A molecular toolkit for the green seaweed Ulva mutabilis

The green seaweed Ulva mutabilis is an ecologically important marine primary producer as well as a promising cash crop cultivated for multiple uses. Despite its importance, several molecular tools are still needed to better understand seaweed biology. Here, we report the development of a flexible and modular molecular cloning toolkit for the green seaweed U. mutabilis based on a Golden Gate cloning system. The toolkit presently contains 125 entry vectors, 26 destination vectors, and 107 functionally validated expression vectors. We demonstrate the importance of endogenous regulatory sequences for transgene expression and characterize three endogenous promoters suitable to drive transgene expression. We describe two vector architectures to express transgenes via two expression cassettes or a bicistronic approach. The majority of selected transformants (50%–80%) consistently give clear visual transgene expression. Furthermore, we made different marker lines for intracellular compartments after evaluating 13 transit peptides and 11 tagged endogenous Ulva genes. Our molecular toolkit enables the study of Ulva gain-of-function lines and paves the way for gene characterization and large-scale functional genomics studies in a green seaweed.

Molecular cloning tools allow generating gain-of-function seaweed lines that will help to study seaweed biology.     

Potassium Translocation into the Root Xylem

Abstract: Potassium is the most abundant cation in cells of higher plants and plays vital roles in plant growth and develop ment. Since the soil is the only source of potassium, plant roots are well adapted to exploit the soil for potassium and supply it to the leaves. Transport across the root can be divided into three stages: uptake into the root symplast, transport across the symplast and release into the xylem. Uptake kinetics of potassium have been studied extensively in the past and sug gested the presence of high and low affinity systems. Molecular and electrophysiological techniques have now confirmed the existence of discrete transporters encoded by a number of genes. Surprisingly, detailed characterisation of the transpor ters using reverse genetics and heterologous expression shows that a number of the transporters (AKT and AtKUP family) func tion both in the low (μM) and high (mM) K⁺ range. Electrophy siological studies indicate that K⁺ uptake by roots is coupled to H⁺, to drive uptake from micromolar K⁺. However, thus far only Na⁺ coupled K⁺ transport has been demonstrated (HKT1). Ion channels play a major role in the exchange of potassium be tween the symplast and the xylem. An outward rectifying chan nel (KORC) mediates potassium release. Cloning of the gene en coding this channel (SKOR) shows that it belongs to the Shaker super-family. Both electrophysiological and genetic studies demonstrate that K⁺ release through this channel is controlled by the stress hormone abscisic acid. Interestingly, xylem par enchyma cells of young barley roots also contain a number of in ward rectifying K⁺ channels that are controlled by G-proteins. The involvement of G-proteins emphasises once more that po tassium transport at the symplast/xylem boundary is under hor monal control. The role of the electrical potential difference across the symplastxylem boundary in controlling potassium release is discussed.     

Generation and characterization of transgenic zebrafish lines using different ubiquitous promoters

Two commonly used promoters to ubiquitously express transgenes in zebrafish are the Xenopus laevis elongation factor 1 α promoter (XlEef1a1) and the zebrafish histone variant H2A.F/Z (h2afv) promoter. Recently, transgenes utilizing these promoters were shown to be silenced in certain adult tissues, particularly the central nervous system. To overcome this limitation, we cloned the promoters of four zebrafish genes that likely are transcribed ubiquitously throughout development and into the adult. These four genes are the TATA box binding protein gene, the taube nuss-like gene, the eukaryotic elongation factor 1-gamma gene, and the beta-actin-1 gene. We PCR amplified approximately 2.5 kb upstream of the putative translational start site of each gene and cloned each into a Tol2 expression vector that contains the EGFP reporter transgene. We used these four Tol2 vectors to independently generate stable transgenic fish lines for analysis of transgene expression during development and in the adult. We demonstrated that all four promoters drive a very broad pattern of EGFP expression throughout development and the adult. Using the retina as a well-characterized component of the CNS, all four promoters appeared to drive EGFP expression in all neuronal and non-neuronal cells of the adult retina. In contrast, the h2afv promoter failed to express EGFP in the adult retina. When we examined EGFP expression in the various cells of the blood cell lineage, we observed that all four promoters exhibited a more heterogenous expression pattern than either the XlEef1a1 or h2afv promoters. While these four ubiquitous promoters did not express EGFP in all the adult blood cells, they did express EGFP throughout the CNS and in broader expression patterns in the adult than either the XlEef1a1 or h2afv promoters. For these reasons, these four promoters will be valuable tools for expressing transgenes in adult zebrafish.     

Efficient expression of a promoter-controlled gene: Tandem promoters of lambda PR and PL functional in enteric bacteria

We describe an expression vector that functions in enteric bacteria. The vector contains the coliphage λ promoters P_R and P_L and entire P_R and P_L operators in tandem upstream from the multiple cloning sites containing the kanamycin-resistant gene. The vector also specifies a ribosome binding site and a thermolabile repressor, cI₈₅₇, and the P_RM promoter. These promoters as well as lacUV5 and trp promoters were inserted into the EcoRI site of pKO-1 plasmid so that they drove the expression of a reporter gene, galactokinase (galK). The P_RP_L promoter showed the highest efficiency of galK expression in the Escherichia coli strain K12ΔH1Δtrp; it was strong in Klebsiella aerogenes, and weak in Serratia marcescens and Citrobacter freundii.     

Improved Salinity Tolerance of Rice Through Cell Type-Specific Expression of AtHKT1;1

Previously, cell type-specific expression of AtHKT1;1, a sodium transporter, improved sodium (Na⁺) exclusion and salinity tolerance in Arabidopsis. In the current work, AtHKT1;1, was expressed specifically in the root cortical and epidermal cells of an Arabidopsis GAL4-GFP enhancer trap line. These transgenic plants were found to have significantly improved Na⁺ exclusion under conditions of salinity stress. The feasibility of a similar biotechnological approach in crop plants was explored using a GAL4-GFP enhancer trap rice line to drive expression of AtHKT1;1 specifically in the root cortex. Compared with the background GAL4-GFP line, the rice plants expressing AtHKT1;1 had a higher fresh weight under salinity stress, which was related to a lower concentration of Na⁺ in the shoots. The root-to-shoot transport of ²²Na⁺ was also decreased and was correlated with an upregulation of OsHKT1;5, the native transporter responsible for Na⁺ retrieval from the transpiration stream. Interestingly, in the transgenic Arabidopsis plants overexpressing AtHKT1;1 in the cortex and epidermis, the native AtHKT1;1 gene responsible for Na⁺ retrieval from the transpiration stream, was also upregulated. Extra Na⁺ retrieved from the xylem was stored in the outer root cells and was correlated with a significant increase in expression of the vacuolar pyrophosphatases (in Arabidopsis and rice) the activity of which would be necessary to move the additional stored Na⁺ into the vacuoles of these cells. This work presents an important step in the development of abiotic stress tolerance in crop plants via targeted changes in mineral transport.     

Construction of two Gateway vectors for gene expression in fungi

We report the construction of two Gateway fungal expression vectors pCBGW and pGWBF. The pCBGW was generated by introducing an expression cassette, which consists of a Gateway recombinant cassette (attR1-Cmr-ccdB-attR2) under the control of fungal promoter PgpdA and a terminator TtrpC, into the multiple cloning site of fungal vector pCB1004. The pGWBF is a binary vector, which was generated from the plant expression vector pGWB2 by replacing the CaMV35S promoter with PgpdA. The pGWBF can be transformed into fungi efficiently with Agrobacterium-mediated transformation. The applicability of two newly constructed vectors was tested by generating the destination vectors pGWBF-GFP and pCBGW-GFP and examining the expression of GFP gene in Trichoderma viride and Gibberella fujikuroi, respectively. Combining with the advantage of Gateway cloning technology, pCBGW and pGWBF will be useful in fungi for large-scale investigation of gene functions by constructing the interested gene destination/expression vectors in a high-throughput way.     

AtHKT1;1 mediates nernstian sodium channel transport properties in Arabidopsis root stelar cells

The Arabidopsis AtHKT1;1 protein was identified as a sodium (Na⁺) transporter by heterologous expression in Xenopus laevis oocytes and Saccharomyces cerevisiae. However, direct comparative in vivo electrophysiological analyses of a plant HKT transporter in wild-type and hkt loss-of-function mutants has not yet been reported and it has been recently argued that heterologous expression systems may alter properties of plant transporters, including HKT transporters. In this report, we analyze several key functions of AtHKT1;1-mediated ion currents in their native root stelar cells, including Na⁺ and K⁺ conductances, AtHKT1;1-mediated outward currents, and shifts in reversal potentials in the presence of defined intracellular and extracellular salt concentrations. Enhancer trap Arabidopsis plants with GFP-labeled root stelar cells were used to investigate AtHKT1;1-dependent ion transport properties using patch clamp electrophysiology in wild-type and athkt1;1 mutant plants. AtHKT1;1-dependent currents were carried by sodium ions and these currents were not observed in athkt1;1 mutant stelar cells. However, K⁺ currents in wild-type and athkt1;1 root stelar cell protoplasts were indistinguishable correlating with the Na⁺ over K⁺ selectivity of AtHKT1;1-mediated transport. Moreover, AtHKT1;1-mediated currents did not show a strong voltage dependence in vivo. Unexpectedly, removal of extracellular Na⁺ caused a reduction in AtHKT1;1-mediated outward currents in Columbia root stelar cells and Xenopus oocytes, indicating a role for external Na⁺ in regulation of AtHKT1;1 activity. Shifting the NaCl gradient in root stelar cells showed a Nernstian shift in the reversal potential providing biophysical evidence for the model that AtHKT1;1 mediates passive Na⁺ channel transport properties.     

Plant tissue-specific promoters can drive gene expression in Escherichia coli

Plant transgenesis often requires the use of tissue-specific promoters to drive the transgene expression exclusively in targeted tissues. Although the eukaryotic promoters are expected to stay silent in Escherichia coli, when the promoter-transgene units within the plant transformation vectors are constructed and propagated, some eukaryotic promoters have been reported to be active in prokaryotes. The potential activity of plant promoter in E. coli cells should be considered in cases of expression of proteins that are toxic for host cells, environmental risk assessment or the stability in E. coli of plant vectors for specific Cre/loxP applications. In this study, DNA fragments harbouring four embryo- and/or pollen-specific Arabidopsis thaliana promoters were investigated for their ability to drive heterologous gene expression in E. coli cells. For this, they were fused to gfp:gus reporter genes in the pCAMBIA1304 vector. Although BPROM, bacterial sigma70 promoter recognition program identified several sequences with characteristics similar to bacterial promoters including -10 and -35 sequences in each of tested fragments, the experimental approach showed that only one promoter fragment was able to drive relatively strong- and one promoter fragment relatively weak-GUS expression in E. coli cells. Remaining two tested promoters did not drive any transgene expression in bacteria. Our results also showed that cloning of a shorter plant promoter sequence into vectors containing lacZ α-complementation system can increase the probability of gene expression driven by upstream located lac promoter. This should be considered when cloning of plant expression units, the expression of which is unwanted in E. coli.     

Development of a novel Gateway-based vector system for efficient, multiparallel protein expression in Escherichia coli

We describe a cloning and expression system which is based on the Escherichia coli T7 expression system and Gateway recombination technology. We have produced numerous destination vectors with selected fusion tags and an additional set of entry vectors containing the gene of interest and optional labeling tags. This powerful system enables us to transfer a cDNA to several expression vectors in parallel and combine them with various labeling tags. To remove the attached amino terminal tags along with the unwanted attB1 site, we inserted PreScission protease cleavage sites. In contrast to the commercially available destination vectors, our plasmids provide kanamycin resistance, which can be an advantage when expressing toxic proteins in E. coli. Some small-scale protein expression experiments are shown to demonstrate the usefulness of these novel Gateway vectors. In summary, this system has some benefits over the widely used and commercially available Gateway standard system, and it enables many different combinations for expression constructs from a single gene of interest.     

An improved,versatile and efficient modular plasmid assembly system for expression analyses of genes in Xanthomonas oryzae

Xanthomonas oryzae pathovars oryzae (Xoo) and oryzicola (Xoc) infect rice, causing bacterial blight and bacterial leaf streak, respectively, which are two economically important bacterial diseases in paddy fields. The interactions of Xoo and Xoc with rice can be used as models for studying fundamental aspects of bacterial pathogenesis and host tissue specificity. However, an improved vector system for gene expression analysis is desired for Xoo and Xoc because some broad host range vectors that can replicate stably in X. oryzae pathovars are low-copy number plasmids. To overcome this limitation, we developed a modular plasmid assembly system to transfer the functional DNA modules from the entry vectors into the pHM1-derived backbone vectors on a high-copy number basis. We demonstrated the feasibility of our vector system for protein detection, and quantification of virulence gene expression under laboratory conditions and in association with host rice and nonhost tobacco cells. This system also allows execution of a mutant complementation equivalent to the single-copy chromosomal integration system and tracing of pathogens in rice leaf. Based on this assembly system, we constructed a series of protein expression and promoter-probe vectors suitable for classical double restriction enzyme cloning. These vector systems enable cloning of all genes or promoters of interest from Xoo and Xoc strains. Our modular assembly system represents a versatile and highly efficient toolkit for gene expression analysis that will accelerate studies on interactions of X. oryzae with rice.     

A Modified MultiSite Gateway Cloning Strategy for Consolidation of Genes in Plants

The genome information is offering opportunities to manipulate genes, polygenic characters and multiple traits in plants. Although a number of approaches have been developed to manipulate traits in plants, technical hurdles make the process difficult. Gene cloning vectors that facilitate the fusion, overexpression or down regulation of genes in plant cells are being used with various degree of success. In this study, we modified gateway MultiSite cloning vectors and developed a hybrid cloning strategy which combines advantages of both traditional cloning and gateway recombination cloning. We developed Gateway entry (pGATE) vectors containing attL sites flanking multiple cloning sites and plant expression vector (pKM12GW) with specific recombination sites carrying different plant and bacterial selection markers. We constructed a plant expression vector carrying a reporter gene (GUS), two Bt cry genes in a predetermined pattern by a single round of LR recombination reaction after restriction endonuclease-mediated cloning of target genes into pGATE vectors. All the three transgenes were co-expressed in Arabidopsis as evidenced by gene expression, histochemical assay and insect bioassay. The pGATE vectors can be used as simple cloning vectors as there are rare restriction endonuclease sites inserted in the vector. The modified multisite vector system developed is ideal for stacking genes and pathway engineering in plants.     

pORE: a modular binary vector series suited for both monocot and dicot plant transformation

We present a series of 14 binary vectors suitable for Agrobacterium-mediated transformation of dicotyledonous plants and adaptable for biolistic transformation of monocotyledonous plants. The vector size has been minimized by eliminating all non-essential elements from the vector backbone and T-DNA regions while maintaining the ability to replicate independently. The smallest of the vector series is 6.3 kb and possesses an extensive multiple cloning site with 21 unique restriction endonuclease sites that are compatible with common cloning, protein expression, yeast two-hybrid and other binary vectors. The T-DNA region was engineered using a synthetic designer oligonucleotide resulting in an entirely modular system whereby any vector element can be independently exchanged. The high copy number ColE1 origin of replication has been included to enhance plasmid yield in Escherichia coli. FRT recombination sites flank the selectable marker cassette regions and allow for in planta excision by FLP recombinase. The pORE series consists of three basic types; an ‘open’ set for general plant transformation, a ‘reporter’ set for promoter analysis and an ‘expression’ set for constitutive expression of transgenes. The sets comprise various combinations of promoters (P _HPL, P _ENTCUP2 and P _TAPADH), selectable markers (nptII and pat) and reporter genes (gusA and smgfp).     

Calnexin co-expression and the use of weaker promoters increase the expression of correctly assembled Shaker potassium channel in insect cells

Voltage-gated potassium channels control the membrane potential of excitable cells. To understand their function, knowledge of their structure is essential. However, these channels are scarce in natural sources, and overexpression is necessary to generate material for structural studies. We have compared functional expression of the Drosophila Shaker H4 potassium channel in stable insect cell lines and in baculovirus-infected insect cells, using three different baculovirus promoters. Stable insect cell lines expressed correctly assembled channel, which was glycosylated and found predominantly at, or close to, the cell surface. In comparison, the majority of baculovirus-overexpressed Shaker was intracellular and incorrectly assembled. The proportion of functional Shaker increased, however, if the weaker basic protein promoter was used rather than the stronger p10 or polyhedrin promoters. In addition, co-expression of the molecular chaperone, calnexin, increased the quantity of correctly assembled channel protein, suggesting that calnexin can be used to increase the efficiency of channel expression in insect cells.     

The Arabidopsis HKT1 Gene Homolog Mediates Inward Na+ Currents in Xenopus laevis Oocytes and Na+ Uptake in Saccharomyces cerevisiae

The Na⁺-K⁺ co-transporter HKT1, first isolated from wheat, mediates high-affinity K⁺ uptake. The function of HKT1 in plants, however, remains to be elucidated, and the isolation of HKT1 homologs from Arabidopsis would further studies of the roles of HKT1 genes in plants. We report here the isolation of a cDNA homologous to HKT1 from Arabidopsis (AtHKT1) and the characterization of its mode of ion transport in heterologous systems. The deduced amino acid sequence of AtHKT1 is 41% identical to that of HKT1, and the hydropathy profiles are very similar. AtHKT1 is expressed in roots and, to a lesser extent, in other tissues. Interestingly, we found that the ion transport properties of AtHKT1 are significantly different from the wheat counterpart. As detected by electrophysiological measurements, AtHKT1 functioned as a selective Na⁺ uptake transporter in Xenopus laevis oocytes, and the presence of external K⁺ did not affect the AtHKT1-mediated ion conductance (unlike that of HKT1). When expressed in Saccharomyces cerevisiae, AtHKT1 inhibited growth of the yeast in a medium containing high levels of Na⁺, which correlates to the large inward Na⁺ currents found in the oocytes. Furthermore, in contrast to HKT1, AtHKT1 did not complement the growth of yeast cells deficient in K⁺ uptake when cultured in K⁺-limiting medium. However, expression of AtHKT1 did rescue Escherichia coli mutants carrying deletions in K⁺ transporters. The rescue was associated with a less than 2-fold stimulation of K⁺ uptake into K⁺-depleted cells. These data demonstrate that AtHKT1 differs in its transport properties from the wheat HKT1, and that AtHKT1 can mediate Na⁺ and, to a small degree, K⁺ transport in heterologous expression systems.     

A convenient set of vectors for expression of multiple gene combinations in plants

A set of vectors has been developed that simplify shuttling expression cassettes between small plasmids of high copy number ideal for experiments involving biolistic transient expression and a binary transformation plasmid. Three cassettes for the expression of a cloned coding sequence behind different promoters have been modified; combinations of these cassettes can be excised withNot I, and sequentially cloned into the transformation vector in a procedure that removes the first cloning site. The system is demonstrated by inducing anthocyanin synthesis with paired regulatory genes of maize biolistically delivered to a maize cell suspension, and then expressed in transformed tobacco.     

Development of a Versatile Expression Plasmid Construction System for Aspergillus oryzae and Its Application to Visualization of Mitochondria

We report here a development of the MultiSite Gateway^TM-based versatile plasmid construction system applicable for the rapid and efficient preparation of Aspergillus oryzae expression plasmids. This system allows the simultaneous connection of the three DNA fragments inserted in entry clones along with a destination vector in a defined order and orientation. We prepared a variety of entry clones and destination vectors containing promoters, genes encoding carrier-proteins and fusion tags, and selectable markers, which makes it possible to generate 80 expression plasmids for each target protein. Using this system, plasmids for expression of the EGFP fused with the mitochondrial-targeting signal of citrate synthase (AoCit1) were generated. Tubular structures of mitochondria were visualized in the transformants expressing the AoCit1-EGFP fusion protein. This plasmid construction system allows us to prepare a large number of expression plasmids without laborious DNA manipulations, which would facilitate molecular biological studies on A. oryzae.     

Heteromeric AtKC1��AKT1 Channels in Arabidopsis Roots Facilitate Growth under K+-limiting Conditions

Plant growth and development is driven by osmotic processes. Potassium represents the major osmotically active cation in plants cells. The uptake of this inorganic osmolyte from the soil in Arabidopsis involves a root K⁺ uptake module consisting of the two K⁺ channel α-subunits, AKT1 and AtKC1. AKT1-mediated potassium absorption from K⁺-depleted soil was shown to depend on the calcium-sensing proteins CBL1/9 and their interacting kinase CIPK23. Here we show that upon activation by the CBL·CIPK complex in low external potassium homomeric AKT1 channels open at voltages positive of E_K, a condition resulting in cellular K⁺ leakage. Although at submillimolar external potassium an intrinsic K⁺ sensor reduces AKT1 channel cord conductance, loss of cytosolic potassium is not completely abolished under these conditions. Depending on channel activity and the actual potassium gradients, this channel-mediated K⁺ loss results in impaired plant growth in the atkc1 mutant. Incorporation of the AtKC1 subunit into the channel complex, however, modulates the properties of the K⁺ uptake module to prevent K⁺ loss. Upon assembly of AKT1 and AtKC1, the activation threshold of the root inward rectifier voltage gate is shifted negative by approximately −70 mV. Additionally, the channel conductance gains a hypersensitive K⁺ dependence. Together, these two processes appear to represent a safety strategy preventing K⁺ loss through the uptake channels under physiological conditions. Similar growth retardation phenotypes of akt1 and atkc1 loss-of-function mutants in response to limiting K⁺ supply further support such functional interdependence of AKT1 and AtKC1. Taken together, these findings suggest an essential role of AtKC1-like subunits for root K⁺ uptake and K⁺ homeostasis when plants experience conditions of K⁺ limitation.Fundamental plant functions such as control of the membrane potential, osmo-regulation, and turgor-driven growth and movements are based on the availability to gain high cellular potassium concentrations (1). The absorption of this inorganic osmolyte from the soil by the root therefore represents a pivotal process for plant life. Classical experiments by Epstein et al. in 1963 (2) described K⁺ root uptake as a biphasic process mediated by two uptake mechanisms: high affinity potassium transport with apparent affinities of ∼20 μm and a low affinity transport system with K_m values in the millimolar range. During the last decades several molecular components of potassium transport systems have been identified and functionally characterized in plants (3, 4). Mutant analyses, heterologous expression, as well as radiotracer uptake experiments characterized the K⁺ channels AKT1·AtKC1 and members of the HAK·KT·KUP family as major components of the Arabidopsis thaliana root-localized potassium transport system (5–9). In this study we focused on AKT1 and AtKC1, members of the Arabidopsis Shaker-like K⁺ channel family. AKT1 is a voltage-dependent inward-rectifying K⁺ channel mediating potassium uptake over a wide range of external potassium concentrations (10–15). Root cells of the akt1-1 loss-of-function mutant completely lack inward rectifying K⁺ currents (12). As a consequence the growth of akt1-1 seedlings is strongly impaired on low potassium medium (100 μm and less) (11, 12, 15). Rescue of yeast growth on 20 μm K⁺ and patch clamp experiments (16, 17) directly demonstrated that plant inward rectifying K⁺ channels are capable of serving as high affinity potassium uptake transporters. AtKC1 shares its expression pattern with AKT1 (18–20). AtKC1 α-subunits, however, neither form functional channels in akt1-1 knock-out plants nor in heterologous expression systems. In contrast to root cells of akt1-1 loss of function mutants, root protoplasts of AtKC1 null mutants (atkc1-f) still exhibit inward rectifying potassium currents most likely derived from homomeric AKT1 tetramers (20). Inward K⁺ currents in this atkc1-f mutant were characterized by a more positive activation voltage. These data suggested that the AtKC1 α-subunits do not form K⁺ channels per se but modulate the properties of the AKT1·AtKC1 heterocomplex (20–22). Previously, two groups in their ground-breaking studies demonstrated that AKT1 is activated by the CBL²-interacting, serine/threonine kinase, CIPK23, particularly under low K⁺ conditions (23, 24). CIPK23 itself was shown to be activated by the two calcineurin B-like proteins, CBL1 and 9, acting in a Ca²⁺-dependent manner upstream of CIPK23 (25, 26). Genetic disruption of these elements resulted in transgenic plants exhibiting a phenotype comparable with that of the AKT1 loss of function mutant. This regulatory system, based on a calcium sensor, a protein kinase, and a K⁺ channel, was functionally reconstituted in Xenopus oocytes (23, 24, 27), suggesting that these elements are essential and sufficient to operate as a low K⁺-sensitive potassium uptake system. Here we report on the physiological properties of the heteromeric K⁺ uptake module formed by the predominant root potassium uptake channel subunits, AKT1 and AtKC1 and its regulating kinase complex, CBL1 and CIPK23. Our studies show that the physical interaction of the CBL1·CIPK23 complex is specific for AKT1 channels and does not involve the AtKC1 subunit. AKT1 possesses a K⁺ (absence) sensor affecting channel activity at submillimolar K⁺ concentrations by strongly reducing its maximal cord conductance. Despite this K⁺ sensor, upon activation, AKT1 homomeric channels were shown to represent a potassium leak at low external potassium concentrations. Integration of AtKC1 into the K⁺ uptake module, however, prevented potassium loss by modulating both the voltage sensor and conductance in the channel complex. Moreover, activation of the AKT1-like maize channel ZMK1 by CBL1·CIPK23 suggests a conserved interaction and regulation across monocot and dicotyledonous plant species. Our biophysical studies as well as growth assays with plant mutant lines lacking the respective channels underline that acquisition of potassium under limiting K⁺ conditions is mediated via the root AKT1·AtKC1 K⁺ uptake channel complex.     

Coordination of AtHKT1;1 and AtSOS1 facilitates Na+ and K+ homeostasis in Arabidopsis thaliana under salt stress

Reducing Na⁺ accumulation and maintaining K⁺ stability in plant is one of the key strategies for improving salt tolerance. AtHKT1;1 and AtSOS1 are not only the salt tolerance determinants themselves, but also mediate K⁺ uptake and transport indirectly. To assess the contribution of AtHKT1;1 and AtSOS1 to Na⁺ homeostasis and K⁺ nutrition in plant, net Na⁺ and K⁺ uptake rate, Na⁺ and K⁺ distributions in Arabidopsis thaliana wild type (WT), hkt1;1 mutant (athkt1;1) and sos1 mutant (atsos1) were investigated. Results showed that under 2.5 mM K⁺ plus 25 or 100 mM NaCl, athkt1;1 shoot concurrently accumulated more Na⁺ and less K⁺ than did WT shoot, suggesting that AtHKT1;1 was critical for controlling Na⁺ and K⁺ distribution in plant; while atsos1 root accumulated more Na⁺ and absorbed lower K⁺ than did WT root, implying that AtSOS1 was determiner of Na⁺ excretion and K⁺ acquisition. Under 0.01 mM K⁺, athkt1;1 absorbed lower Na⁺ than did WT with 100 mM NaCl, suggesting that AtHKT1;1 is involved in Na⁺ uptake in roots; while atsos1 shoot accumulated less Na⁺ than did WT shoot no matter with 25 or 100 mM NaCl, implying that AtSOS1 played a key role in controlling long-distance Na⁺ transport from root to shoot. We present a model in which coordination of AtHKT1;1 and AtSOS1 facilitates Na⁺ and K⁺ homeostasis in A. thaliana under salt stress: under the normal K⁺, the major function of AtHKT1;1 is Na⁺ unloading and AtSOS1 is mainly involved in Na⁺ exclusion, whereas under the low K⁺, AtHKT1;1 may play a dominant role in Na+ uptake and AtSOS1 may be mainly involved in Na⁺ loading into the xylem.