In Planta Assessment of the Role of Thioredoxin h Proteins in the Regulation of S-Locus Receptor Kinase Signaling in Transgenic Arabidopsis

The self-incompatibility (SI) response of the Brassicaceae is mediated by allele-specific interaction between the stigma-localized S-locus receptor kinase (SRK) and its ligand, the pollen coat-localized S-locus cysteine-rich protein (SCR). Based on work in Brassica spp., the thioredoxin h-like proteins THL1 and THL2, which interact with SRK, have been proposed to function as oxidoreductases that negatively regulate SRK catalytic activity. By preventing the spontaneous activation of SRK in the absence of SCR ligand, these thioredoxins are thought to be essential for the success of cross pollinations in self-incompatible plants. However, the in planta role of thioredoxins in the regulation of SI signaling has not been conclusively demonstrated. Here, we addressed this issue using Arabidopsis thaliana plants transformed with the SRKb-SCRb gene pair isolated from self-incompatible Arabidopsis lyrata. These plants express an intense SI response, allowing us to exploit the extensive tools and resources available in A. thaliana for analysis of SI signaling. To test the hypothesis that SRK is redox regulated by thioredoxin h, we expressed a mutant form of SRKb lacking a transmembrane-localized cysteine residue thought to be essential for the SRK-thioredoxin h interaction. We also analyzed transfer DNA insertion mutants in the A. thaliana orthologs of THL1 and THL2. In neither case did we observe an effect on the pollination responses of SRKb-expressing stigmas toward incompatible or compatible pollen. Our results are consistent with the conclusion that, contrary to their proposed role, thioredoxin h proteins are not required to prevent the spontaneous activation of SRK in the A. thaliana stigma.Many flowering plants possess self-incompatibility (SI), a genetic system that promotes outcrossing by preventing self-fertilization. In the Brassicaceae family, the SI response is controlled by haplotypes of the S locus, each of which contains two genes that encode highly polymorphic proteins, the S-locus receptor kinase (SRK), which is a plasma membrane resident single-pass transmembrane Ser/Thr receptor kinase displayed at the surface of stigma epidermal cells (Stein et al., 1991; Takasaki et al., 2000), and the S-locus Cys-rich protein (SCR), which is the pollen coat-localized ligand for SRK (Schopfer et al., 1999; Kachroo et al., 2001; Takayama et al., 2001). SRK and SCR exhibit allele-specific interactions, whereby only SRK and SCR encoded by the same S-locus haplotype interact. In a self-pollination, the binding of this “self” pollen-borne SCR to the extracellular domain of SRK activates the SRK kinase, thereby triggering a cellular response in stigma epidermal cells that causes inhibition of pollen germination and tube penetration into the stigma epidermal cell wall (for review, see Tantikanjana et al., 2010).Tight regulation of SRK kinase activity and its signaling cascade is critical for productive pollen-stigma interactions because constitutive (i.e. SCR-independent) activity of the receptor is expected to result in sterile stigmas that reject both compatible and incompatible pollen. In the classical view of ligand-activated receptor kinases, the receptor occurs as catalytically inactive monomers in the absence of ligand and only becomes activated upon ligand-induced dimerization (for review, see Lemmon and Schlessinger, 2010). However, some receptor kinases in both animals (Chan et al., 2000; Ehrlich et al., 2011) and plants (Giranton et al., 2000; Wang et al., 2005, 2008; Shimizu et al., 2010; Bücherl et al., 2013) form catalytically inactive dimers or oligomers in the absence of ligand, with receptor activation presumably resulting from ligand-induced higher order oligomerization or conformational changes (Lemmon and Schlessinger, 2010). Similar to the latter receptors, SRK forms oligomers in unpollinated stigmas, i.e. in the absence of SCR (Giranton et al., 2000), at least partly via ligand-independent dimerization domains located within the SRK extracellular domain (Naithani et al., 2007). It has been proposed that these ligand-independent SRK oligomers are maintained in an inactive state by thioredoxins, the ubiquitous small oxidoreductases that reduce disulfide bridges in proteins (Buchanan and Balmer, 2005). This hypothesis is supported by the following observations: (1) two Brassica napus thioredoxins, the Thioredoxin H-Like proteins THL1 and THL2, were identified as SRK interactors in a yeast (Saccharomyces cerevisiae) two-hybrid screen that used the B. napus SRK₉₁₀ kinase domain as bait (Bower et al., 1996); (2) when purified from pistils or insect cells, the Brassica oleracea SRK₃ variant was found to exhibit constitutive autophosphorylation activity in vitro, and this activity was inhibited by Escherichia coli-expressed THL1 proteins and was restored by addition of pollen coat proteins containing self but not of pollen coat proteins containing nonself SCR (Cabrillac et al., 2001); (3) the catalytic activity of THL1 was required for its inhibition of SRK₃ autophosphorylation activity in vitro (Cabrillac et al., 2001); and (4) antisense suppression of THL1/THL2 gene expression in the stigmas of a self-compatible B. napus strain reportedly produced a low-level constitutive incompatibility (Haffani et al., 2004), as might be expected if the THL1/THL2 proteins prevent the spontaneous activation of SRK-mediated signaling in stigmas.These observations notwithstanding, the in planta role of thioredoxin h proteins as negative regulators of SRK activity has not been conclusively demonstrated. To date, this proposed function has only been evaluated in a self-compatible strain of B. napus (Haffani et al., 2004). Consequently, it is not known if the proposed inhibitory effect of these thioredoxins on SRK catalytic activity is manifested in self-incompatible stigmas and if it applies to all SRK variants, be they derived from Brassica spp. or other self-incompatible species of the Brassicaceae such as Arabidopsis lyrata.In this study, we tested the in planta role of thioredoxin h proteins in the regulation of SI signaling using a transgenic self-incompatible Arabidopsis thaliana model that we generated by transforming A. thaliana with the SRKb-SCRb gene pair isolated from the Sb haplotype of self-incompatible A. lyrata (Kusaba et al., 2001; Nasrallah et al., 2002, 2004). We had previously shown that the stigmas of A. thaliana SRKb-SCRb transformants can exhibit an SI response that is as robust as the SI response observed in naturally self-incompatible A. lyrata, demonstrating that A. thaliana, which harbors nonfunctional S-locus haplotypes (Kusaba et al., 2001; Sherman-Broyles et al., 2007; Shimizu et al., 2008; Boggs et al., 2009c), has nevertheless retained all other factors required for SI. In view of the availability in A. thaliana of a highly efficient transformation method and numerous genetic resources, the A. thaliana SRK-SCR transgenic model has enabled the use of experimental approaches that are difficult or impossible to implement in Brassica species and has thus proven to be an invaluable platform for in planta analysis of SRK and SI signaling (Liu et al., 2007; Boggs et al., 2009a, 2009b; Tantikanjana et al., 2009; Tantikanjana and Nasrallah, 2012).We therefore used this transgenic A. thaliana self-incompatible model to determine if abolishing the proposed SRK-thioredoxin h interaction or eliminating expression of the major thioredoxin h proteins expressed in stigmas would affect the outcome of self- or cross pollination. To this end, we expressed a mutant form of SRKb that lacked the Cys residue previously shown to be required for the interaction of SRK with THLs (Mazzurco et al., 2001), and we analyzed plants carrying knockout insertional mutations in thioredoxin h genes. Our results are inconsistent with the proposed role of thioredoxin h proteins as negative regulators of SRK catalytic activity and SI signaling.     

Mutants impaired in vacuolar metal mobilization identify chloroplasts as a target for cadmium hypersensitivity in Arabidopsis thaliana

Cadmium (Cd) is highly toxic to plants causing growth reduction and chlorosis. It binds thiols and competes with essential transition metals. It affects major biochemical processes such as photosynthesis and the redox balance, but the connection between cadmium effects at the biochemical level and its deleterious effect on growth has seldom been established. In this study, two Cd hypersensitive mutants, cad1‐3 impaired in phytochelatin synthase (PCS1), and nramp3nramp4 impaired in release of vacuolar metal stores, have been compared. The analysis combines genetics with measurements of photosynthetic and antioxidant functions. Loss of AtNRAMP3 and AtNRAMP4 function or of PCS1 function leads to comparable Cd sensitivity. Root Cd hypersensitivities conferred by cad1‐3 and nramp3nramp4 are cumulative. The two mutants contrast in their tolerance to oxidative stress. In nramp3nramp4, the photosynthetic apparatus is severely affected by Cd, whereas it is much less affected in cad1‐3. In agreement with chloroplast being a prime target for Cd toxicity in nramp3nramp4, the Cd hypersensitivity of this mutant is alleviated in the dark. The Cd hypersensitivity of nramp3nramp4 mutant highlights the critical role of vacuolar metal stores to supply essential metals to plastids and maintain photosynthetic function under Cd and oxidative stresses.     

Molecular Characterization and Evolution of Self-Incompatibility Genes in Arabidopsis thaliana: The Case of the Sc Haplotype

The switch from an outcrossing mode of mating enforced by self-incompatibility to self-fertility in the Arabidopsis thaliana lineage was associated with mutations that inactivated one or both of the two genes that comprise the self-incompatibility (SI) specificity-determining S-locus haplotype, the S-locus receptor kinase (SRK) and the S-locus cysteine-rich (SCR) genes, as well as unlinked modifier loci required for SI. All analyzed A. thaliana S-locus haplotypes belong to the SA, SB, or SC haplotypic groups. Of these three, the SC haplotype is the least well characterized. Its SRKC gene can encode a complete open-reading frame, although no functional data are available, while its SCRC sequences have not been isolated. As a result, it is not known what mutations were associated with inactivation of this haplotype. Here, we report on our analysis of the Lz-0 accession and the characterization of its highly rearranged SC haplotype. We describe the isolation of its SCRC gene as well as the subsequent isolation of SCRC sequences from other SC-containing accessions and from the A. lyrata S36 haplotype, which is the functional equivalent of the A. thaliana SC haplotype. By performing transformation experiments using chimeric SRK and SCR genes constructed with SC- and S36-derived sequences, we show that the SRKC and SCRC genes of Lz-0 and at least a few other SC-containing accessions are nonfunctional, despite SCRC encoding a functional full-length protein. We identify the probable mutations that caused the inactivation of these genes and discuss our results in the context of mechanisms of S-locus inactivation in A. thaliana.     

Glycine and Folate Ameliorate Models of Congenital Sideroblastic Anemia

Sideroblastic anemias are acquired or inherited anemias that result in a decreased ability to synthesize hemoglobin in red blood cells and result in the presence of iron deposits in the mitochondria of red blood cell precursors. A common subtype of congenital sideroblastic anemia is due to autosomal recessive mutations in the SLC25A38 gene. The current treatment for SLC25A38 congenital sideroblastic anemia is chronic blood transfusion coupled with iron chelation. The function of SLC25A38 is not known. Here we report that the SLC25A38 protein, and its yeast homolog Hem25, are mitochondrial glycine transporters required for the initiation of heme synthesis. To do so, we took advantage of the fact that mitochondrial glycine has several roles beyond the synthesis of heme, including the synthesis of folate derivatives through the glycine cleavage system. The data were consistent with Hem25 not being the sole mitochondrial glycine importer, and we identify a second SLC25 family member Ymc1, as a potential secondary mitochondrial glycine importer. Based on these findings, we observed that high levels of exogenous glycine, or 5-aminolevulinic acid (5-Ala) a metabolite downstream of Hem25 in heme biosynthetic pathway, were able to restore heme levels to normal in yeast cells lacking Hem25 function. While neither glycine nor 5-Ala could ameliorate SLC25A38 congenital sideroblastic anemia in a zebrafish model, we determined that the addition of folate with glycine was able to restore hemoglobin levels. This difference is likely due to the fact that yeast can synthesize folate, whereas in zebrafish folate is an essential vitamin that must be obtained exogenously. Given the tolerability of glycine and folate in humans, this study points to a potential novel treatment for SLC25A38 congenital sideroblastic anemia.     

Effects of curcumin on methyl methanesulfonate damage to mouse kidney

Methylmethane sulfonate (MMS) is an alkylating agent that may react with DNA and damage it. We investigated histological changes and apoptosis caused by MMS and the effects of curcumin on MMS treated mouse kidneys. Twenty-four mice were divided into four equal groups: controls injected with saline, a group injected with 40 mg/kg MMS, a group injected with 40 mg/kg MMS and given 100 mg/kg curcumin by gavage, and a group given 100 mg/kg curcumin by gavage. MMS caused congestion and vacuole formation, and elevated the apoptotic index significantly, but had no other effect on kidney tissue. Curcumin improved the congestion and vacuole formation caused by MMS and decreased the apoptotic index. Curcumin administered with MMS appears to decrease the deleterious effects of MMS on the kidney.     

Methenyltetrahydrofolate synthetase regulates folate turnover and accumulation

Cellular folate deficiency impairs one-carbon metabolism, resulting in decreased fidelity of DNA synthesis and inhibition of numerous S-adenosylmethionine-dependent methylation reactions including protein and DNA methylation. Cellular folate concentrations are influenced by folate availability, cellular folate transport efficiency, folate polyglutamylation, and folate turnover specifically through degradation. Folate cofactors are highly susceptible to oxidative degradation in vitro with the exception of 5-formyltetrahydrofolate, which may be a storage form of folate. In this study, we determined the effects of depleting cytoplasmic 5-formyltetrahydrofolate on cellular folate concentrations and folate turnover rates in cell cultures by expressing the human methenyltetrahydrofolate synthetase cDNA in human MCF-7 cells and SH-SY5Y neuroblastoma. Cells with increased methenyltetrahydrofolate synthetase activity exhibited: 1) increased rates of folate turnover, 2) elevated generation of p-aminobenzoylglutamate in culture medium, 3) depressed cellular folate concentrations independent of medium folic acid concentrations, and 4) increased average polyglutamate chain lengths of folate cofactors. These data indicate that folate catabolism and folate polyglutamylation are competitive reactions that influence cellular folate concentrations, and that increased methenyltetrahydrofolate synthetase activity accelerates folate turnover rates, depletes cellular folate concentrations, and may account in part for tissue-specific differences in folate accumulation.