Overexpression of AtLEA3-3 confers resistance to cold stress in Escherichia coli and provides enhanced osmotic stress tolerance and ABA sensitivity in Arabidopsis thaliana

Previous studies have shown that the late embryogenesis abundant (LEA) group 3 proteins significantly respond to changes in environmental conditions. However, reports that demonstrate their biological role, especially in Arabidopsis, are notably limited. This study examines the functional roles of the Arabidopsis LEA group 3 proteins AtLEA3-3 and AtLEA3-4 in abiotic stress and ABA treatments. Expression of AtLEA3-3 and AtLEA3-4 is upregulated by ABA, high salinity, and osmotic stress. Results on the ectopic expression of AtLEA3-3 and AtLEA3-4 in E. coli suggest that both proteins play important roles in resistance to cold stress. Overexpression of AtLEA3-3 in Arabidopsis (AtLEA3-3-OE) confers salt and osmotic stress tolerance that is characterized during germination and early seedling establishment. However, AtLEA3-3-OE lines show sensitivity to ABA treatment during early seedling development. These results suggest that accumulation of AtLEA3-3 mRNA and/or proteins may help heterologous ABA re-initiate second dormancy during seedling establishment. Analysis of yellow fluorescent fusion proteins localization shows that AtLEA3-3 and AtLEA3-4 are mainly distributed in the ER and that AtLEA3-3 also localizes in the nucleus, and in response to salt, mannitol, cold, or BFA treatments, the localization of AtLEA3-3 and AtLEA3-4 is altered and becomes more condensed. Protein translocalization may be a positive and effective strategy for responding to abiotic stresses. Taken together, these results suggest that AtLEA3-3 has an important function during seed germination and seedling development of Arabidopsis under abiotic stress conditions.     

Over-expression of <Emphasis Type=Italic>ThpI</Emphasis> from <Emphasis Type=Italic>Choristoneura fumiferana</Emphasis> enhances tolerance to cold in Arabidopsis

Thermal hysteresis proteins (Thps) known as antifreeze proteins for their antifreeze activity, depress the freezing point of water below the melting point in many polar marine fishes, terrestrial arthropods and plants. For the purpose of breeding cold-resistant plants, we designed to introduce the Thp gene into the plants. The physiological and biochemical effect of high-lever expression of the modified Choristoneura fumiferana Thp (ThpI) in Arabidopsis thaliana plants was analyzed. Under low temperature stress, the ThpI transgenic plants exhibited stronger growth than wild-type plants. The elevated cold tolerance of the ThpI over-expressing plants was confirmed by the changes of electrolyte leakage activity, malonyldialdehyde and proline contents. These results preliminarily showed that the Thp possibly be used to enhance the low temperature-tolerant ability of plants.     

Functional characterization of <Emphasis Type=Italic>Arabidopsis thaliana</Emphasis> transthyretin-like protein

Background  

Arabidopsis thaliana transthyretin-like (TTL) protein is a potential substrate in the brassinosteroid signalling cascade, having a role that moderates plant growth. Moreover, sequence homology revealed two sequence domains similar to 2-oxo-4-hydroxy-4-carboxy-5-ureidoimidazoline (OHCU) decarboxylase (N-terminal domain) and 5-hydroxyisourate (5-HIU) hydrolase (C-terminal domain). TTL is a member of the transthyretin-related protein family (TRP), which comprises a number of proteins with sequence homology to transthyretin (TTR) and the characteristic C-terminal sequence motif Tyr-Arg-Gly-Ser. TRPs are single domain proteins that form tetrameric structures with 5-HIU hydrolase activity. Experimental evidence is fundamental for knowing if TTL is a tetrameric protein, formed by the association of the 5-HIU hydrolase domains and, in this case, if the structural arrangement allows for OHCU decarboxylase activity. This work reports about the biochemical and functional characterization of TTL.     

Decrypting the H-NS-dependent regulatory cascade of acid stress resistance in <Emphasis Type=Italic>Escherichia coli</Emphasis>

Background  

H-NS regulates the acid stress resistance. The present study aimed to characterize the H-NS-dependent cascade governing the acid stress resistance pathways and to define the interplay between the different regulators.     

Cloning and expression of <Emphasis Type=Italic>Tenebrio molitor</Emphasis> antifreeze protein in <Emphasis Type=Italic>Escherichia coli</Emphasis>

A novel antifreeze protein cDNA was cloned by RT-PCR from the larva of the yellow mealworm Tenebrio molitor. The coding fragment of 339 bp encodes a protein of 112 amino acid residues and was fused to the expression vectors pET32a and pTWIN1. The resulted expression plasmids were transformed into Escherischia coli strains BL21 (DE3), ER2566, and Origami B (DE3), respectively. Several strategies were used for expression of the highly disulfide-bonded β-helix-contained protein with the activity of antifreeze in different expression systems. A protocol for production of refolded and active T. molitor antifreeze protein in bacteria was obtained.     

No direct binding of the heat-labile enterotoxin of <Emphasis Type=Italic>Escherichia coli</Emphasis> to <Emphasis Type=Italic>E. coli</Emphasis> lipopolysaccharides

A novel carbohydrate binding site recognizing blood group A and B determinants in a hybrid of cholera toxin and Escherichia coli heat-labile enterotoxin B-subunits (termed LCTBK) has previously been described, and also the native heat-labile enterotoxin bind to some extent to blood group A/B terminated glycoconjugates. The blood group antigen binding site is located at the interface of the B-subunits. Interestingly, the same area of the B-subunits has been proposed to be involved in binding of the heat-labile enterotoxin to lipopolysaccharides on the bacterial cell surface. Binding of the toxin to lipopolysaccharides does not affect the GM1 binding capacity. The present study aimed at characterizing the relationship between the blood group A/B antigen binding site and the lipopolysaccharide binding site. However, no binding of the B-subunits to E. coli lipopolysaccharides in microtiter wells or on thin-layer chromatograms was obtained. Incubation with lipopolysaccharides did not affect the binding of the B-subunits of heat-labile enterotoxin of human isolates to blood group A-carrying glycosphingolipids, indicating that the blood group antigen site is not involved in LPS binding. However, the saccharide competition experiments showed that GM1 binding reduced the affinity for blood group A determinants and vice versa, suggesting that a concurrent occupancy of the two binding sites does not occur. The latter finding is related to a connection between the blood group antigen binding site and the GM1 binding site through residues interacting with both ligands.     

Chromosomes are eliminated in the symmetric fusion between <Emphasis Type=Italic>Arabidopsis </Emphasis><Emphasis Type=Italic>thaliana</Emphasis> L. and <Emphasis Type=Italic>Bupleurum scorzonerifolium</Emphasis> Willd.

In order to investigate chromosome elimination in symmetric somatic hybridization between Bupleurum scorzonerifolium and Arabidopsis thaliana, protoplasts were isolated from suspension cultures of both A. thaliana and B. scorzonerifolium parents. Biparental protoplasts were mixed at a rate of 1.5:1 and fused with PEG-method. After protoplast fusion, the products were cultured in the P5 liquid medium for microcallus formation. Single cell lines formed from microcalli after subculturing on the MB1 (Xia and Chen, Plant Sci 120:197–203, 1996) solid medium. The putative somatic hybrid cell lines were identified by cytological and molecular analysis. Of the 132 somatic cell lines generated, 16 were identified as somatic hybrids, with the phenotypes resembled B. scorzonerifolium parent. These hybrids showed a complete set of B. scorzonerifolium chromosome and 0–2 small chromosome(s) of A. thaliana. A few of them showed nuclear and cytoplasmic SSR fragments of A. thaliana. These hybrid cell lines could differentiate to green spots, buds/leaves through complementation of regeneration ability. The chromosomes elimination of A. thaliana was discussed. Wang Minqin and Zhao Junsheng contributed equally to the work.     

A rapid<Emphasis Type=Italic>Agrobacterium</Emphasis>-mediated<Emphasis Type=Italic>Arabidopsis thaliana</Emphasis> transient assay system

Stable transformation ofArabidopsis thaliana is a lengthy process that involves up to 3 mo of plant growth and seed selection. We have developed a rapid, 3-wk transient assay system to test the functionality ofcis-regulatory regions controlling expression of a reporter gene in plants before undertaking stable transformation. Two-week-oldArabidopsis seedlings were vacuum-infiltrated withAgrobacterium tumefaciens cultures carrying various upstream regulatory regions controllinguidA (β-glucuronidase [GUS]) expression. Seedlings were fixed and stained for GUS activity 3–5 d following infiltration. Regulatory regions tested in this system include the cauliflower mosaic virus (CaMV)35S promoter, the upstream regulatory region of ribosomal protein geneL23A-1, and a temperature-inducible regulatory region (HSP101B) also fromArabidopsis. The percentage of seedlings positive for GUS activity varied depending on the construct used, with the CaMV35S promoter producing the highest number of GUS-positive seedlings. Temperature induction treatments elicited increased GUS expression in seedlings transformed with theHSP101B regulatory region. Regardless of construct, GUS expression levels were higher in seedlings collected 5 d followingAgrobacterium infiltration than those collected 3–4 d postinfiltration.     

Influence of the<Emphasis Type=Italic>SMT2</Emphasis> knock-out on hypocotyl elongation in<Emphasis Type=Italic>Arabidopsis thaliana</Emphasis>

Inhibitors are very important in the study of hormone function. Brasinazole (Brz) is a specific inhibitor of brassinosteroids (BRs) biosynthesis. To expand our knowledge of the molecular mechanisms of plant steroid signaling, we performed genetic screening using medium containing Brz under dark conditions. Mutants insensitive to Brz developlonger hypocotyls than their wild type counterparts. We isolatedabz453 as a Brz insensitive mutant. TAIL-PCR and the segregation ratio of T2 plants indicated a single T-DNA insertion at the 24-Sterol C-methyltransferase (SMT2) gene in theabz453 mutant. Recapitulation for putative FCP serine phosphatase (FSP), the gene neighboringSMT2, indicated no significant phenotypes, but theSMT2 anti-sense (SMT2-AS) line developed longer hypocotyls than the wild type in medium containing Brz. Additionally, theSMT2-AS line displayed similar phenotypes to theabz453 line in soil including enhanced growth and smaller silique. Theabz453 andSMT2-AS mutants showed phenotypes similar to those of wild type in medium containing benzylaminopurine, pacrobutrazol and ACC (precursor for ethylene) under dark conditions. However, when brassinolide (BL) dose response was observed, theabz453 andSMT2-AS lines showed higher sensitivity than wild type. Theabz453/det2 andabz453/bri1-119 double mutants showed enhanced growth compared to thedet2 andbri1-119 line under both dark and light conditions. Specially, in dark conditions double mutants displayed nearly 2- and 1.5-fold longer hypocotyls thandet2 andbri1-119 plants. Brz insensitivity to theSMT2 knock-out mutant and phenotypes of double mutants indicate that not only do BRI1 and DET2 influence the BRs response, as evidenced by hypocotyl elongation, but another sterol derived signals may also be affected in mutants, suggesting that another pathway is involved in hypocotyl elongation due to SMT2.     

A role of <Emphasis Type=Italic>ygfZ</Emphasis> in the <Emphasis Type=Italic>Escherichia coli</Emphasis> response to plumbagin challenge

Plumbagin is found in many herbal plants and inhibits the growth of various bacteria. Escherichia coli strains are relatively resistant to this drug. The mechanism of resistance is not clear. Previous findings showed that plumbagin treatment triggered up-regulation of many genes in E. coli including ahpC, mdaB, nfnB, nfo, sodA, yggX and ygfZ. By analyzing minimal inhibition concentration and inhibition zones of plumbagin in various gene-disruption mutants, ygfZ and sodA were found critical for the bacteria to resist plumbagin toxicity. We also found that the roles of YgfZ and SodA in detoxifying plumbagin are independent of each other. This is because of the fact that ectopically expressed SodA reduced the superoxide stress but not restore the resistance of bacteria when encountering plumbagin at the absence of ygfZ. On the other hand, an ectopically expressed YgfZ was unable to complement and failed to rescue the plumbagin resistance when sodA was perturbed. Furthermore, mutagenesis analysis showed that residue Cys228 within YgfZ fingerprint region was critical for the resistance of E. coli to plumbagin. By solvent extraction and HPLC analysis to follow the fate of the chemical, it was found that plumbagin vanished apparently from the culture of YgfZ-expressing E. coli. A less toxic form, methylated plumbagin, which may represent one of the YgfZ-dependent metabolites, was found in the culture supernatant of the wild type E. coli but not in the ΔygfZ mutant. Our results showed that the presence of ygfZ is not only critical for the E coli resistance to plumbagin but also facilitates the plumbagin degradation.     

Enteropathogenic <Emphasis Type=Italic>Escherichia coli</Emphasis> (EPEC) in Antarctic fur seals <Emphasis Type=Italic>Arctocephalus gazella</Emphasis>

Rectal swabs were collected from Antarctic fur seal pups Arctocephalus gazella at Cape Shirreff, South Shetland Islands, and analyzed for the presence of anthropogenic pathogens. Two of the 33 pups tested positive for enteropathogenic Escherichia coli (EPEC). These samples are the first records of EPEC in Antarctic wildlife and suggest that more needs to be done to protect the Antarctic fauna from exotic anthropogenic pathogens.     

Across Genus Plasmid Transformation Between <Emphasis Type=Italic>Bacillus subtilis</Emphasis> and <Emphasis Type=Italic>Escherichia coli</Emphasis> and the Effect of <Emphasis Type=Italic>Escherichia coli</Emphasis> on the Transforming Ability of Free Plasmid DNA

The results presented in this article show that direct plasmid transfer from Escherichia coli carrying shuttle plasmid to Bacillus subtilis occurred when close contact between the two species was established by mixing E. coli and B. subtilis onto selective agar plates. The data demonstrate that the production of resistant colonies by plasmid transformation through cell contact was DNase I sensitive and dependent on transformable B. subtilis strains. Furthermore, another observation indicated that the E. coli strain is able to affect the transformation capability of B. subtilis. It is assumed that the donor strain is a momentous factor for taking up plasmid DNA. This conclusion is significant in the assessment of both the possibility of intercellular DNA transfer in natural habitats of micro-organisms and the risk of the application of genetically engineered micro-organisms.