Mitochondria targeted redox GFP reveals time and dose dependent onset and progression of mitochondrial oxidation with diverging cell death decisions during photodynamic therapy.

BACKGROUND: Photodynamic therapy (PDT) is a successful cancer treatment modality. In vitro, in vivo, and clinical studies with different photosensitizers reveal diverging cell fates, including apoptosis, necrosis, autophagy, and non-specific forms of cell death. The mode of action and efficacy of PDT is mediated through free radical generation and is highly dependent on diverse variables such as nature, dose, metabolism of photosensitizer, irradiation energy, and irradiation cycle. AIM: Discovery of newer photosensitizers and optimization of PDT approaches to achieve a clinically relevant form of cell death called apoptosis requires better in vitro real-time methods. Oxidative damage and mitochondrial permeabilization are critical signaling events involved in photodamage and apoptosis. Hence, mitochondrial damage detection is an appropriate target signaling for mechanistic evaluation of PDT. METHODOLOGY: We report mitochondria-targeted redox GFP expressing cells as a sensitive system to test and validate important variables of PDT using the photosensitizer 5-Aminolevulinic acid (5-ALA) as a model. An independent FRET-based caspase sensor cell was also used to study the impact of the photosensitizer dosage and irradiation duration on the mode of cell death. RESULTS: The study reveals that the cancer cells expressing mt-roGFP are extremely sensitive to monitor mitochondrial oxidation induced by PDT. The extent of mitochondrial redox changes induced by PDT can be determined using these sensor cells by real-time image-based approaches. These approaches provide sufficient temporal resolution that is required to fine-tune and optimize the PDT conditions. The degree of oxidation of the probe is highly dependent on the dosage of photosensitizer and duration of light irradiation, which determines the nature of cell death. A real-time caspase sensor probe further confirmed that the caspase-dependent and caspase-independent nature of cell death is in high correlation with the extent of mitochondrial oxidation. A condition that triggers rapid and extreme mito-oxidation seems to favor necrosis, while delayed and slowly progressing redox changes contribute to caspase-dependent apoptosis. CONCLUSION: The study confirms that temporal analysis of mitochondrial oxidation is a reliable biomarker for fine-tuning PDT conditions to achieve the desired outcome. This can be achieved using stable cancer cell lines expressing mitochondria-targeted roGFP by ratiometric imaging.

Oropharyngeal microbiome of an HIV-positive patient.

Studies on understanding the human microbiome continue to grow rapidly; nonetheless, reports on alterations in the microbiome post HIV infection are limited. Human microbiome is an aggregate of bacteria, fungi, viruses and archaea that have co-evolved with humans. These microbes have important roles in immune modulation, vitamin synthesis, metabolism etc. The human pharyngeal microbiome, which resides in the junction between digestive and respiratory tracts, might have a key role in the prevention of respiratory tract infections, akin to the actions of the intestinal microbiome against enteric infections. The respiratory tract is constantly exposed to various environmental and endogenous microbes; however, unlike other similar mucosal surfaces, there has been limited investigation of the microbiome of the respiratory tract. HIV infection is associated with alterations in the respiratory microbiome. The aim of this study was to use next-generation sequencing to determine the composition of the oropharyngeal microbiome in a HIV-positive individual. The bacterial composition was determined by illumina sequencing using MiSeq of partial 16S rRNA genes (V3-V4). A total of 3, 57,926 reads were analyzed. Overall, the genera Proteus, Enterococcus, Bacteroides, Prevotella and Clostridium were most prevalent bacterial populations in the oropharynx of an HIV positive patient.

Ameliorative effect of alkaloid extract of Cyclea peltata (Poir.) Hook. f. & Thoms. roots (ACP) on APAP/CCl4 induced liver toxicity in Wistar rats and in vitro free radical scavenging property.

OBJECTIVE: To evaluate the hepatoprotective and antioxidant properties of alkaloid extract of Cyclea peltata (C. peltata) against paracetamol/carbon tetra chloride induced liver damage in Wistar rats. METHODS: In vivo paracetamol/carbon tetrachloride induced liver damage in Wistar rats, in vitro free radical scavenging studies, HPTLC estimation of tetrandrine and direct analysis in real time- mass spectrometry of alkaloid extract of C. peltata were used for the validation. RESULTS: The results showed that pretreatment with alkaloid extract of C. peltata caused significant reduction of serum glutamate pyruvate transaminase, serum glutamate oxaloacetate transaminase, serum alkaline phosphatase, serum cholesterol, liver malondialdehyde levels. The reduced glutathione, catalase, superoxide dismutase levels in liver were increased with alkaloid extract of C. peltata treatment. These results were almost comparable to silymarin and normal control. Histopathological studies also substantiated the biochemical findings. The in vitro hydroxyl, superoxide and DPPH scavenging study of alkaloid extract of C. peltata showed significant free radical scavenging property. CONCLUSIONS: The hepatoprotective property of alkaloid extract of C. peltata against paracetamol/carbon tetrachloride may be due the synergistic action of alkaloids especially tetrandrine, fangchinoline through free radical scavenging and thus preventing oxidative stress.