Impact of noncoding RNAs on cancer directed immune therapies: Now then and forever.

Accumulating evidence demonstrates that the host genome's epigenetic modifications are essential for living organisms to adapt to extreme conditions. DNA methylation, covalent modifications of histone and interassociation of noncoding RNAs facilitate the cellular manifestation of epigenetic changes in the genome. Out of various factors involved in the epigenetic programming of the host, noncoding RNAs (ncRNAs) such as microRNA (miRNA), long noncoding RNA (lncRNA), circular RNA, snoRNA and piRNA are new generation noncoding molecules that influence a variety of cellular processes like immunity, cellular differentiation and tumor development. During tumor development, temporal changes in miRNA/lncRNA rheostat influence sterile inflammatory responses accompanied by the changes in the carcinogenic signaling in the host. At the cellular level, this is manifested by the upregulation of inflammasome and inflammatory pathways, which promotes cancer-related inflammation. Given this, we discuss the potential of lncRNAs, miRNAs, circular RNA, snoRNA and piRNA in regulating inflammation and tumor development in the host.

A Prelude to Biogermylene Chemistry*.

The biological applications of germylenes remain unrealised owing to their unstable nature. We report the isolation of air-, water-, and culture-medium-stable germylene DPMGeOH (3; DPM=dipyrromethene ligand) and its potential biological application. Compound 3 exhibits antiproliferative effects comparable to that of cisplatin in human cancer cells. The cytotoxicity of compound 3 on normal epithelial cells is minimal and is similar to that of the currently used anticancer drugs. These findings provide a framework for a plethora of biological studies using germylenes and have important implications for low-valent main-group chemistry.

Antibacterial and cytocompatibility study of modified Ti6Al4V surfaces through thermal annealing.

Silver coating of different thicknesses ranging from 5 to 20 nm was deposited on the Ti6Al4V substrate using DC sputtering followed by thermal annealing at 750 °C for 15 min in an ambient environment. The surface topography and elemental composition of annealed samples were analyzed using different characterization techniques. The silver ions (Ag+) concentration released from the modified titanium surface was calculated through inductive coupled plasma mass spectroscopy (ICP-MS). The plate counting method was used to quantify the bacteria-killing potential of modified titanium surface against Escherichia coli (E. coli), Staphylococcus aureus (S. aureus), Fluoroquinolones-resistant Salmonella typhi (FRST) and Methicillin-resistant Staphylococcus aureus (MRSA) bacteria. The cell membrane integrity study of E. coli and S. aureus bacterium was done qualitatively using scanning electron microscopy and further confirmed with fluorescence microscopy. Due to thermal annealing, polygonal shaped oxide nanoparticles were formed on the titanium substrate. Moreover, the surface topography of modified titanium surface changes with the thickness of the silver film. In order to check the cytotoxic effect of modified titanium surface, mouse fibroblast cells (NIH3T3) were used for 3­(4,5­dimethylthiazol­2­yl)­2,5­diphenyltetrazolium bromide (MTT) assay. The limited (<35 ppb) Ag+ ion release was noticed for 15 nm silver film which has shown the good bactericidal property and significant growth of fibroblast cells. This study proposes a simple and efficient method to enhance the antibacterial property of Ti6Al4V surfaces to avoid implant-related infection.

The CpG dinucleotide content of the HIV-1 envelope gene may predict disease progression.

The clinical course of HIV-1 varies greatly among infected individuals. Despite extensive research, virus factors associated with slow-progression remain poorly understood. Identification of unique HIV-1 genomic signatures linked to slow-progression remains elusive. We investigated CpG dinucleotide content in HIV-1 envelope gene as a potential virus factor in disease progression. We analysed 1808 HIV-1 envelope gene sequences from three independent longitudinal studies; this included 1280 sequences from twelve typical-progressors and 528 sequences from six slow-progressors. Relative abundance of CpG dinucleotides and relative synonymous codon usage (RSCU) for CpG-containing codons among HIV-1 envelope gene sequences from typical-progressors and slow-progressors were analysed. HIV-1 envelope gene sequences from slow-progressors have high-CpG dinucleotide content and increased number of CpG-containing codons as compared to typical-progressors. Our findings suggest that observed differences in CpG-content between typical-progressors and slow-progressors is not explained by differences in the mononucleotide content. Our results also highlight that the high-CpG content in HIV-1 envelope gene from slow-progressors is observed immediately after seroconversion. Thus CpG dinucleotide content of HIV-1 envelope gene is a potential virus-related factor that is linked to disease progression. The CpG dinucleotide content of HIV-1 envelope gene may help predict HIV-1 disease progression at early stages after seroconversion.

Association of DNA repair and cell cycle gene variations with breast cancer risk in Northeast Indian population: a multiple interaction analysis.

Polymorphisms in DNA repair and cell cycle genes contribute to increased breast cancer (BC) risk. Their association and interaction in relation to betel quid and tobacco chewing habits need exhaustive multi-analytical investigation to explain BC predisposition due to DNA damage. Polymorphism in TP53-72Arg>Pro, RAD51-135G>C, BRCA2, and CCND1-G870A were examined in 204 BC cases and 217 controls from Northeast Indian population. Multifaceted analytic approaches were used to explore relationships between polymorphisms, tobacco history, and BC susceptibility. Betel quid chewing was identified as the predominant risk factor. CCND-AA and dominant model showed protection towards BC in betel quid chewer (BQC) [(0.28 (0.10-0.77), 0.01 and 0.32 (0.12-0.81), 0.01)] and non-betel quid chewers (NBQC) [(0.26 (0.09-0.78), 0.01 and 0.37 (0.16-0.87), 0.02)]. TP53-Pro/Pro genotype showed protection towards BC in NBQC (0.29 (0.10-0.81), p=0.01) and (0.51 (0.32-0.80), p=0.003, respectively). RAD51-C allele was associated with BC risk (2.03 (1.26-3.30) 0.002) in BQC. Two BQC cases had BRCA2 8415G>T:K2729N mutation in Exon18. MDR analysis showed best four locus model with TBA 0.6765 (0.005) and CVC of 10/10 in NBQC. Interaction diagram concurred the interactions between TP53 and RAD51 (1.32 %) with independent effect (1.89 %) of CCND1in NBQC. In CART analysis, BQC with CCND1 GG genotype were at risk (OR=33.0; 95 % CI=6.08-179.07), p<0.001) followed by combination of BQC, CCND1, No-Smk, and Alc (OR=42.00; 95 % CI=5.11-345.11, p<0.001). Risk was also observed in BQC, CCND1, No-Smk, Non-Alc, and TP53 combination (OR=14.84; 95 % CI=3.13-70.34, p<0.001) and BQC, CCND1, No-Smk, Non-Alc, TP53 (OR=9.40; 95 % CI=1.99-44.34, p<0.001). NBQC group showed risk with combination of NBQC and TP53 (OR=5.54; 95 % CI=1.11-27.42, p=0.03). Genetic variants in DNA repair and cell cycle genes contribute to BC risk through gene-gene and gene-environmental interactions.