Cytopathological evaluations combined RNA and protein analyses on defined cell regions using single frozen tissue block

The co-existence of multiple cell components in tissue samples is the main obstacle for precise molecular evaluation on defined cell types. Based on morphological examination, we developed an efficient approach for paralleled RNA and protein isolations from an identical histological region in frozen tissue section.The RNA and protein samples prepared were sufficient for RT-PCR and Western blot analyses, and the results obtained were well coincident each other as well as with the corresponding parameters revealed from immunohistochemical examinations. By this way, the sampling problem caused by cell-cross contamination can be largely avoided, committing the experimental data more specific to a defined cell type. These novel methods thus allow us to use single tissue block for a comprehensive study by integration of conventional cytological evaluations with nucleic acid and protein analyses.

Review on microbial degradation of zearalenone and aflatoxins

The widespread contamination by mycotoxins,especially zearalenone and aflatoxins,in crops and their by-products has caused severe undesirable effects on human health and commercial trade.Researchers had screened out microorganisms from various media for degrading zearalenone and aflatoxins,and the results of a lot of studies showed that enzymes derived from microbial strains play a key role in degrading mycotoxins.Genetic engineering technology had been applied to improve the heterologously expressed degrading enzymes in several mature microbial hosts such as Escherichia coli and Pichia pastoris.The separated and purified recombinant enzyme had high activity in degrading mycotoxins in vitro.This review summarized the types of mycotoxins-degrading microorganisms and enzymes,and the progress on synthesis of heterologously expressed degrading enzymes by genetic engineering technology as well as related researches on improving the effect of degrading enzymes.We also prospected the future development in the study of using recombinant enzymes formed by genetic engineering technology to realize the simultaneous degradation of multiple mycotoxins in crops.

Anti-tumor Effect of Newcastle Disease Virus Expressing IL-2 in Lung Cancer Model

Recombinant Newcastle disease virus(rNDV)has shown an anti-cancer effect in preclinical studies,but has never been tested for lung cancer models.This study explored the anti-cancer activity of genetically modified NDV expressing IL-2(rNDV–IL-2)in lung cancer models.This study used Lewis lung carcinoma cell line(LLC)to create tumor models in C57 female mice,the tumor-bearing mice were treated with rNDV-IL-2,rNDV and phosphate-buffered saline(PBS),respectively.In vitro results revealed that rNDV effectively infected malignant cells and expressed IL-2,in vivo results revealed that rNDV expressing IL-2 was highly efficient in inhibiting lung cancer tumors,with an average tumor size of 291.255 mm^3 in rNDV-IL-2 group compared to 763.068 mm^3 in rNDV group and 1101.68 mm^3 in PBS group.For the survival studies,treatment with rNDV-IL-2 enhanced the survival rates of tumor-bearing mice by 36%compared to those of rNDV treated mice and by 80%compared to those of vehicle-treated mice(survival rate:12 out of 15 for rNDV-IL-2 group;seven out of 15 for rNDV group and zero out of 15 for vehicle group).These results demonstrated that rNDV-expressed IL-2 enhanced the intrinsic anti-tumor ability of Newcastle disease virus in lung cancer models by further restrain of lung tumor growth and improvement of the survival rates of the tumor-bearing mice.The genetically modified rNDV-IL-2 was a good candidate for lung cancer therapy.

An adaptive laser beam shaping technique based on a genetic algorithm

A new adaptive beam intensity shaping technique based on the combination of a 19-element piezo-electricity deformable mirror （DM） and a global genetic algorithm is presented. This technique can adaptively adjust the voltages of the 19 actuators on the DM to reduce the difference between the target beam shape and the actual beam shape. Numerical simulations and experimental results show that within the stroke range of the DM, this technique can be well used to create the given beam intensity profiles on the focal plane.

Application of Molecular Markers in Wildlife DNA Forensic Investigations

Wildlife DNAForensic isthe application of regular DNAforensic methodsfor proper identification of wildlife parts and their products.Recent advances in molecular genetic studies have generated a new and exciting range of possible applications of genetic methods to wildlife research,conservation,and management.These advances have led to an explosion in genetic research on wildlife for their identification at molecular level and have increased interest among researchers working in other scientific disciplines for application of genetic technology in wildlife DNAforensic field.Different molecular markers have been developed and being routinely used for analysis,such as nuclear markers(variable number of tandem repeats,single-nucleotide polymorphisms),mitochondrial markers(cytochrome b,cytochrome c oxidase subunit I,16S rRNA,12S rRNA,and D‑Loop)and microsatellites.As soon as,a case is reported under Wildlife Protection Act(1972)the case exhibits are sent to forensic laboratories for proper analysis of species for appropriate application of law.

Multiscale engineering of microbial cell factories: A step forward towards sustainable natural products industry

Microbial cell factories(bacteria and fungi)are the leading producers of beneficial natural products such as lycopene,carotene,herbal medicine,and biodiesel etc.These microorganisms are considered efficient due to their effective bioprocessing strategy(monoculture-and consortial-based approach)under distinct processing conditions.Meanwhile,the advancement in genetic and process optimization techniques leads to enhanced biosynthesis of natural products that are known functional ingredients with numerous applications in the food,cosmetic and medical industries.Natural consortia and monoculture thrive in nature in a small proportion,such as wastewater,food products,and soils.In similitude to natural consortia,it is possible to engineer artificial microbial consortia and program their behaviours via synthetic biology tools.Therefore,this review summarizes the optimization of genetic and physicochemical parameters of the microbial system for improved production of natural products.Also,this review presents a brief history of natural consortium and describes the functional properties of monocultures.This review focuses on synthetic biology tools that enable new approaches to design synthetic consortia;and highlights the syntropic interactions that determine the performance and stability of synthetic consortia.In particular,the effect of processing conditions and advanced genetic techniques to improve the productibility of both monoculture and consortial based systems have been greatly emphasized.In this context,possible strategies are also discussed to give an insight into microbial engineering for improved pro-duction of natural products in the future.In summary,it is concluded that the coupling of genomic modifications with optimum physicochemical factors would be promising for producing a robust microbial cell factory that shall contribute to the increased production of natural products.