Heterologous expression of antifreeze protein gene AnAFP from Ammopiptanthus nanus enhances cold tolerance in Escherichia coli and tobacco

Antifreeze proteins are a class of polypeptides produced by certain animals, plants, fungi and bacteria that permit their survival under the subzero environments. Ammopiptanthus nanus is the unique evergreen broadleaf bush endemic to the Mid-Asia deserts. It survives at the west edge of the Tarim Basin from the disappearance of the ancient Mediterranean in the Tertiary Period. Its distribution region is characterized by the arid climate and extreme temperatures, where the extreme temperatures range from − 30 °C to 40 °C. In the present study, the antifreeze protein gene AnAFP of A. nanus was used to transform Escherichia coli and tobacco, after bioinformatics analysis for its possible function. The transformed E. coli strain expressed the heterologous AnAFP gene under the induction of isopropyl β-D-thiogalactopyranoside, and demonstrated significant enhancement of cold tolerance. The transformed tobacco lines expressed the heterologous AnAFP gene in response to cold stress, and showed a less change of relative electrical conductivity under cold stress, and a less wilting phenotype after 16 h of − 3 °C cold stress and thawing for 1 h than the untransformed wild-type plants. All these results imply the potential value of the AnAFP gene to be used in genetic modification of commercially important crops for improvement of cold tolerance.     

Chibby functions in Xenopus ciliary assembly,embryonic development,and the regulation of gene expression

Wnt signaling and ciliogenesis are core features of embryonic development in a range of metazoans. Chibby (Cby), a basal-body associated protein, regulates β-catenin-mediated Wnt signaling in the mouse but not Drosophila. Here we present an analysis of Cby?s embryonic expression and morphant phenotypes in Xenopus laevis. Cby RNA is supplied maternally, negatively regulated by Snail2 but not Twist1, preferentially expressed in the neuroectoderm, and regulates β-catenin-mediated gene expression. Reducing Cby levels reduced the density of multiciliated cells, the number of basal bodies per multiciliated cell, and the numbers of neural tube primary cilia; it also led to abnormal development of the neural crest, central nervous system, and pronephros, all defects that were rescued by a Cby-GFP chimera. Reduction of Cby led to an increase in Wnt8a and decreases in Gli2, Gli3, and Shh RNA levels. Many, but not all, morphant phenotypes were significantly reversed by the Wnt inhibitor SFRP2. These observations extend our understanding of Cby?s role in mediating the network of interactions between ciliogenesis, signaling systems and tissue patterning.     

Gene expression and characterization of a stress-induced tyrosine decarboxylase from Arabidopsis thaliana

Full-length tyrosine decarboxylase cDNA (TyrDC) from Arabidopsis thaliana was identified by rapid amplification of cDNA ends-PCR and isolated by RT-PCR. The TyrDC mRNA was substantially induced by drought stress and wounding, and was considerably decreased by salt stress. By using TyrDC protein fusions with green fluorescent protein, an intracellular localization to the cytoplasm was shown. Recombinant (His)₆-TyrDC was expressed in Escherichia coli and enzymatically characterized: it exclusively catalyzed the conversion of l-tyrosine to tyramine, exhibited an optimum temperature of 50 °C, and an optimum pH at approximately 8.5-9. Recombinant TyrDC protein formed tetramers, as shown by blue native gel electrophoresis.

Structured summary

MINT-7040408:TyrDC (uniprotkb:Q8RY79) and TyrDC (uniprotkb:Q8RY79) bind (MI:0407) by blue native page (MI:0276)     

Optimizing Membrane Protein Overexpression in the Escherichia coli strain Lemo21(DE3)

Escherichia coli BL21(DE3) is widely used to overexpress proteins. In this overexpression host, the gene encoding the target protein is located on a plasmid and is under control of the T7 promoter, which is recognized exclusively by the T7 RNA polymerase (RNAP). The T7 RNAP gene is localized on the chromosome, and its expression is governed by the non-titratable, IPTG-inducible lacUV5 promoter. Recently, we constructed the Lemo21(DE3) strain, which allows improved control over the expression of genes from the T7 promoter. Lemo21(DE3) is a BL21(DE3) strain equipped with a plasmid harboring the gene encoding T7 lysozyme, an inhibitor of the T7 RNAP, under control of the exceptionally well-titratable rhamnose promoter. The overexpression yields of a large collection of membrane proteins in Lemo21(DE3) at different concentrations of rhamnose indicated that this strain may be very suitable for optimizing the production of membrane proteins. However, insight in the mechanism by which optimized expression yields are achieved in Lemo21(DE3) is lacking. Furthermore, whether the overexpressed proteins are suitable for functional and structural studies remains to be tested. Here, we show that in Lemo21(DE3), (i) the modulation of the activity of the T7 RNAP by the T7 lysozyme is key to optimizing the ratio of membrane proteins properly inserted in the cytoplasmic membrane to non-inserted proteins; (ii) maximizing the yields of membrane proteins is accompanied by reduction of the adverse effects of membrane protein overexpression, resulting in stable overexpression; and (iii) produced membrane proteins can be used for functional and structural studies.     

pKILLIN: a versatile positive-selection cloning vector based on the toxicity of Killin in Escherichia coli

The invention of DNA cloning over 40 years ago marked the advent of molecular biology. The technique has now become a routine practice in any modern biomedical laboratory. Although positive-selection of recombinants in DNA cloning seems to be superior to blue/white selection based on the disruption of the lacZ gene, it is rarely practiced due to its high background, lack of multiple cloning sites, and inability to express the genes of interest or purify the protein products. Here we report the creation of a new positive-selection cloning vector dubbed pKILLIN, which overcomes all of the above pitfalls. The essence behind its high cloning efficiency is the extreme toxicity and small size of the toxic domain of killin, a recently discovered p53 target gene. Insertion inactivation of killin within the multiple cloning site via either blunt- or sticky-end ligation not only serves as a highly efficient cloning trap, but also may allow any cloned genes to be expressed as His-tagged fusion proteins for subsequent purification. Thus, pKILLIN is a versatile positive-selection vector ideal for cloning PCR products, making DNA libraries, as well as routine cloning and bacterial expression of genes.     

Molecular cloning and characterization of an Hsp90/70 organizing protein gene from Frankliniella occidentalis (Insecta: Thysanoptera,Thripidae)

The heat shock 90/70 organizing protein (Hop), also known as Sti-1 (stress-induced protein-1), is a co-chaperone that usually mediates the interaction of Hsp90 and Hsp70 and has been extensively characterized in mammals and plants. However, its role in insects remains unknown. In the present study, we isolated and characterized a Hop homologue gene from Frankliniella occidentalis (Fohop). The Fohop contains a 1659 bp ORF encoding a protein of 552 amino acids with a caculated molecular mass of approximately 62.25 kDa, which displays a reasonable degree of identity with the known Hops and shares several canonical motifs, including three tetratricopeptide repeated motif domains (TPR1, TPR2A and TPR2B) and two aspartic acid–proline (DP) repeat motifs (DP1 and DP2). As in other hops, Fohop contains introns, but the number and the position are quite variable. The mRNA expression patterns indicated that Fohop was constitutively expressed throughout the developmental stages, but was obviously upregulated by heat stress both in larvae and adults. Our studies imply that Hop, as in other Hsps, may play an important role in heat shock response of F. occidentalis.     

Genetic variation in exon 10 of the BPI gene is associated with Escherichia coli F18 susceptibility in Sutai piglets

Our aim was to investigate the effect of the porcine bactericidal/permeability-increasing protein (BPI) on the susceptibility to enterotoxigenic Escherichia coli F18 (ETEC F18). Specifically, we wanted to determine whether the HpaII restriction polymorphism in exon 10 of BPI mediates susceptibility to ETEC F18. Thirty verified ETEC F18-resistant and thirty susceptible Sutai (Duroc × Taihu) piglets were identified using the receptor binding assay. Exon 10 of the BPI gene produced the AA, BB, and AB genotypes after HpaII digestion. The genotype distribution among ETEC F18-resistant piglets was significantly different from that among susceptible piglets. Among piglets with the AA genotype, 90% were ETEC F18-resistant; this percentage of resistant piglets was significantly higher than the percentage of resistant piglets with the AB (57.1%) and BB genotypes (17.4%). There was high expression only in the tissues of the duodenum and jejunum, wherein the expression levels in the ETEC F18-resistant group were significantly higher than those in the susceptible group (P < 0.05). The average expression levels in individuals with the AA genotype were significantly higher than those in individuals with the AB or BB genotype (P < 0.05), while the results of Western blot show the same evidences as real time PCR. These results indicate that the upregulation of porcine BPI gene expression in the small intestines plays a direct role in resistance to ETEC F18 infection. The AA genotype for the HpaII site in exon 10 of the porcine BPI gene was demonstrated to be an anti-ETEC F18 marker and could be used for selective breeding to enhance ETEC F18 resistance.     

Quantitative proteomic analysis of ribosomal protein L35b mutant of Saccharomyces cerevisiae

Recent studies have revealed that in higher eukaryotes, several ribosomal proteins are involved in some pathological events or developmental defects, indicating that ribosomal proteins perform unconventional functions other than protein biosynthesis. To obtain an insight into the novel roles of ribosomal proteins, we aimed to analyze the changes in proteome expression in ribosomal protein mutants by using Saccharomyces cerevisiae as a model system. We introduced the rpl35bΔ mutation into the 4159 green fluorescent protein (GFP)-tagged yeast strains by using the synthetic genetic array (SGA) method, and performed quantitative proteomic analysis by using a multilabel microplate reader and flow cytometer. We identified 22 upregulated and 20 downregulated proteins in the rpl35bΔ mutant. These proteins were primarily classified into the Gene Ontology (GO) categories of cellular biosynthetic process, translation, protein or nucleotide metabolic process, cell wall organization and biogenesis, and hyperosmotic response. We also investigated the correlation between the mRNA and protein levels of the identified proteins. Our results show that a ribosomal protein mutation can lead to perturbation in the expression of several proteins, including some other ribosomal proteins. Furthermore, our approach of combining a library of GFP-tagged yeast strains and the SGA method provides an effective and highly sensitive method for dynamic analysis of the effects of various mutations on proteome expression.