Epidemiological, clinical, and laboratory characteristics of human granulocytic anaplasmosis in North India.

Human granulocytic anaplasmosis (HGA) is an emerging, rickettsial tick-borne disease caused by Anaplasma phagocytophilum. Sero-epidemiological data demonstrate that this pathogen has a worldwide distribution. The diagnosis of HGA requires a high index of clinical suspicion, even in endemic areas. In recent years, HGA has increasingly been reported from Asia and described in China, Japan, and Korea. We serologically and molecularly screened 467 patients with clinical suspicion of Anaplasmosis. The present study describes the epidemiology, clinical, and laboratory details of 6 confirmed and 43 probable cases of human granulocytic anaplasmosis. One of the HGA patients developed secondary invasive opportunistic Aspergillus fumigatus and Acinetobacter baumanii infection during the illness, which resulted in a fatal infection. The HGA patients without severe complications had excellent treatment responses to doxycycline. The emergence of this newly recognized tick-borne zoonotic HGA in North India is a significant concern for public health and is likely underdiagnosed, underreported, and untreated. Hence, it is also essential to establish a well-coordinated system for actively conducting tick surveillance, especially in the forested areas of the country.IMPORTANCEThe results of the present study show the clinical and laboratory evidence of autochthonous cases of Anaplasma phagocytophilum in North India. The results suggest the possibility of underdiagnosis of HGA in this geographical area. One of the HGA patients developed secondary invasive opportunistic Aspergillus fumigatus and Acinetobacter baumanii infection during the illness, which resulted in a fatal infection.

A mechanistic insight into the potential anti-cancerous property of Nigella sativa on breast cancer through micro-RNA regulation: An in vitro & in vivo study.

Cancer continues to threat mortal alongside scientific community with burgeoning grasp. Most efforts directed to tame Cancer such as radiotherapy or chemotherapy, all came at a cost of severe side effects. The plant derived bioactive compounds on the other hand carries an inevitable advantage of being safer, bioavailable & less toxic compared to contemporary chemotherapeutics. Our strategic approach employed solvent extraction of Black Seed Oil (BSO) to highlight the orchestrated use of its oil soluble phytochemicals - Thymoquinone, Carvacrol & Trans-Anethole when used in cohort. These anti-cancer agents in unbelievably modest amounts present in BSO shows better potential to delineate migratory properties in breast cancer cells as compared to when treated individually. BSO was also observed to have apoptotic calibre when investigated in MDA-MB-231 and MCF-7 cell lines. We performed chemical characterization of the individual phytochemical as well as the oil in-whole to demonstrate the bioactive oil-soluble entities present in whole extract. BSO was observed to have significant anti-cancerous properties in cumulative proportion that is reportedly higher than the individual three components. Besides, this study also reports micro-RNA regulation on BSO administration, thereby playing a pivotal role in breast cancer alleviation. Thus, synergistic action of the integrants serves better combat force against breast cancer in the form of whole extract, hence aiming at a more lucrative paradigm while significantly regulating microRNAs associated with breast cancer migration and apoptosis.

Unfolding of Imminent Bio-Signatures in the Prognosis of Thyroid Cancer; The Emergence of Estrogen Related Receptor Gamma (ERRγ) as a Hurricane.

Thyroid cancer's incidence has increased by leaps and bounds over the last years and accounts for 2.8% of new cases of cancers. This increasing bar is partially assisted by enormous screening to understand the sub-clinical status. Advanced tumor growth is the leading cause of thyroid cancer-associated death. However, the complete understanding of the underlying cause is still to be disclosed. The updated clinical assessment evidenced a few major oncogenes viz. RAS, BRAF, and RET as key drivers in the development and progression of thyroid cancer. The BRAF mutation, a major cause of aggressive tumor type in papillary thyroid carcinoma, is frequently reported. The characteristic oncogenic changes imply thyroid cancer to be clinically an ideal model for targeted therapy against RET, RAS, and BRAF mutation. Though the sensitive biochemical marker assay has been improvised, the diagnosis of thyroid follicular neoplasms is still a big challenge as the biopsy aspiration cannot define the nature of the tumor in 30% of the cases. The main hurdle is assisted distinction between follicular thyroid lesions. The discrimination between follicular thyroid adenomas and carcinomas is histologically accomplished. This strictly necessitates the identification of sensitive diagnostic/prognostic markers to mitigate the risk of thyroid cancer and to avoid the unnecessary hurdles of biopsy and surgery. An array of prognostic biomarkers is being used for the diagnosis of thyroid cancer. However, Estrogen Related Receptor Gamma (ERRγ) is setting a new benchmark among the clinical biomarkers. The dramatic expression of ERRγ in thyroid cancer enables itself not only to serve as a characteristic diagnostic marker but also as a therapeutic target. Recently, we have reported that ERRγ is upregulated in 96 papillary thyroid cancer (PTC) and 26 poorly differentiated/ anaplastic thyroid cancer (ATC) samples. Various synthetic ERRγ inverse agonists viz. GSK5182, DN200434, and 24e are fully proved to modulate ERRγ expression in ATC to attain partial cure. If this finding can be assayed on a larger scale the evaluation of this marker may be warranted and informative. This review article highlights the ascending sheds of clinical biomarkers of thyroid cancer. This also reveals the clinical importance of ERRγ as an evolving diagnostic and therapeutic target in thyroid cancer.

Unsung versatility of elastin-like polypeptide inspired spheroid fabrication: A review.

Lately, 3D cell culture technique has gained a lot of appreciation as a research model. Augmented with technological advancements, the area of 3D cell culture is growing rapidly with a diverse array of scaffolds being tested. This is especially the case for spheroid cultures. The culture of cells as spheroids provides opportunities for unanticipated vision into biological phenomena with its application to drug discovery, metabolic profiling, stem cell research as well as tumor, and disease biology. Spheroid fabrication techniques are broadly categorised into matrix-dependent and matrix-independent techniques. While there is a profusion of spheroid fabrication substrates with substantial biological relevance, an economical, modular, and bio-compatible substrate for high throughput production of spheroids is lacking. In this review, we posit the prospects of elastin-like polypeptides (ELPs) as a broad-spectrum spheroid fabrication platform. Elastin-like polypeptides are nature inspired, size-tunable genetically engineered polymers with wide applicability in various arena of biological considerations, has been employed for spheroid culture with profound utility. The technology offers a cheap, high-throughput, reproducible alternative for spheroid culture with exquisite adaptability. Here, we will brief the applicability of 3D cultures as compared to 2D cultures with spheroids being the focal point of the review. Common approaches to spheroid fabrication are discussed with existential limitations. Finally, the versatility of elastin-like polypeptide inspired substrates for spheroid culture has been discussed.

Unlocking the hidden variation from wild repository for accelerating genetic gain in legumes.

The fluctuating climates, rising human population, and deteriorating arable lands necessitate sustainable crops to fulfil global food requirements. In the countryside, legumes with intriguing but enigmatic nitrogen-fixing abilities and thriving in harsh climatic conditions promise future food security. However, breaking the yield plateau and achieving higher genetic gain are the unsolved problems of legume improvement. Present study gives emphasis on 15 important legume crops, i.e., chickpea, pigeonpea, soybean, groundnut, lentil, common bean, faba bean, cowpea, lupin, pea, green gram, back gram, horse gram, moth bean, rice bean, and some forage legumes. We have given an overview of the world and India's area, production, and productivity trends for all legume crops from 1961 to 2020. Our review article investigates the importance of gene pools and wild relatives in broadening the genetic base of legumes through pre-breeding and alien gene introgression. We have also discussed the importance of integrating genomics, phenomics, speed breeding, genetic engineering and genome editing tools in legume improvement programmes. Overall, legume breeding may undergo a paradigm shift once genomics and conventional breeding are integrated in the near future.

Genome wide association studies for acid phosphatase activity at varying phosphorous levels in Brassica juncea L.

Acid phosphatases (Apases) are an important group of enzymes that hydrolyze soil and plant phosphoesters and anhydrides to release Pi (inorganic phosphate) for plant acquisition. Their activity is strongly correlated to the phosphorus use efficiency (PUE) of plants. Indian mustard (Brassica juncea L. Czern & Coss) is a major oilseed crop that also provides protein for the animal feed industry. It exhibits low PUE. Understanding the genetics of PUE and its component traits, especially Apase activity, will help to reduce Pi fertilizer application in the crop. In the present study, we evaluated 280 genotypes of the diversity fixed foundation set of Indian mustard for Apase activity in the root (RApase) and leaf (LApase) tissues at three- low (5µM), normal (250µM) and high (1mM) Pi levels in a hydroponic system. Substantial effects of genotype and Pi level were observed for Apase activity in both tissues of the evaluated lines. Low Pi stress induced higher mean RApase and LApase activities. However, mean LApase activity was relatively more than mean RApase at all three Pi levels. JM06016, IM70 and Kranti were identified as promising genotypes with higher LApase activity and increased R/S at low Pi. Genome-wide association study revealed 10 and 4 genomic regions associated with RApase and LApase, respectively. Annotation of genomic regions in the vicinity of peak associated SNPs allowed prediction of 15 candidates, including genes encoding different family members of the acid phosphatase such as PAP10 (purple acid phosphatase 10), PAP16, PNP (polynucleotide phosphorylase) and AT5G51260 (HAD superfamily gene, subfamily IIIB acid phosphatase) genes. Our studies provide an understanding of molecular mechanism of the Apase response of B. juncea at varying Pi levels. The identified SNPs and candidate genes will support marker-assisted breeding program for improving PUE in Indian mustard. This will redeem the crop with enhanced productivity under restricted Pi reserves and degrading agro-environments.

A natural derivative from ethnomedicinal mushroom potentiates apoptosis, autophagy and attenuates cell migration, via fine tuning the Akt signaling in human lung adenocarcinoma cells (A549).

Although comprehensive exertions have been made in late decades for treating advanced lung cancer with inclusive therapies but efficient anti-lung cancer therapeutics are statically inadequate in the clinics. Hence, compelling novel anti-lung cancer drugs are considerably desired. This backdrop enticed us to unveil anticancer efficacy of astrakurkurol, derivative of wild edible mushroom against lung cancer, whose effects have not yet been described. Mechanistic analysis disclosed that sensitizing effect of astrakurkurol is due to cell cycle arrest at G0/G1 phase, increased level of Fas, FADD, decreased ratio of Bax/Bcl-2, and increased cleaved form of caspase 9, 8, and 3. Apart from the induction of apoptosis, it was demonstrated for the first time that astrakurkurol induced an autophagic response as evidenced by the development of acidic vesicular organelles (AVOs) with up-regulation of beclin-1, Atg7, and downregulated p62. Apoptosis and autophagy can be sparked by the same stimuli, which was as evident from the astrakurkurol-induced inactivation of PI3K/AKT signaling. The thorough scanning of the mechanism of crosstalk between apoptosis and autophagy is requisite for prosperous anticancer remedy. Triterpenoid has evidently intensified cytotoxicity, induced apoptosis and autophagy on A549 cells. Besides astrakurkurol could also curb migration and regress the size of tumor in ex ovo xenograft model. All these findings put forth astrakurkurol as a convincing novel anti-cancer agent, for scrutinizing the lung cancer therapies and as a robust contender for future in vitro and in vivo analysis.

Delivery of gefitinib in synergism with thymoquinone via transferrin-conjugated nanoparticle sensitizes gefitinib-resistant non-small cell lung carcinoma to control metastasis and stemness.

Epidermal growth factor receptor (EGFR) normally over-expresses in non-small cell lung cancer (NSCLC) cells. Its mutations act as oncogenic drivers in the cellular signal transduction pathway, and induce the downstream activation of numerous key cellular events involved in cellular proliferation and survival. EGFR tyrosine kinase inhibitors (EGFR-TK inhibitors), such as gefitinib and erlotinib, have been used for a long time in the treatment of NSCLC. However, they fail to overcome the EGFR-TK mutation due to the acquisition of drug resistance. It is strongly believed that the epithelial-to-mesenchymal transition (EMT) is a key player for acquired resistance and consequent limitation of the clinical efficiency of EGFR-TKIs. Therefore, a new strategy needs to be developed to overcome the resistance in NSCLC. In this current study, we have disclosed for the first time the efficiency of transferrin-modified PLGA-thymoquinone-nanoparticles in combination with gefitinib (NP-dual-1, NP-dual-2 and NP-dual-3) towards gefitinib-resistant A549 cells. The gefitinib-resistant A549 cells (A549/GR) showed 12.3-fold more resistance to gefitinib in comparison to non-resistant A549 cells. The phenotypic alteration resembling spindle-cell shape and increased pseudopodia integuments featured the EMT phenomena in A549/GR cells. EMT in A549/GR was later coupled with the loss of Ecad and expansion of Ncad, along with upregulated vimentin expression, as compared to the control A549 cells. Moreover, the invasive nature and migration potential are more amplified in A549/GR cells. Pre-incubation of A549 cells with TGFß1 also initiated EMT, leading to drug resistance. Conversely, treatment of A549 or A549/GR cells with NP-dual-3 effectively retrieved the sensitivity to gefitinib, restricted the EMT phenomenon, and impaired the TGFß1-induced EMT. On unveiling the underlying mechanism of therapeutic action, we found that STAT3 and miR-21 were individually overexpressed in the A549/GR cells by transfection, and followed by treatment with NP-dual-3. Simultaneously, NP-dual-3 fragmented HIF1-α induced EMT in A549/GR cells and reduced the CSCs markers, viz., Oct-4, Sox-2, Nanog, and Aldh1. These data are self-sufficient to suggest that NP-dual-3 re-sensitizes the drug-resistant A549/GR cells to gefitinib, possibly by retrieving MET phenomena via modulation of STAT3/mir-21/Akt/PTEN/HIF1-α axis. Thus, TQ nanoparticles combined with TKI gefitinib may provide an effective platform to treat NSCLC.

Delivery of novel coumarin-dihydropyrimidinone conjugates through mixed polymeric nanoparticles to potentiate therapeutic efficacy against triple-negative breast cancer.

To date, most of the accessible therapeutic options are virtually non-responsive towards triple-negative breast cancer (TNBC) due to its highly aggressive and metastatic nature. Interestingly, chemotherapy reacts soundly in many TNBC cases compared to other types of breast cancer. However, the side effects of many chemotherapeutic agents are still under cross-examination, and thus prohibit their extensive uses. In this present study, we have developed a series of coumarin-dihydropyrimidinone conjugates (CDHPs) and subsequently their poly(lactic-co-glycolic acid) (PLGA)-PEG4000 mixed copolymer nanoparticles as excellent chemotherapeutic nanomedicine to control TNBC. Among all the synthesized CDHPs, CDHP-4 (prepared by the combination of EDCO with 3,4-difluorobenzaldehyde) showed excellent therapeutic effect on a wide variety of cancer cell lines, including TNBC. Besides, it can control the metastasis and stemness property of TNBC. Furthermore, the nano-encapsulation of CDHP-4 in a mixed polymer nanoparticle system (CDHP-4@PP-NPs) and simultaneous delivery showed much improved therapeutic efficacy at a much lower dose, and almost negligible side effects in normal healthy cells or organs. The effectiveness of the present therapeutic agent was observed both in intravenous and oral mode of administration in in vivo experiments. Moreover, on elucidating the molecular mechanism, we found that CDHP-4@PP-NPs could exhibit apoptotic, anti-migratory, as well as anti-stemness activity against TNBC cell lines through the downregulation of miR-138. We validated our findings in MDA-MB-231 xenograft chick embryos, as well as in 4T1-induced mammary tumor-bearing BALB/c mice models, and studied the bio-distribution of CDHP-4@PP-NPs on the basis of the photoluminescence property of nanoparticles. Our recent study, hence for the first time, unravels the synthesis of CDHP-4@PP-NPs and the molecular mechanism behind the anti-migration, anti-stemness and anti-tumor efficacy of the nanoparticles against the TNBC cells through the miR-138/p65/TUSC2 axis.

Hyaluronic acid engrafted metformin loaded graphene oxide nanoparticle as CD44 targeted anti-cancer therapy for triple negative breast cancer.

BACKGROUND: Triple negative breast cancer (TNBC) is the most aggressive form of breast cancer with limited treatment modalities. It is associated with high propensity of cancer recurrence. METHODS: UV Spectroscopy, FTIR, DLS, Zeta potential, TEM and SEM were employed to characterize nanoparticles. MTT assay, Wound healing assay, SEM, Immunocytochemistry analysis, Western blot, RT-PCR, mammosphere formation assay were employed to study apoptosis, cell migration and stemness. Tumor regression was studied in chick embryo xenograft and BALB/c mice model. RESULTS: Hylaluronic acid engrafted metformin loaded graphene oxide (HA-GO-Met) nanoparticles exhibited an anti-cancer efficacy at much lower dosage as compared to metformin alone. HA-GO-Met nanoparticles induced apoptosis and inhibited cell migration of TNBC cells by targeting miR-10b/PTEN axis via NFkB-p65. Upregulation of PTEN affected pAKT(473) expression that induced apoptosis. Cell migration was inhibited by reduction of pFAK/integrinß1 expressions. Treatment inhibited epithelial mesenchymal transition (EMT) and reduced stemness as evident from the increase in E-cadherin expression, inhibition of mammosphere formation and low expression levels of stemness markers including nanog, oct4 and sox2 as compared to control. Moreover, tumor regression was studied in chick embryo xenograft and BALB/c mice model. HA-GO-Met nanoparticle treatment reduced tumor load and nullified toxicity in peripheral organs imparted by tumor. CONCLUSIONS: HA-GO-Met nanoparticles exhibited an enormous anti-cancer efficacy in TNBC in vitro and in vivo. GENERAL SIGNIFICANCE: HA-GO-Met nanoparticles induced apoptosis and attenuated cell migration in TNBC. It nullified overall toxicity imparted by tumor load. It inhibited EMT and reduced stemness and thereby addressed the issue of cancer recurrence.

Combinatorial therapy of Thymoquinone and Emodin synergistically enhances apoptosis, attenuates cell migration and reduces stemness efficiently in breast cancer.

BACKGROUND: Breast cancer intimidates the contemporary medical advances, attempting to revolutionize cancer therapeutics. While patients suffering an advanced breast cancer are dependent on mono drugs, yet the build out of resistance leading to treatment fails has become inevitable. METHODS: Cell viability Assay with MTT revealed the "IC50" concentrations of the drugs in both cancer as well as PBMC. Cell cycle arrest, flow cytometric ROS analysis & apoptosis evaluation pointed out the efficacy of the dual drug. Wound Healing, Transwell Migration & Immunocytochemistry indicated anti-migratory potential of TQ-Emo while expression patterns of Cl-Cas3, p53, Bax, Bcl2 & the stemness markers further vouched the potential of the combinatorial drug. Furthermore, validation of tumor inhibitory effect was earned by an ex-ovo xenograft model. RESULTS: Dual dosage enhanced apoptosis through ROS generation, anti- migratory effect by targeting FAK &Integrins, displaying effective stemness control by assessing regulatory proteins- Oct4, Sox2, Nanog, ALDH1/2. Ex-ovo xenograft model validated tumor regression. Our study thereby deals with devastating effects of cancer drug resistance while trying to abate enhanced migratory potential & stemness, utilizing the synergism of the combinable therapy. CONCLUSION: TQ/Emo inhibited breast cancer proliferation synergistically while enhancing cytotoxicity, inducing apoptosis on MCF-7 cells while curbing migration & stemness. GENERAL SIGNIFICANCE: Employment of the combinatorial phytochemicals, Thymoquinone & Emodin attempted to achieve deliverables like reduced cellular toxicity, drug resistance, anti-migratory potency & stemness. Besides, decreased p-FAK expression or regression in Mammosphere & tumor size in ex-ovo xenograft model is indicative of the better anti-tumorigenic potential of the dual formulation.

Delivery of dual miRNA through CD44-targeted mesoporous silica nanoparticles for enhanced and effective triple-negative breast cancer therapy.

The development of new therapeutic strategies to target triple-negative breast cancer (TNBC) is in much demand to overcome the roadblocks associated with the existing treatment procedures. In this regard, therapies targeting the CD44 receptor have drawn attention for more than a decade. MicroRNAs (miRNAs) modulate post-transcriptional gene regulation and thus, the correction of specific miRNA alterations using miRNA mimics or antagomiRs is an emerging strategy to normalize the genetic regulation in the tumor microenvironment. It has been acknowledged that miR-34a is downregulated and miR-10b is upregulated in TNBC, which promotes tumorigenesis and metastatic dissemination. However, there are a few barriers related to miRNA delivery. Herein, we have introduced tailored mesoporous silica nanoparticles (MSNs) for the co-delivery of miR-34a-mimic and antisense-miR-10b. MSN was functionalized with a cationic basic side chain and then loaded with the dual combination to overexpress miR-34a and downregulate miR-10b simultaneously. Finally, the loaded MSNs were coated with an hyaluronic acid-appended PEG-PLGA polymer for specific targeting. The cellular uptake, release profile, and subsequent effect in TNBC cells were evaluated. In vitro and in vivo studies demonstrated high specificity in TNBC tumor targeting, leading to efficient tumor growth inhibition as well as the retardation of metastasis, which affirmed the clinical application potential of the system.

Small-Molecule Probe for Sensing Serum Albumin with Consequential Self-Assembly as a Fluorescent Organic Nanoparticle for Bioimaging and Drug-Delivery Applications.

The recognition of a specific protein in blood serum amidst similar proteins is a challenging and vital endeavor in clinical diagnostics. Herein, we have described a small-molecule probe (DFPAC-OH) that can induce self-assembly of human serum albumin (HSA) and bovine serum albumin (BSA) to generate a highly sustainable fluorescent organic nanoparticle (NP), useful for imaging and in vitro drug-delivery applications. In the midst of similar proteins, DFPAC-OH selectively binds in a noncovalent manner to serum albumin. The specific binding tailors the fluorescence properties of DFPAC-OH. The lowest detection limit for BSA is 47 nM with a binding constant of 1.03 × 105 M-1. The probe can efficiently detect HSA in an artificial urine sample. Furthermore, the subsequent bovine albumin self-assembled nanoparticle (DFPAC-OH@BSA-NPs) displays a strong emission at 580 nm both in solution and in solid state. The nanoparticle is highly stable over a long pH range, covering the physiologic pH, and shows an excellent bioavailability to be used for sustainable cell imaging and drug-delivery applications. In addition, the cellular internalization and the pH-responsive drug-release behavior of a hydrophobic drug thymoquinone (TQ) encapsulated in DFPAC-OH@BSA-NPs (TQ-DFPAC-OH@BSA-NPs) have also been evaluated in A549 cell lines. The cytotoxic effect and quantification of intracellular reactive oxygen species (ROS) generation were further examined carefully to observe the anticancer property of TQ-DFPAC-OH@BSA-NPs. Therefore, the present system can simultaneously deliver drug molecules and image the event of delivery. The entire nanoparticles are characterized by transmission electron microscopy (TEM), scanning electron microscopy (SEM), dynamic light scattering (DLS), and infrared (IR) spectroscopy. The specific binding of DFPAC-OH is well supported by the molecular docking study, fluorescence lifetime measurement, and circular dichroism analysis.

Silymarin-Loaded, Lactobionic Acid-Conjugated Porous PLGA Nanoparticles Induce Apoptosis in Liver Cancer Cells.

HepG2 cells (HCC), characterized by epithelial-like morphology, high proliferation rates, and nontumorigenicity, require cost-effective and efficient treatment. Silymarin, a flavonoid extract of Silybum marianum, is effective in the treatment of HCC. Here, we have reported a comparative anticancer study of the well-characterized nanoformulations of lactobionic acid-adorned porous PLGA-encapsulated silymarin (LA-PLGA-Sil) with only porous PLGA-encapsulated silymarin (PLGA-Sil) against HepG2 cells. Treatment of HepG2 cells with LA-PLGA-Sil produced a significant deterioration in cell viability at an essentially low dose as compared with PLGA-Sil, due to the adorned lactobionic acid moiety, which results in better targeting. p53, a tumor suppressor gene, essentially initiates apoptosis in cells procuring wild-type p53 (p53 +/+). In our report, treatment of HepG2 cells (p53 +/+) with LA-PLGA-Sil activated p53, which in turn inhibited the proliferation of cells by instigating cell-cycle arrest and apoptosis in a concentration-dependent manner and simultaneously stabilized the nuclear translocation of NFκB-p65. To explore the effect of LA-PLGA-Sil on the expression of microRNA, we observed that LA-PLGA-Sil markedly upregulated the miR-29b in human HCC cells. Reactivation of the p53 gene by miR-29b targeted Bcl-2 and triggered the sequential activation of mediators such as proapoptotic Bax protein, release of cytochrome c, and the activation of caspase proteins (caspase-3 and caspase-9). Furthermore, the overexpression of NFκB-p65 in HepG2 cells reversed the repression, and this stabilization effect of LA-PLGA-Sil on the nuclear translocation of p65 led to the significant downregulation of miR-29b and successively decreased the p53 expression in LA-PLGA-Sil-treated cells, thereby providing a survival mechanism to HepG2. In entirety, our study demonstrated the extensive potential of LA-PLGA-Sil to instigate the cell death of HepG2 cells via apoptosis by targeting the miR-29b/p53 axis through the stabilization of NFκB. It also impaired the migratory activity of HepG2 cells and thereby furnished a comprehensive way to HCC therapeutic treatment.

Transferrin-decorated thymoquinone-loaded PEG-PLGA nanoparticles exhibit anticarcinogenic effect in non-small cell lung carcinoma via the modulation of miR-34a and miR-16.

Non-small cell lung carcinoma (NSCLC) is a highly lethal type of cancer with limited therapeutic avenues available to date. In the present study, we formulated PEGylated PLGA thymoquinone nanoparticles (TQ-Np) for improved TQ delivery to NSCLC cells. Transferrin (TF), a biodegradable, non-immunogenic and non-toxic protein, is well known to bind to TFR (transferrin receptor) over-expressed in non-small cell lung carcinoma A549 cells. Thus, the further decoration of the PEGylated PLGA thymoquinone nanoparticles with transferrin (TF-TQ-Np) enhanced the internalization of the nanoparticles within the A549 cells and the activity of TQ. We established TF-TQ-Np as a potent anti-tumorigenic agent through the involvement of p53 and the ROS feedback loop in regulating the microRNA (miRNA) circuitry to control apoptosis and migration of NSCLC cells. TF-TQ-Np-mediated p53 up-regulation favored the potential simultaneous activation of miR-34a and miR-16 targeting Bcl2 to induce apoptosis in the A549 cells. Additionally, TF-TQ-Np also restricted the migration through actin de-polymerization via activation of the p53/miR-34a axis. Further studies in chick CAM xenograft models confirmed the anti-cancer activity of TF-TQ-Np by controlling the p53/miR-34a/miR-16 axis. Furthermore, in vivo experiments conducted in a xenograft model in immunosuppressed Balb/c mice also proved the efficacy of the nanoparticles as an antitumor agent against NSCLC. Thus, our findings cumulatively suggest that the transferrin-adorned TQ-Np successfully coupled two distinct miRNA pathways to potentiate the apoptotic death cascade in the very lethal NSCLC cells and also restricts the migration of these cells without imparting any significant toxicity, which occurs in the widely used chemotherapeutic combinations. Thereby, our findings rekindle new hopes for the development of improved targeted therapeutic options with specified molecular objectives for combating the deadly NSCLC.

Folic-Acid-Adorned PEGylated Graphene Oxide Interferes with the Cell Migration of Triple Negative Breast Cancer Cell Line, MDAMB-231 by Targeting miR-21/PTEN Axis through NFκB.

Triple negative breast cancer (TNBC), characterized by its aggressive and highly metastatic nature, is difficult to cure by the currently available therapies. In our investigation, folic-acid-adorned PEGylated graphene oxide (FA-PEG-GO) was synthesized by modifying graphene oxide (GO) with folic acid-PEG conjugate (FA-PEG-NH2) by EDC/NHS coupling reaction. FA-PEG-GO exhibited an exceptional potential to attenuate cell migration of TNBC cell line ,MDAMB-231 as compared to GO because of the adorned folic acid moiety, which rendered better targeting. FA-PEG-GO inhibited cell migration by actin depolymerization and perturbing lamellipodia formation. The immunocytochemistry and western blot data unraveled the fact that FA-PEG-GO inhibited cell migration by targeting miR-21 by restricting the nuclear translocation of NFκB. The downregulation of miR-21 resulted in the elevation of PTEN expression which sequentially downregulated pFAK resulting in inhibition of cell migration. Moreover, upregulation of PTEN in FA-PEG-GO treated cells led to the decrease in expression of the downstream regulators including pAkt(Ser473) and pERK1/2, which contributed to the retardation of cell migration. Interestingly, the overexpression of NFκB-p65 by the transfection of NFκB-p65 expression plasmid in TNBC cells reversed the inhibitory effect of FA-PEG-GO on the nuclear translocation of NFκB-p65 which stabilized miR-21 expression and successively downregulated PTEN expression in FA-PEG-GO treated cells. Furthermore, miR-21 overexpression by transfection of miR-21 mimic in turn downregulated PTEN expression and sequentially restored the expression of pFAK even upon FA-PEG-GO treatment. miR-21 overexpression also compensated the inhibitory effect of FA-PEG-GO on pAkt(Ser473) and pERK1/2 which was evident from their significant expression in FA-PEG-GO-treated cells. The studies on chick embryo model ratified the ex ovo antimigratory efficacy of FA-PEG-GO. Altogether, our study unveiled the enormous potential of FA-PEG-GO to attenuate migration of TNBC cell line, MDAMB-231 by targeting the miR-21/PTEN axis through NFκB and thereby providing insights on cancer treatment.

Methylglyoxal at metronomic doses sensitizes breast cancer cells to doxorubicin and cisplatin causing synergistic induction of programmed cell death and inhibition of stemness.

Potent anticancer activity coupled with absence of toxicity at therapeutic dose established the glycolytic metabolite, methylglyoxal, as a promising candidate against malignant neoplasia. In this preclinical study we illustrate the applicability of methylglyoxal in formulating an optimally designed combination regimen with chemotherapeutic drugs against breast cancer. Results demonstrated a synergistic augmentation in doxorubicin and cisplatin mediated cytotoxicity in human breast cancer cell lines MDA MB 231 & MCF 7 with methylglyoxal co-treatment at metronomic concentrations. The cell death due to combination treatment was significantly prevented by N-Acetylcysteine and the synergistic effects were attenuated in presence of inhibitors for apoptosis and necroptosis, in MDA MB 231 and MCF 7 cells, respectively. Additionally, acridine orange staining and immunoblotting with LC3B antibody indicated the suppression of doxorubicin induced autophagy flux with methylglyoxal co-treatment. This report documents for the first time the preferential targeting of breast cancer stem cells by methylglyoxal. Combination treatment with doxorubicin or cisplatin hindered mammosphere forming efficiency and inclusively eliminated both cancer stem as well as non-stem cancer cells. The synergistic effect was validated in Ehrlich mammary carcinoma cell induced murine ascites model and the combination advantage in vivo was achieved without any additional deleterious effect to liver and kidney. Our present study evidences the implications of methylglyoxal inclusion in adjuvant multimodal chemotherapeutics against breast cancer and offers noteworthy insights into the possible outcome.