Encapsulation of propolis extracted with methylal in the chitosan nanoparticles and its antibacterial and cell cytotoxicity studies.

In this study we develop novel type of antibacterial chitosan-propolis NPs to improve theantimicrobial activity against various pathogens. To this aim, we primarily extracted propolis with methylal and ethanol as green solvents and its encapsulation with chitosan NPs. The developed propolis loaded chitosan NPs indicated antimicrobial and anti-biofilm properties against various gram positive and negative. FTIR revealed the successful encapsulation of the propolis extract with Ethanol (PE) and Methylal (PM) into the chitosan nano career matrix. HPLC and GC-MASS also confirmed the presence of flavonoids and phenols compounds of propolis extracted with both solvents. In addition, we confirmed the total phenolic and flavonoid compounds in propolis by calorimetric method of Folin-Ciocalteu and aluminum trichloride complex formation assays, respectively. PE-CH and PM-CH were optimized regarding physicochemical properties such as particle size, zeta potential, and poly dispersity index (PDI) index. DLS and SEM micrographs confirmed a spherical morphology in a range of 360-420 nm with Z potential values of 30-48 mV and PDI of 0.105-0.166 for PE-CH and PM-CH, respectively. The encapsulation efficiency was evaluated using colorimetric analysis, with median values ranging from 90 to 92%. The MIC values within the range of 2 to 230 µg/ml and MBC values between 3 to 346 µg/ml against both gram-positive and negative bacteria. While both PE and PM showed a significant reduction in the number of E. coli, S. aureus, and S. epidermidis, the use of PE-CH and PM-CH led to a statistically significant and greater reduction in number of E. coli, S. aureus, and S. epidermidis strains on the biofilm, pre-formed biofilm and planktonic phases. Besides, the DPPH assay showed significant antioxidant activity for these NPs within the range of 36 to 92%. MTT assay for MHFB-1, HFF, L929, MDF, and MCF-7 cells exhibited statistically significant differences in each other that show the IC50 between 60-160 µg/ml for normal cells and 20 for cancer cells. Finally the present study indicated that both PM and PM-CH greater than PE and PE-CH in which contain high flavonoid and phenolic contents with a high antioxidation potential antioxidant properties, which could be beneficial for cell proliferation and antibiotic and anticancer applications.

Poliglusam Nanoparticles Activate T Cell Response in Breast Cancer Cell: an In Vivo and In Vitro Study.

Poliglusam nanoparticles are potential therapeutic agents for the treatment of cancer. In particular, their efficacy has been reported as delivery systems in breast cancer. The aim of this study is to propose a new immunotherapeutic strategy, using Poliglusam nanoparticles as activators of the human immune response. Poliglusam nanoparticles were synthesized and characterized using both dynamic light scattering and electron microscopy. Whilst, their effectiveness in immune stimulation and detection of apoptosis was evaluated by cytokine and TUNEL assays. Finally, the cytokines pattern in splenocytes revealed an increase in IFN-γ production. The results of cytotoxicity on 4 T1 cells show an increase in the mortality rate with respect to the control cell line. The rate of apoptosis induced by Poliglusam nanoparticles on 4 T1 mouse breast cancer cell line is about 45% higher compared to MCF-7 human cells line, revealing the natural tendency of Poliglusam in increasing the production of IFN-γ in cancer cells. At the state-of-art of the knowledge, very few information have been achieved on the immunological effects of Poliglusam. This work is one of the first studies for the identification of non-functionalized Poliglusam nanoparticles impact on breast cancer. Thus, their immunotherapeutic effect, combined with an anticancer drug, can be employed as potential effective drug for eliminating breast cancer cells in the future.

Simultaneous Expression of GUS and Actin Genes by Using the Multiplex RT-PCR and Multiplex Gold Nanoparticle Probes.

Gene expression analysis is considered to be extremely important in many different biological researches. DNA-based diagnostic test, which contributes to DNA identification, has higher specificity, cost, and speed than some biochemical and molecular methods. In this study, we try to use the novel nano technology approach with Multiplex RT-PCR and Gold nano particular probes (GNPs-probes) in order to get gene expression in Curcumas melons. We used Agrobacterium tumefactions for gene transfer and GUS reporter gene as a reporter. After cDNA synthesis, Multiplex PCR and Multiplex RT-PCR techniques were used. Finally, probes were designed for RNA of GUS and Actin genes, and then the analysis of the gene expression using the probes attached to GNPs was carried out and the color changes in the GNPs were applied. In the following, probes hybridization was checked with DNA between 400 to 700 nm wavelengths and the highest rate was observed in the 550 to 650 nm. The results show that the simultaneous use of GNP-attached detectors and Multiplex RT-PCRcan reduce time and costmore considerably than somelaboratory methods for gene expiration investigation. Additionally, it can be seen thatthere is an increase in sensitivity and specificity of our investigation. Based on our findings, this can bea novel study doneusingMultiplex RT-PCRand unmodified AuNPs for gene transfer and expression detection to plants. We can claim that this assay has a remarkable advantage including rapid, cost-effectiveness, specificity and accuracy to detect transfer and expression genes in plants. Also,we can use this technique from other gene expressionsin many different biology samples.

Thiolated AuNP probes and multiplex PCR for molecular detection of Staphylococcus epidermidis.

The emergence of nanotechnology in biology helps to apply the gold nanoparticle probes for fast and accurate identification of pathogens compared to the time-consuming and non-precise phenotypic methods. In this study, two molecular methods have been established for the accurate identification of staphylococcus epidermidis from other coagulase-negative staphylococci. Multiplex PCR was performed using designed primers for Gmk2 and pta housekeeping genes, and SESB specific gene of S. epidermidis. Colorimetric detection by gold nanoparticle probes was carried out using two 20-base thiolated probes designed based on the sequence of pta housekeeping gene of S. epidermidis. The specificity of multiplex PCR and colorimetric assays were determined using genomic DNA of Staphylococcus aureus, Escherichia coli, Pseudomonas aeruginosa and Acinetobacter baumannii as negative controls and no alteration was detected. To investigate the sensitivity of the primers and gold nanoparticle probes, different concentrations of the extracted DNA from S. epidermidis were used. Based on the results, the minimum required quantity of target DNA for multiplex PCR amplification was 1 ng/µL and for color and absorption alteration of solution in colorimetric assay was 20 ng/µL. Our results revealed that both methods were sufficiently specific and sensitive to detect S. epidermidis.

ß-Lactoglobulin: An efficient nanocarrier for advanced delivery systems.

Thanks to the progress of nanotechnology there are several agent-delivery systems that can be selected to achieve rapid and specific delivery of a wide variety of biologically active agents. Consequently, the manipulation and engineering of biopolymers has become one of the most exciting subjects for those who study delivery systems on the nanoscale. In this regard, both nanoparticle formation and a carrier role have been observed in the case of the globular milk whey protein, ß-lactoglobulin (ß-LG), setting it apart from many other proteins. To date, many efforts adopting different approaches have created ß-LG nanoparticles useful in forming delivery systems for various agents with specific targets. In this review, the potential of ß-LG to play the role of an efficient and diverse carrier protein, as well as its ability to form a well-targeted nano-scale delivery system is discussed.

Overexpression of molecular chaperons GRP78 and GRP94 in CD44(hi)/CD24(lo) breast cancer stem cells.

INTRODUCTION: Breast cancer stem cell with CD44(hi)/CD24(lo) phonotype is described having stem cell properties and represented as the main driving factor in breast cancer initiation, growth, metastasis and low response to anti-cancer agents. Glucoseregulated proteins (GRPs) are heat shock protein family chaperons that are charged with regulation of protein machinery and modulation of endoplasmic reticulum homeostasis whose important roles in stem cell development and invasion of various cancers have been demonstrated. Here, we investigated the expression levels of GRP78 and GRP94 in CD44(hi)/CD24(lo) phenotype breast cancer stem cells (BCSCs). METHODS: MCF7, T-47D and MDA-MB-231 breast cancer cell lines were used. CD44(hi)/CD24(lo) phenotype cell population were analyzed and sorted by fluorescence-activated cell sorting (FACS). Transcriptional and translational expression of GRP78 and GRP94 were investigated by western blotting and quantitative real time PCR. RESULTS: RESULTS showed different proportion of CD44(hi)/CD24(lo) phenotype cell population in their original bulk cells. The ranking of the cell lines in terms of CD44(hi)/CD24(lo) phenotype cell population was as MCF7

Protein cold adaptation: Role of physico-chemical parameters in adaptation of proteins to low temperatures.

During years 2007 and 2008, we published three papers (Jahandideh, 2007a, JTB, 246, 159-166; Jahandideh, 2007b, JTB, 248, 721-726; Jahandideh, 2008, JTB, 255, 113-118) investigating sequence and structural parameters in adaptation of proteins to low temperatures. Our studies revealed important features in cold-adaptation of proteins. Here, we calculate values of a new set of physico-chemical parameters and perform a comparative systematic analysis on a more comprehensive database of psychrophilic-mesophilic homologous protein pairs. Our obtained results confirm that psychrophilicity rules are not merely the inverse rules of thermostability; for instance, although contact order is reported as a key feature in thermostability, our results have shown no significant difference between contact orders of psychrophilic proteins compared to mesophilic proteins. We are optimistic that these findings would help future efforts to propose a strategy for designing cold-adapted proteins.

PCR amplification of the hrcV gene through specific primers for detecting Pseudomonas syringae pathovars.

Pseudomonas syringae pathovars are important pathogens among phytopathogenic bacteria causing a variety of diseases in plants. These pathogens can rapidly disseminate in a large area leading to infection and destruction of plants. To prevent the incidence of the bacteria, appropriate detection methods should be employed. Routinely serological tests, being time-consuming and costly, are exploited to detect these pathogens in plants, soil, water and other resources. Over the recent years, DNA-based detection approaches which are stable, rapid, specific and reliable have been developed and sequence analysis of various genes are widely utilized to identify different strains of P. syringe. However, the greatest limitation of these genes is inability to detect numerous pathovars of P. syringae. Herein, by using bioinformatic analysis, we found the hrcV gene located at pathogenicity islands of bacterial genome with the potential of being used as a new marker for phylogenetic detection of numerous pathovars of P. syringae. Following design of specific primers to hrcV, we amplified a 440 bp fragment. Of 13 assayed pathovars, 11 were detected. Also, through experimental procedures and bioinformatic analysis it was revealed that the designed primers have the capacity to detect 19 pathovars. Our findings suggest that hrcV could be used as a gene with the merit of detecting more pathovars of P. syringae in comparison with other genes used frequently for detection purposes.