Comparative study on the inactivation of MS2 and M13 bacteriophages using energetic femtosecond lasers

Femtosecond (fs) laser irradiation techniques are emerging tools for inactivating viruses that do not involve ionizing radiation. In this work, the inactivation of two bacteriophages representing protective capsids with different geometric constraints, that is, the near‐spherical MS2 (with a diameter of 27 nm) and the filamentous M13 (with a length of 880 nm) is compared using energetic visible and near‐infrared fs laser pulses with various energies, pulse durations, and exposure times. Intriguingly, the results show that inactivation using 400 nm lasers is substantially more efficient for MS2 compared to M13. In contrast, using 800 nm lasers, M13 was slightly more efficiently inactivated. For both viruses, the genome was exposed to a harmful environment upon fs‐laser irradiation. However, in addition to the protection of the genome, the metastable capsids differ in many properties required for stepwise cell entry that may explain their dissimilar behavior after (partial) disassembly. For MS2, the dominant mechanism of fs‐laser inactivation was the aggregation of the viral capsid proteins, whereas aggregation did not affect M13 inactivation, suggesting that the dominant mechanism of M13 inactivation was related to breaking of secondary protein links.     

The world distribution of the electrophoretic variants of the red cell enzyme esterase D.

The phenotypic variation in the esterase D phenotypes among 2,405 individuals in 14 samples from populations in Europe, Africa and Asia are reported. There exists a marked difference in esterase D allele frequencies in different continental regions. Comparison of the world population data so far available show that esterase D is another useful genetic parameter for the study of population diversity.     

Fast flow rate processes for purification of alkaline xylanase isoforms from Bacillus pumilus AJK and their biochemical characterization for industrial application purposes

This study shows the presence of five isozymic forms of alkaline xylanase from Bacillus pumilus using fast flow rate microfiltration, ultrafiltration, Q-sepharose, and phenyl sepharose chromatographic techniques. Polyacrylamide gel electrophoresis, high-performance liquid chromatography, and zymographic studies also revealed the purity of five isoforms of alkaline xylanases. Isoforms—X-I, X-III, and X-V exhibited optimum activity at pH 8.5, whereas X-II, X-IV showed maximum activity at pH 9. All isoforms were optimally active at temperature 55°C. Isoforms were found to be stable at pH 7–11, showed 92–100% residual activity after 3 hr, treatment time for most industrial applications. The isoforms retained nearly 80–86% residual activity after incubating at 45°C for 3 hr. Molecular weights of xylanase I–V, were 13.1, 15.3, 18.4, 20.1, and 21.0 kDa, respectively. Mg²⁺ ions were found to be potent activator for all isozymic forms. The Km and Vmax values of X-I, X-II, X-III, X-IV, and X-V were 6.71, 6.66, 7.14, 5.88, 6.25 mg/ml and 2,000, 1,695, 1,666.66, 1,428.57, and 1,408.45 IU/mg protein, respectively. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis revealed the monomeric nature of all isoforms. The low-molecular masses, significantly enhanced activity in the presence of industrially suitable—low cost activator, better stability of all isoforms at pH 7–11 and at higher temperature, also presence of multiple forms of alkaline xylanase, makes this enzyme suitable for textile–paper industries. This is also the first report mentioning the purification of five isozymic forms of alkaline xylanase using fast flow rate techniques.     

A versatile tool in controlling aggregation and Ag nanoparticles assisted in vitro folding of thermally denatured zDHFR

BackgroundProteins have tendency to form inactive aggregates at higher temperatures due to thermal instability. Maintenance of thermal stability is essential to gain the protein in sufficient quantity and biologically active form during their commercial production.MethodsBL21-DE3 Rosetta E. coli cells which contains plasmid pET43.1a vector was used for producing zDHFR protein commercially. The purification of N-terminal Histidine tagged zDHFR was performed by Immobilized Metal Ion chromatography (IMAC). Investigations were performed in existence and non existence of Silver nanoparticles (AgNPs). The inactivation kinetics of zDHFR in existence and non existence of AgNPs were monitored over a range of 40–80 °C as monitored by UV–Visible absorption spectroscopy.ResultsThe protein completely lost its activity at 55 °C. Kinetics of inactivated zDHFR follows first order model in presence and absence of AgNPs. Decrease in rate constant (k) values at respective temperatures depicts that AgNPs contribute in the thermostability of the protein. AgNPs also assists in regaining the activity of zDHFR protein.ConclusionsAgNPs helps in maintaining thermostability and reducing the aggregation propensity of zDHFR protein.General significanceResult explains that AgNPs are recommended as a valuable system in enhancing the industrial production of biologically active zDHFR protein which is an important component in folate cycle and essential for survival of cells and prevents the protein from being aggregated.     

Screening for natural inhibitors of human topoisomerases from medicinal plants with bio-affinity ultrafiltration and LC–MS

Phytochemistry Reviews - The continuing rise in cancer morbidity and mortality all over the world makes cancer the No. 2 cause of death in humans, posing a major public health challenge. Currently,...