Oxidative Folding of Conopeptides Modified by <Emphasis Type="Italic">Conus</Emphasis> Protein Disulfide Isomerase

Protein disulfide isomerase is a type of enzyme that catalyses the oxidation, isomerization and reduction of disulfide bonds. Conotoxins that containing disulfide bonds are likely substrates of protein disulfide isomerise. Here, we cloned 12 protein disulfide isomerise genes from 12 different cone snail species that inhabited the sea near Sanya in China. The full-length amino acid sequences of these protein disulfide isomerase genes share a high degree of homology, including the same -CGHC- active site sequence and -RDEL- endoplasmic reticulum retention signal. To obtain enough conus protein disulfide isomerase for functional studies, we constructed the expression vector pET28a-sPDI. Conus protein disulfide isomerase was successfully expressed using Escherichia coli expression system and purified using chromatography method of affinity chromatography. The recombinant conus protein disulfide isomerase showed the ability to catalyse disulfide bond formation and rearrangement in the lysozyme enzyme activity assay. The role of conus protein disulfide isomerase in the in vitro oxidative folding of conotoxins was investigated using synthetic linear conotoxin lt14a, a peptide composed of 13 amino acids. It was confirmed by high performance liquid chromatography and mass spectrometry analysis that conus protein disulfide isomerase can catalyse the disulfide bond formation of linear lt14a. Then, conus protein disulfide isomerase was acted as a fusion partner during the production of engineered peptidyl-prolyl cis–trans isomerase and lt14a derived from cone snails. It was shown that peptidyl-prolyl cis–trans isomerase and conotoxin lt14a are successfully expressed in a highly soluble form by fusion with conus protein disulfide isomerase. Thus, conus protein disulfide isomerase functions not only as an enzyme that catalyses oxidative process but also a fusion partner in recombinant conotoxin expression.     

Twin-Arginine Translocation of Active Human Tissue Plasminogen Activator in Escherichia coli

When eukaryotic proteins with multiple disulfide bonds are expressed at high levels in Escherichia coli, the efficiency of thiol oxidation and isomerization is typically not sufficient to yield soluble products with native structures. Even when such proteins are secreted into the oxidizing periplasm or expressed in the cytoplasm of cells carrying mutations in the major intracellular disulfide bond reduction systems (e.g., trxB gor mutants), correct folding can be problematic unless a folding modulator is simultaneously coexpressed. In the present study we explored whether the bacterial twin-arginine translocation (Tat) pathway could serve as an alternative expression system for obtaining appreciable levels of recombinant proteins which exhibit complex patterns of disulfide bond formation, such as full-length human tissue plasminogen activator (tPA) (17 disulfides) and a truncated but enzymatically active version of tPA containing nine disulfides (vtPA). Remarkably, targeting of both tPA and vtPA to the Tat pathway resulted in active protein in the periplasmic space. We show here that export by the Tat translocator is dependent upon oxidative protein folding in the cytoplasm of trxB gor cells prior to transport. Whereas previous efforts to produce high levels of active tPA or vtPA in E. coli required coexpression of the disulfide bond isomerase DsbC, we observed that Tat-targeted vtPA and tPA reach a native conformation without thiol-disulfide oxidoreductase coexpression. These results demonstrate that the Tat system may have inherent and unexpected benefits compared with existing expression strategies, making it a viable alternative for biotechnology applications that hinge on protein expression and secretion.     

水稻金属耐受蛋白基因OsMTP2生物信息学及表达分析

为了解水稻(Oryza sativa)响应重金属污染及对重金属积累的机制,利用生物信息学手段对水稻金属耐受蛋白(metal tolerance protein, MTP) OsMTP2的结构特征进行预测,并分析OsMTP2基因的表达特征。结果表明,该蛋白由415个氨基酸组成,具有很强的疏水性。mRNA原位杂交结果表明,OsMTP2在叶片输导组织中有较强的表达,但在根、花药中没有检测到明显的杂交信号。这说明水稻金属耐受蛋白基因OsMTP2主要在输导组织中表达,并在金属离子运输中发挥重要作用。     

Alternations in phenolic acids content in developing rye grains in normal environment and during enforced dehydration

A series of high pressure liquid chroamtography analyses revealed the presence of five phenolic acids in rye caryopses (vanillic, caffeic, p-coumaric, ferulic and sinapic), three of which (p-coumaric, ferulic and sinapic) were found in the free phenolic fraction. Ferulic acid was predominant, both among free acids and total phenolic acids (i.e. free, liberated from soluble esters and glycosides). The highest content of the free phenolic acids in rye caryopses was observed at the beginning of development, when on 22 DAF it was estimated at 11.55 μg·g⁻¹ DW. During dehydratation the total level of free phenolic acids in rye caryopses decreased in all investigated samples. Although total phenolic acids contents in all samples of unripe rye caryopses always decreased after dehydration, in rye sample collected in full ripeness (57 DAF), the amount of these compounds increased after the enforced dehydration. It should be added that in ester-bound-soluble phenolic acids fraction (the largest part in the total phenolic acids fraction), irrespective of the total amount decrease, much increase of sinapic acid content in this fraction was observed after dehydratation treatment in all investigated samples of caryopses of various ripeness. During the development and ripening of rye caryopses, a gradual increase in the precocious germination ability of the grain was observed. The enforced dehydration stimulated the process of precocious germination of developing and ripening rye caryopses. A possible role of phenolics in preventing precocious germination and acclimation to dehydration of developing and ripening rye grains is discussed.     

Redundancy modulation of nuclear DNA sequences in Dasypyrum villosum

In order to assess fluid domains in the genome of Dasypyrum villosum, Feulgen/DNA cytophotometric determinations and molecular and cytological DNA-DNA hybridization experiments were carried out in resting embryos and developing seedlings from yellow and brown caryopses belonging to different populations. The cytophotometric data showed that the basic amount of nuclear DNA is, on average, 12% higher in 2-day-old seedlings from yellow caryopses as compared to those from brown caryopses. It increases in each individual during seed germination, to a higher extent in seedlings from yellow caryopses than in those from brown caryopses. DNA content also differs up to 13% between plants within a caryopsis-colour group and up to 40% between populations. Dot-blot hybridization of a 396-bp D. villosum-specific DNA repeat to genomic DNA extracted from embryos in dry seeds, or from seedlings belonging to single progenies of plants from different populations, confirmed the cytophotometric results. The redundancy in the genome of sequences hybridizing to the 396-bp element differs significantly both between populations and between plant progenies within a population. During seed germination these sequences are the more amplified the less they are redundant in the genome of resting embryos, and amplification occurs to a significantly-greater extent in seedlings from yellow caryopses than in those from brown caryopses. ³H-labelled 396-bp sequences hybridize at or near the telomeres of most chromsome pairs though only to the shorter of the two subtelocentric pairs. The hybridization level is higher in seedlings from yellow caryopses that in those from brown caryopses, and a linear correlation exists between the number of silver grains counted over the labelled regions of each chromosome pair in the two groups of seedlings. Possible control mechanisms of the observed changes in the nuclear genome, and the role of these changes in developmental pregulation and environmental adaptation, are discussed.     

Maternal Nicotine Exposure Leads to Impaired Disulfide Bond Formation and Augmented Endoplasmic Reticulum Stress in the Rat Placenta

Maternal nicotine exposure has been associated with many adverse fetal and placental outcomes. Although underlying mechanisms remain elusive, recent studies have identified that augmented endoplasmic reticulum (ER) stress is linked to placental insufficiency. Moreover, ER function depends on proper disulfide bond formation—a partially oxygen-dependent process mediated by protein disulfide isomerase (PDI) and ER oxidoreductases. Given that nicotine compromised placental development in the rat, and placental insufficiency has been associated with poor disulfide bond formation and ER stress, we hypothesized that maternal nicotine exposure leads to both placental ER stress and impaired disulfide bond formation. To test this hypothesis, female Wistar rats received daily subcutaneous injections of either saline (vehicle) or nicotine bitartrate (1 mg/kg) for 14 days prior to mating and during pregnancy. Placentas were harvested on embryonic day 15 for analysis. Protein and mRNA expression of markers involved in ER stress (e.g., phosphorylated eIF2α, Grp78, Atf4, and CHOP), disulfide bond formation (e.g., PDI, QSOX1, VKORC1), hypoxia (Hif1α), and amino acid deprivation (GCN2) were quantified via Western blot and/or Real-time PCR. Maternal nicotine exposure led to increased expression of Grp78, phosphorylated eIF2α, Atf4, and CHOP (p<0.05) in the rat placenta, demonstrating the presence of augmented ER stress. Decreased expression of PDI and QSOX1 (p<0.05) reveal an impaired disulfide bond formation pathway, which may underlie nicotine-induced ER stress. Finally, elevated expression of Hif1α and GCN2 (p<0.05) indicate hypoxia and amino acid deprivation in nicotine-exposed placentas, respectively, which may also cause impaired disulfide bond formation and augmented ER stress. This study is the first to link maternal nicotine exposure with both placental ER stress and disulfide bond impairment in vivo, providing novel insight into the mechanisms underlying nicotine exposure during pregnancy on placental health.     

Biosynthesis of stizolamine in Stizolobium hassjoo

In Stizolobium hassjoo, stizolamine is located in seeds and pericarps and is not found in mature leaves, stems and roots. The content of stizolamine in seeds and the fruits increases with their maturation but do not correlate with their dry weights. A feeding experiment showed that guanosine triphosphate [U-¹⁴C] is effectively incorporated into stizolamine in pericarps.     

Oxidative protein folding: Selective pressure for prolamin evolution in rice

During seed development, endosperm cells of highly productive cereals, including rice, synthesize disulfide-rich proteins in large amounts and deposit them into storage organelles. Disulfide bond formation involves electron transfer and generates H₂O₂ as a by-product. To ensure proper development and maturation of seeds, the endosperm cells must supply large amounts of oxidizing equivalents to dithiols in nascent proteins in a controlled manner. This review compares multiple oxidative protein folding systems in yeast, cultured human cells, and rice endosperm. We discuss possible roles of ERO1, other sulfhydryl oxidases, and the protein disulfide isomerase family in the formation of disulfide bonds in storage proteins and the development of protein bodies. Rice prolamins, encoded by a multigene family, are divided into Cys-rich and Cys-depleted subgroups. We discuss the potential importance of disulfide bond formation in the evolution of the prolamin family in japonica rice.     

Promising Role of Moderate Soil Drying and Subsequent Recovery Through Moderate Wetting at Grain-Filling Stage for Rice Yield Enhancement

The study was conducted at the grain-filling stage to elucidate the physiological and molecular mechanisms of the root to enhance yield under alternate wetting and drying (AWD) compared with conventional irrigation. Measurements of root dry weight (RDW), seed setting rate, total kernel weight, and grain yield were determined along with 2D electrophoresis to detect altered protein expression in response to moderate soil drying (MD) and the subsequent recovery phase as moderate wetting (MW) under AWD compared with continuous wetting under CI. We found significant enhancement in RDW as well as 14.30 % increase in inferior spikelets^, seed setting and 10.32 g m⁻² increase in final yield. Among the total 55 differentially expressed proteins, 26 proteins were differentially expressed under both MD treatment and MW treatment, whereas 14 proteins under MD and 15 proteins under MW showed distinct expression. Differentially expressed proteins were involved in redox homeostasis, signaling, defense, energy, photoassimilate remobilization and included 14-3-3 proteins, cysteine-rich receptor-like protein kinase, monodehydroascorbate reductase, ascorbate peroxidase, glutathione S-transferases, translationally controlled tumor protein, remorin C-terminal domain containing protein, protein disulfide isomerase, DnaK family protein, cysteine synthase, aminotransferase, phosphoglycerate mutase, pyruvate phosphate dikinase, ATP synthase, and abscisic acid stress ripening (ASR1). The differential expression ratio of the signaling, redox, and defense group proteins was almost the same under MD and MW. ABA signaling, amino acid synthesis, and N remobilization were upregulated under MD, and the enzymes involved in carbohydrate, energy, and transportation metabolism were upregulated under MW. In conclusion, at the rice grain-filling stage, AWD is a potential technique to trigger signaling and the enzymatic protein network for systematic senescence initiation, root enlargement for maximum nutrient uptake, and maximize photoassimilate remobilization for yield enhancement.