Exploring recombinant secretory proteins from Mycobacterium tuberculosis to develop a serological platform for tuberculosis diagnosis.

The lack of a sensitive diagnostic tool for tuberculosis (TB) is the main reason for increasing cause of death in many developing countries. The routine diagnostic tests are either time-consuming or equivocal in terms of results. Hence, there is a need for quicker and accurate diagnostic tests. Certain studies have documented the usage of proteins secreted by Mycobacterium tuberculosis (MTB) in developing a sensitive tool for diagnosing TB. The study aimed to employ PPE41, MPT53, LPQH, CFP10, ESAT6 and TB18.5 proteins and analyze their usage as early diagnostic markers. The proteins were cloned, expressed, purified and applied in ELISA platforms in separate as well as combined systems to assess their early diagnostic features. The results of our study revealed that a cocktail of all six antigen combinations was identified in the maximum number of TB cases. Thus, proteins such as PPE41, MPT53, LPQH, CFP10, ESAT6, and TB18.5 incorporated detection tools could be optimized for an improvised early detection of MTB infections. Moreover, the results suggested that 95.7 % of the MTB-positive serum samples reacted with all the selected antigens of Mycobacterium tuberculosis, while the control serum samples did not react with those antigens. The hexavalent antigen system yielded a novel ELISA platform for better diagnosing MTB infections. Our study yielded a novel technology to diagnose TB, which warrants testing in clinical settings.

Molecular diversity of dengue virus serotypes 1-4 during an outbreak of acute dengue virus infection in Theni, India.

Background: Dengue fever (DF) is caused by an arthropod-borne dengue virus (DENV), has four serotypes and several genotypes. Although having clinical and epidemiological significance, the information on the circulating serotypes/genotypes is scarce in India. Materials and Methods: Blood specimens were collected from the patients suspected of DF and they are tested for DENV NS1 antigen and DENV IgM by ELISA. Antigen-positive samples were further serotyped by reverse transcriptase polymerase chain reaction. Representative samples from each serotype were sequenced to identify the genotypes. Results: All the four DENV serotypes were detected with the pre-dominance of DENV-1 (n = 49; 41.9%). Cases with multiple DENV serotype infections were also identified. Genotyping showed that DENV-1 belonging to genotype I, DENV-2 cosmopolitan (IV), DENV-3 genotype III and DENV-4 genotype I were active in the circulation during the outbreak in 2017. Conclusion: Our study documents the molecular characteristics of DENV circulating in our geographical locality. The detection of heterologous DENV serotypes highlights the importance of regular molecular monitoring for the early recognition of any switch in pre-dominant serotype.

DNA Vaccines - A Modern Gimmick or a Boon to Vaccinology?

The reports in 1993 that naked DNA encoding viral genes conferred protective immunity came as a surprise to most vaccinologists. This review analyses the expanding number of examples where plasmid DNA induces immune responses. Issues such as the type of immunity induced, mechanisms of immune protection, and how DNA vaccines compare with other approaches are emphasized. Additional issues discussed include the likely means by which DNA vaccines induce CTL, how the potency and type of immunity induced can be modified, and whether DNA vaccines represent a practical means of manipulating unwanted immune response occurring during immunoinflammatory diseases. It seems doubtful if DNA vaccines will replace currently effective vaccines, but they may prove useful for prophylactic use against some agents that at present lack an effective vaccine. DNA vaccines promise to be valuable to manipulate the immune response in situations where responses to agents are inappropriate or ineffective.

Rapid Kupffer cell death after intravenous injection of adenovirus vectors.

When adenovirus vectors are injected intravenously, they are quickly taken up by Kupffer cells in the liver. We report that this causes rapid necrosis of Kupffer cells in mice at doses of 10(11) particles/kg or higher. By 10 min after intravenous vector injection, Kupffer cells were permeable to propidium iodide and trypan blue. This coincided with a sharp rise in serum lactate dehydrogenase. Ultrastructural examination showed degeneration of Kupffer cells, including complete disappearance of chromatin by 1 h. After an initial intravenous injection of vector, dead Kupffer cells were unable to take up a second dose of vector, and hepatic transgene expression from the second dose was augmented. Death of Kupffer cells did not affect serum levels of IL-6 or IL-12. There was no immediate change in the number of Kupffer cells in the liver, but a significant decline was found by 4 h after injection of vector. Interestingly, substantial numbers of vector-containing Kupffer cells were found in pulmonary capillaries, indicating that they had been swept out of the liver. Together these results show that an intravenous injection of adenovirus vector causes synchronous and surprisingly rapid Kupffer cell death.