).     

Vitronectin binds to the head region of Moraxella catarrhalis ubiquitous surface protein A2 and confers complement‐inhibitory activity

The serum resistance of the common respiratory pathogen Moraxella catarrhalis is mainly dependent on ubiquitous surface proteins (Usp) A1 and A2 that interact with complement factor 3 (C3) and complement inhibitor C4b binding protein (C4BP) preventing the alternative and classical pathways of the complement system respectively. UspA2 also has the capacity to attract vitronectin that in turn binds C9 and hereby inhibits membrane attack complex (MAC) formation. We found UspA2 as a major vitronectin binding protein and hence the UspA2/vitronectin interaction was studied in detail. The affinity constant (K_D) for vitronectin binding to UspA2 was 2.3 × 10^?8 M, and the N‐terminal region encompassing residues UspA2 30–170 bound vitronectin with a K_D of 7.9 × 10^?8 M. Electron microscopy verified that the active binding domain (UspA2^30–177) was located at the head region of UspA2. Experiments with recombinantly expressed vitronectin also revealed that UspA2^30–177 bound to the C‐terminal region of vitronectin residues 312–396. Finally, when human serum was pre‐incubated with UspA2, bacteria showed significantly less serum resistance. Our study directly reveals the binding mode between the N‐terminal domain of UspA2 and the C‐terminal part of vitronectin and thus sheds light upon the mechanism of M. catarrhalis‐dependent serum resistance.     

Structural and functional analysis of the phosphoryl transfer reaction mediated by the human small C‐terminal domain phosphatase,Scp1

Human small C‐terminal domain phosphatase 1 (Scp1) modulates the phosphorylation state of the C‐terminal domain (CTD) of eukaryotic RNA polymerase II (RNAP II), with preference for phosphorylated Ser5 in the tandem heptad repeats of the CTD. Additionally, Scp1 was identified as a conserved regulator of neuronal stem cell development. Scp1 is a member of haloacid dehalogenase (HAD) superfamily, whose catalysis depends on a Mg²⁺ ion and a DXDX(T/V) motif. The first Asp of the motif is identified as the nucleophile that is subject to phosphorylation leading to a phosphoryl‐aspartate intermediate. This high‐energy mixed anhydride intermediate is subsequently hydrolyzed to regenerate the enzyme. In the present study, we successfully captured the phosphoryl‐aspartate intermediate in the crystal structure of a Scp1D206A mutant soaked with para‐nitrophenyl phosphate (pNPP), providing strong evidence for the proposed mechanism. Furthermore, steady‐state kinetic analysis of a variety of Scp1 mutants revealed the importance of Asp206 in Mg²⁺ coordination mediated by a water molecule. Overall, we captured the snapshots of the phosphoryl transfer reaction at each stage of Scp1‐mediated catalysis. Through structural‐based sequence alignment, we show that the spatial position of the D206 side chain is strictly conserved throughout HAD family. Our results strongly suggest that Asp206 and its equivalent residues in other HAD family members play important structural and possible mechanistic roles.