Expression of Drosera rotundifolia Chitinase in Transgenic Tobacco Plants Enhanced Their Antifungal Potential Abstract In this study, a chitinase gene (DrChit) that plays a role in the carnivorous processes of Drosera rotundifolia L. was isolated from genomic DNA, linked to a double CaMV35S promoter and nos terminator in a pBinPlus plant binary vector, and used for Agrobacterium-mediated transformation of tobacco. RT-qPCR revealed that within 14 transgenic lines analysed in detail, 57% had DrChit transcript abundance comparable to or lower than level of a reference actin gene transcript. In contrast, the transgenic lines 9 and 14 exhibited 72 and 152 times higher expression level than actin. The protein extracts of these two lines exhibited five and eight times higher chitinolytic activity than non-transgenic controls when measured in a fluorimetric assay with FITC-chitin. Finally, the growth of Trichoderma viride was obviously suppressed when the pathogen was exposed to 100 μg of crude protein extract isolated from line 9 and line 14, with the area of mycelium growth reaching only 56.4% and 45.2%, of non-transgenic control, respectively. This is the first time a chitinase from a carnivorous plant with substrate specificity for long chitin polymers was tested in a transgenic plant with the aim of exploring its antifungal potential.

High Yield Expression of Recombinant CD151 in E. coli and a Structural Insight into Cholesterol Binding Domain Abstract CD151 is an abundantly expressed eukaryotic transmembrane protein on the cell surface. It is involved in cell adhesion, angiogenesis and signal transduction as well in disease conditions such as cancer and viral infections. However, the molecular mechanism of CD151 activation is poorly understood due to the lack of structural information. By considering the difficulties in expressing the membrane protein in E. coli, herein we introduce the strategic design for the effective expression of recombinant CD151 protein in E. coli with high yield, that would aid for the structural studies. CD151 having four transmembrane domain (TMD’s) along with small and a large extracellular loop (LEL) is constructed in parts to enhance the soluble expression of the protein attached with fusion tag. This has led to the high yield of the recombinant CD151 protein in the designed constructs. The recombinant CD151 protein is characterized and confirmed by western blot, CD and Mass peptide fingerprint. The molecular dynamics simulations (MDS) for the full-length CD151 shows conformational changes in the LEL of the protein in the presence and absence of cholesterol and indicate the certainty of closed and open conformation of CD151 based on cholesterol binding. The MDS results have led to the understanding of the possible underlying mechanism for the activation of the CD151 protein.

Structural Characterization of Open Reading Frame-Encoded Functional Genes from Tilapia Lake Virus (TiLV) Abstract In recent years, large-scale mortalities are observed in tilapia due to infection with a novel orthomyxo-like virus named, tilapia lake virus (TiLV) which is marked to be a severe threat to universal tilapia industry. Currently, there are knowledge gaps relating to the antiviral peptide as well as there are no affordable vaccines or drugs available against TiLV yet. To understand the spreading of infection of TiLV in different organs of Oreochromis niloticus, RT-PCR analysis has been carried out. The gene segments of TiLV were retrieved from the NCBI database for computational biology analysis. The 14 functional genes were predicted from the 10 gene segments of TiLV. Phylogenetic analysis was employed to find out a better understanding for the evolution of tilapia lake virus genes. Out of 14 proteins, only six proteins show transmembrane helix region. Moreover, molecular modeling and molecular dynamics simulations of the predicted proteins revealed structural stability of the protein stabilized after 10-ns simulation. Overall, our study provided a basic bioinformatics on functional proteome of TiLV. Further, this study could be useful for development of novel peptide-based therapeutics to control TiLV infection.

Host-Induced Silencing of Some Important Genes Involved in Osmoregulation of Parasitic Plant Phelipanche aegyptiaca Abstract Broomrape is an obligate root-parasitic weed that acts as a competitive sink for host photoassimilates. Disruption of essential processes for growth of broomrape using host plant-mediated systemic signals can help to implement more specific and effective management plans of this parasite. Accordingly, we tested the possibility of transient silencing three involved genes (PaM6PR, PaCWI, and PaSUS1) in osmoregulation process of broomrape using syringe agroinfiltration of dsRNA constructs in tomato. The highest decrease in mRNA levels, enzyme activity, and amount of total reducing sugars was observed in Phelipanche aegyptiaca when grown on agroinfiltrated tomato plants by PaM6PR dsRNA construct than control. In addition, PaSUS1 dsRNA construct showed high reduction in mRNA abundance (32-fold fewer than control). The lowest decrease in mRNA levels was observed after infiltration of PaCWI dsRNA construct (eightfold fewer than control). While the highest reduction in PaM6PR and PaSUS1 expression levels was detected in the parasite at 3 days post-infiltration (dpi), the maximum reduction in both of the total reducing sugars amount and M6PR and SUS1 activities was observed at 8 dpi. On the contrary, CWI activity, PaCWI expression level, and amount of total reducing sugars in broomrape shoots simultaneously decreased at the day 3 after the dsRNA construct infiltration against PaCWI. On the whole, our results indicated that the three studied genes especially PaM6PR may constitute appropriate targets for the development of transgenic resistance in host plants using silencing strategy.

Design of Experiments As a Tool for Optimization in Recombinant Protein Biotechnology: From Constructs to Crystals Abstract In this review, the basic concepts and applications of design of experiments (DoE) in recombinant protein biotechnology will be discussed. The production of recombinant proteins usually begins with the construction of an expression vector that is then introduced into a microbial host. The target protein is overexpressed in the host’s cells and subsequently, it is isolated using a suitable purification method, its activity is assessed using a biological assay, while its crystallization is often required. Because each protein is unique and due to the complex interactions among the reagents in experiments, it is impossible that one set of reaction conditions would be optimal for all cases. Optimization of experimental conditions is usually carried out by the inefficient one-factor-at-a-time approach that does not take into account the combined effects of factors on a process. On the other hand, DoE approaches with a carefully selected small set of experiments, and therefore with a reduced cost and in a limited amount of time predict the effect of each factor and the effects of their interactions on a process. Importantly, several software packages are available that facilitate the choice of the DoE approach, design of the experiments, and analysis of the results.

A Novel VIII Carboxylesterase with High Hydrolytic Activity Against Ampicillin from a Soil Metagenomic Library Abstract A novel carboxylesterase gene, named dlfae4, was discovered and sequenced from a soil metagenomic library. The dlfae4 gene was composed of 1017 base pairs encoding 338 amino acid residues with a predicted molecular mass of 37.2 kDa. DLFae4 exhibited strong hydrolytic activity towards methyl ferulate under optimum pH and temperature conditions (pH 8.6, 50 °C) and displayed remarkable thermostability, with residual activity as high as 50% after incubation for 3 h at 60 °C. A family VIII esterase DLFae4 was found to contain a typical serine residue within the S-X-X-K motif, which serves as a catalytic nucleophile in class C β-lactamases and family VIII esterases. As a consequence of its high sequence similarity with β-lactamases, DLFae4 exhibited significant hydrolytic activity towards ampicillin. In addition, DLFae4 was found to be the first known member of family VIII carboxylesterases with phthalate-degrading ability. Site-directed mutagenesis studies revealed that Ser11, Lys14, and Tyr121 residues play an essential catalytic role in DLFae4. These new findings, which are of great importance for further in-depth research and engineering development of carboxylesterases, should advance the implementation of biotechnological applications.

An Alternative Hot Start PCR Method Using a Nuclease-Deficient ExoIII from Escherichia coli Abstract The Hot Start polymerase chain reaction (Hot Start PCR) is designed to reduce off-target amplification by blocking DNA polymerase extension at room temperature until the desired temperature is reached. In this study, we investigated a new method of Hot Start PCR that uses a modified Escherichia coli Exonuclease III (EcoExoIIIM) by substituting residues in the DNA-binding pocket and catalytic center. The results showed that PCR amplification yield and specificity were significantly promoted by the addition of EcoExoIIIM. We hypothesize that non-specific binding of primers at room temperature is prevented by binding of the primed template by EcoExoIIIM, which is then released from the DNA by heat denaturation before the first PCR cycle. Through this mechanism, PCR would be enhanced by reducing off-target extension at room temperature.

Anti-HER2 scFv Expression in Escherichia coli SHuffle ® T7 Express Cells: Effects on Solubility and Biological Activity Abstract Breast cancer is the second most commonly diagnosed cancer, worldwide. Human epidermal growth factor receptor 2 (HER2)-overexpressing breast cancer is correlated with poor prognosis. HER2-targeting monoclonal antibodies resulted in longer survival of HER2+ breast cancer. Single-chain variable fragment (scFv) demonstrates improved penetrability into tumors. Due to the presence of two disulfide bond, scFv expression in reducing bacterial cytoplasm may cause formation of inclusion bodies. Disulfide bond can be formed properly in cytoplasm of SHuffle® strain as it is trxB−, gor−, and overexpresses cytoplasmic DsbC chaperone. In this study, the anti-HER2 scFv was successfully expressed and purified in BL21 (DE3) and SHuffle® cells. Here, significant higher soluble anti-HER2 scFv was produced in SHuffle® than in BL21 strain. The specific binding of anti-HER2 scFv to HER2 was shown by flow cytometry analysis and ELISA. Moreover, it was demonstrated that the anti-HER2 scFv produced in SHuffle® binds to HER2 at higher level as compared to that expressed in BL21 cells. Furthermore, competitive ELISA-based study suggested that anti-HER2 scFv recognizes the same epitope of HER2 receptor as the trastuzumab antibody. Our findings indicated that correct disulfide bond formation in SHuffle® strain can result in enhanced solubility and higher biological activity level of anti-HER2 scFv.

Advances in the Production and Batch Reformatting of Phage Antibody Libraries Abstract Phage display antibody libraries have proven an invaluable resource for the isolation of diagnostic and potentially therapeutic antibodies, the latter usually being antibody fragments converted into IgG formats. Recent advances in the production of highly diverse and functional antibody libraries are considered here, including for Fabs, scFvs and nanobodies. These advances include codon optimisation during generation of CDR diversity, improved display levels using novel signal sequences, molecular chaperones and isomerases and the use of highly stable scaffolds with relatively high expression levels. In addition, novel strategies for the batch reformatting of scFv and Fab phagemid libraries, derived from phage panning, into IgG formats are described. These strategies allow the screening of antibodies in the end-use format, facilitating more efficient selection of potential therapeutics.

Molecular Cloning, Expression and Biochemical Characterization of a Family 5 Glycoside Hydrolase First Endo-Mannanase ( Rf GH5_7) from Ruminococcus flavefaciens FD-1 v3 Abstract The cellulosomal enzyme, RfGH51/2, of Ruminococcus flavefaciens contains an N-terminal module, a family 5 glycoside hydrolase GH5_4 with a putative endoglucanase activity, while C-terminal domain is a putative endo-mannanase (GH5_7). The two putative catalytic modules are separated by family 80 carbohydrate binding module (CBM80) having wide ligand specificity. The putative endo-mannanase module, GH5_7 (RfGH5_7), was cloned, expressed in Escherichia coli BL-21(DE3) cells and purified. SDS-PAGE analysis of purified RfGH5_7 showed molecular size ~ 35 kDa. Substrate specificity analysis of RfGH5_7 showed maximum activity against locust bean galactomannan (298.5 U/mg) followed by konjac glucomannan (256.2 U/mg) and carob galactomannan (177.2 U/mg). RfGH5_7 showed maximum activity at optimum pH 6.0 and temperature 60 °C. RfGH5_7 displayed stability in between pH 6.0 and 9.0 and thermostability till 50 °C. 10 mM Ca2+ ions increased the enzyme activity by 33%. The melting temperature of RfGH5_7 was 84 °C that was not affected by Ca2+ ions or chelating agents. RfGH5_7 showed, Vmax, 389 U/mg and Km, 0.92 mg/mL for locust bean galactomannan. TLC analysis revealed that RfGH5_7 hydrolysed locust bean galactomannan predominantly to mannose, mannobiose, mannotriose and higher degree of polymerization of manno-oligosaccharides indicating an endo-acting catalytic mechanism. This study revealed a highly active and thermostable endo-mannanase with considerable biotechnological potential.