Muhammad Shahbaz Aslam

Phytochemical, toxicological and antimicrobial evaluation of lawsonia inermis extracts against clinical isolates of pathogenic bacteria

BackgroundThe emerging resistance of pathogen against the currently available antimicrobial agents demands the search of new antimicrobial agents. The use of medicinal plants as natural substitute is the paramount area of research to overwhelm the drug resistance of infectious agents. Scientists have not made enough effort on the evaluation of safety of medicinal plant yet.MethodsIn the present study antimicrobial activity of Lawsonia inermis is investigated against clinical isolates of seven bacteria including four Gram negative (Escherichia coli, Salmonella typhi, Klebsiella spp., Shigella sonnei) and three Gram positive (Bacillus subtilis, Staphylococcus aureus, Staphylococcus epidermidis) using disc diffusion method. Four types of Lawsonia inermis extracts were prepared using methanol, chloroform, acetone and water as extraction solvents, while DMSO (Dimethyl sulfoxide) and water as dissolution solvents. The rate and extent of bacterial killing was estimated by time-kill kinetic assay at 1× MIC of each bacterial isolate. The overall safety of Lawsonia inermis extracts was assessed in mice.ResultsLawsonia inermis displayed noteworthy antimicrobial activity against both gram positive and gram negative bacterial strains used in the study. The minimum value of MIC for different bacterial strains ranged from 2.31 mg/ml to 9.27 mg/ml. At 1x MIC of each bacterial isolate, 3log10 decrease in CFU was recorded after 6 hours of drug exposure and no growth was observed in almost all tested bacteria after 24 hours of exposure. No sign of toxidrome were observed during in vivo toxicity evaluation in mice at 300 mg/kg concentration.ConclusionIn conclusion, the present study provides the scientific rational for medicinal use of Lawsonia inermis. The use of Lawsonia inermis extracts is of great significance as substitute antimicrobial agent in therapeutics.

Starvation based differential chemotherapy: a novel approach for cancer treatment.

Cancer patients undergoing chemotherapy treatment are advised to increase food intake to overcome the therapy-induced side effects, and weight loss. Dietary restriction is known to slow down the aging process and hence reduce age-related diseases such as cancer. Fasting or short-term starvation is more effective than dietary restriction to prevent cancer growth since starved cells switch off signals for growth and reproduction and enter a protective mode, while cancer cells, being mutated, are not sensitized by any external growth signals and are not protected against any stress. This phenomenon is known as differential stress resistance (DSR). Nutrient signaling pathways involving growth hormone/insulin-like growth factor-1 axis and its downstream effectors, play a key role in DSR in response to starvation controlling the other cell maintenance systems, such as autophagy and apoptosis, that are related to the tumorigenesis. Yeast cells lacking these effectors are better protected against oxidative stress compared to normal cells. In the same way, starvation protects many cell lines and mice against high-dose chemotherapeutic drugs. According to a series of studies, fasting results in overall reduction in chemotherapy side effects in cancer patients. Data shows that starvation-dependent differential chemotherapy is safe, feasible and effective in cancer treatment, but the possible side effects of starvation limit its efficacy. However, further studies and clinical trials may result in its implementation in cancer treatment.

Anticancer medicines (Doxorubicin and methotrexate) conjugated with magnetic nanoparticles for targeting drug delivery through iron.

The uptake of iron is increased by cancer cells. Iron magnetic nanoparticles (MNP) can be used as a nanovehicle for immobilization of anticancer medicines and to integrate them at a target site. The anticancer medicines doxorubicin (DOX) and methotrexate (MTX) were immobilized separately and in combination onto MNP by a glutaraldehyde activation method and confirmed by magnetic nanoparticles linked immunosorbent assay (MagLISA) and Fourier-transform infrared (FTIR) spectroscopy. The phenol peaks of DOX and MTX at 2896.6 cm−1 to 2912.5 cm−1 in FTIR spectra of immobilized medicines indicated the conjugation. Affinity-purified anti-DOX and anti-MTX antibodies were used to evaluate the coupling of DOX and MTX onto MNP, and the binding was found 34.6% to 37.2% and 51.8% to 54.3% separately, respectively. The immobilization of DOX and MTX in combination onto MNP was 18% and 27%, respectively. HeLa and B cells were cultured with DOX-MNP, MTX-MNP, and DOX-MNP-MTX separately, and MagLISA indicated that the binding of DOX-MNP/MTX-MNP was 41.5% to 45% with HeLa cells and 20% to 26% with B cells. No significant difference was observed in binding of DOX-MNP-MTX with HeLa and B cells. Results also indicated that the release of medicines at pH 5.0 is more (39% to 44%) than at pH 7.4 (3.7% to 10.2%). Sixteen to 22% more killing effect was observed on HeLa cells than on B cells. In immunohistochemical staining, more deposition of brown color on HeLa cells than on B cells may be due to more expression of iron-binding sites on cancer cells. The dual property of MNP can be used for binding of medicines and for targeting drug delivery.

Cell-Free DNA Quantification and Methylation Status of DCC Gene as Predictive Diagnostic Biomarkers of Lung Cancer in Patients Reported at Gulab Devi Chest Hospital, Lahore:

The worldwide high mortality rate of lung cancer could be reduced significantly by its noninvasive early detection. The quantitative analysis of cell-free circulating DNA in plasma presents a potential noninvasive approach for liquid biopsy of tumor. In this study, real-time polymerase chain reaction–based approach was used to quantify free circulating DNA in plasma. The concentration of free circulating DNA was checked using human telomerase reverse transcriptase gene as marker, and amplification status of oncogene RAC-β serine/threonine protein kinase along with the DNA methylation status of tumor suppressor gene (deleted in colorectal cancer) was assessed. The concentration of free circulating DNA in patients with lung cancer (22.8 ng/mL) was found approximately 6 times above than the value detected in controls (2.8 ng/mL). Considerable variation in the AKT2 copy number was observed in patients with lung cancer and controls (P < .000). Aberrant methylation of the deleted in colorectal cancer promoter was found to be highly specific (100%), as none of the control plasma samples showed aberrant methylation. The quantification of free circulating DNA along with determination of AKT2 amplification and deleted in colorectal cancer promoter methylation status appeared promising to differentiate patients with lung cancer from healthy individuals.

Use of Moringa oleifera Flower Pod Extract as Natural Preservative and Development of SCAR Marker for Its DNA Based Identification

The use of Moringa oleifera as natural food preservative has been evaluated in the present study. In addition, for quality assurance, the study has also been focused on the shelf life of product to authenticate the identification of plant by development of DNA based marker. Among the different extracts prepared from flower pods of Moringa oleifera, methanol and aqueous extract exhibited high antibacterial and antioxidant activity, respectively. The high phenolic contents (53.5 ± 0.169 mg GAE/g) and flavonoid contents (10.9 ± 0.094 mg QE/g) were also recorded in methanol and aqueous extract, respectively. Due to instability of bioactive compounds in aqueous extract, methanol extract is considered as potent natural preservative. The shelf life of methanol extract was observed for two months at 4°C under dark conditions. The developed SCAR primers (MOF217/317/MOR317) specifically amplified a fragment of 317 bp from DNA of Moringa oleifera samples collected from different regions of Punjab province of Pakistan. The methanol extract of Moringa oleifera flower pods has great potential to be used as natural preservative and nutraceutical in food industry.

SHORT COMMUNICATION: Identification and Purification of Antigenic 34 kDa Outer Membrane Protein of Salmonella Typhi

BACKGROUND Salmonella Typhi is a pathogenic bacterium that causes a number of infectious diseases such as gastroenteritis and typhoid fever. In this study, an antigenic (34 kDa) protein was identified, purified, and characterized from outer membrane of Salmonella typhi. METHODS Immunoblot analysis was used to screen antigenic proteins from outer membrane of Salmonella Typhi. Proteins from outer membrane were isolated and resolved on SDS-PAGE. In immunoblot analysis, four proteins with the following molecular weights of 60 kDa, 54 kDa, 34 kDa, and 26 kDa were identified as highly antigenic against the serum of patients suffering from typhoid fever. One of these outer membrane proteins, with a molecular mass of 34 kDa, was selected for this study. The 34 kDa protein was purified and characterized by a combination of anion exchange chromatography and gel permeation chromatography. The molecular weight of 34 kDa was determined using SDS-PAGE electrophoresis. The antigenic nature of the purified 34 kDa protein was determined by ELISA against serum proteins of patients suffering from typhoid fever and finally confirmed by immunoblot analysis. Antisera against the purified 34 kDa outer membrane protein of Salmonella typhi was produced and was used to recognize the epitope on the surface of an intact Salmonella typhi bacterium. RESULTS The antigenic 34 kDa protein from the outer membrane of Salmonella typhi was identified, purified and characterized. The antigenecity of purified protein was confirmed by using antibodies present in serum of patient suffering from typhoid fever. It was also observed that antibody against 34 kDa outer membrane protein recognizes intact Salmonella typhi cells. CONCLUSIONS It is established from the study that 34 kDa protein is antigenic in nature and antibody against this protein can also recognize epitopes on intact Salmonella typhi cells. Furthermore, this protein can be a good source material to produce vaccine against typhoid fever.