Diastereoselective synthesis of substituted hexahydrobenzo[de]isochromanes and evaluation of their antileishmanial activity.

Hexahydrobenzo[de]isochromanes and hexahydropyrano[3,4,5-ij]isoquinolines can be efficiently synthesized via Friedel Crafts and oxa Pictet-Spengler reaction of acrylyl enol ethers mediated by triflic acid in good yields. The reaction is highly stereoselective. Two of the hexahydrobenzo[de]isochromanes are found to have moderate antileishmanial activity.

Simplified CRISPR-Mediated DNA Editing in Multicellular Eukaryotes.

The CRISPR-Cas9 system is becoming an imperative tool to edit the genome of various organisms. The gene-editing study by the CRISPR-Cas9 system has revolutionized the diverse field of biomedical research, genome engineering, and gene therapy. CRISPR-Cas9 system has been modified to induce genome editing by small-guide RNAs, which function together with Cas9 nuclease for sequence-specific cleavage of target sequences. Here, we describe the simplified protocol of CRISPR-Cas9-mediated DNA editing in multicellular eukaryotes, including the construction of gRNA plasmids into vectors, screening of positive clones, transfections into 293FT cell line, and transduction into Jurkat cells. We also describe different bioinformatic tools to design suitable gRNAs with increased efficiency and decreased off-target events. Further, we describe the assessments of DNA editing by indel mutations and sequencing in transduced cells.

Design of SaCas9-HF for In Vivo Gene Therapy.

Genome alteration results in several diseases for which therapeutics are limited. Gene editing provides a strong and potential alternative for the treatment of rare and genetic diseases. CRISPR-Cas9-based system is now being envisaged as a potential tool for the cure of genetic diseases. The RNA-guided nuclease, SaCas9 enzyme, along with its HF versions is widely employed for in vivo gene editing because of its small size and high efficiency. The current work summarizes the widely used and improved methods for in vivo manipulation of genes. The potential of CRISPR-Cas9-based systems can be harnessed to treat genetic diseases and holds great promise for therapeutic interventions in gene therapy. The in vivo gene editing poses a caveat in the form of delivery systems, the tissue in question, and several other factors. This work describes the methods which have been optimized to offer high efficiency, delivery, and gene editing in vivo.

In Vitro Assay for the Assessment of Oxygen Depletion Triggers in Human Cell Lines, Associated with Improving Responses to Cancer Therapy.

Tumors are usually associated with oxygen-deficient regions (hypoxia) which results from reduced and disorganized intratumoral vasculature, increased diffusion distances, and growing tumor masses. The proteomic and metabolomic landscape of the hypoxic cells is reprogrammed through hypoxia-induced transcription factor 1 which is activated in hypoxic conditions and is inactive when oxygen is abundant. This transcription factor has also been shown to inhibit or even reverse cell differentiation. Hypoxia impedes chemotherapy as it hampers the formation of cytotoxic free radicals due to the lesser availability of molecular oxygen. The metastatic and invasive attributes of cancer cells in hypoxic conditions are exacerbated, which results in poor therapeutic outcomes. Various cell-based assays for measuring hypoxia have been developed which give an estimate of the hypoxic state of cancer cells. Prior knowledge of these assays will improve the efficacy of the treatment regimens for cancers. This article provides exhaustive information on the hypoxia-based assays which are sensitive, robust, reliable, and give easy readout with choice of cell type for these assays may be dictated by the procedural or endpoint selection.

Molecular characterization and genetic diversity of four undescribed novel oleaginous Mortierella alpina strains from Libya.

Background: A large number of undiscovered fungal species still exist on earth, which can be useful for bioprospecting, particularly for single cell oil (SCO) production. Mortierella is one of the significant genera in this field and contains about hundred species. Moreover, M. alpina is the main single cell oil producer at commercial scale under this genus. Methods: Soil samples from four unique locations of North-East Libya were collected for the isolation of oleaginous Mortierellaalpina strains by a serial dilution method. Morphological identification was carried out using light microscopy (Olympus, Japan) and genetic diversity of the isolated Mortierella alpina strains was assessed using conserved internal transcribed spacer (ITS) gene sequences available on the NCBI GenBank database for the confirmation of novelty. The nucleotide sequences reported in this study have been deposited at GenBank (accession no. MZ298831:MZ298835). The MultAlin program was used to align the sequences of closely related strains. The DNA sequences were analyzed for phylogenetic relationships by molecular evolutionary genetic analysis using MEGA X software consisting of Clustal_X v.2.1 for multiple sequence alignment. The neighbour-joining tree was constructed using the Kimura 2-parameter substitution model. Results: The present research study confirms four oleaginous fungal isolates from Libyan soil. These isolates (barcoded as MSU-101, MSU-201, MSU-401 and MSU-501) were discovered and reported for the first time from diverse soil samples of district Aljabal Al-Akhdar in North-East Libya and fall in the class: Zygomycetes; order: Mortierellales. Conclusions: Four oleaginous fungal isolates barcoded as MSU-101, MSU-201, MSU-401 and MSU-501 were identified and confirmed by morphological and molecular analysis. These fungal isolates showed highest similarity with Mortierella alpina species and can be potentialistic single cell oil producers. Thus, the present research study provides insight to the unseen fungal diversity and contributes to more comprehensive Mortierella alpina reference collections worldwide.

Transcriptome Profiling Reveals Matrisome Alteration as a Key Feature of Ovarian Cancer Progression.

BACKGROUND: Ovarian cancer is the most lethal gynecologic malignancy. There is a lack of comprehensive investigation of disease initiation and progression, including gene expression changes during early metastatic colonization. METHODS: RNA-sequencing (RNA-seq) was done with matched primary tumors and fallopian tubes (n = 8 pairs) as well as matched metastatic and primary tumors (n = 11 pairs) from ovarian cancer patients. Since these are end point analyses, it was combined with RNA-seq using high-grade serous ovarian cancer cells seeded on an organotypic three-dimensional (3D) culture model of the omentum, mimicking early metastasis. This comprehensive approach revealed key changes in gene expression occurring in ovarian cancer initiation and metastasis, including early metastatic colonization. RESULTS: 2987 genes were significantly deregulated in primary tumors compared to fallopian tubes, 845 genes were differentially expressed in metastasis compared to primary tumors and 304 genes were common to both. An assessment of patient metastasis and 3D omental culture model of early metastatic colonization revealed 144 common genes that were altered during early colonization and remain deregulated even in the fully developed metastasis. Deregulation of the matrisome was a key process in early and late metastasis. CONCLUSION: These findings will help in understanding the key pathways involved in ovarian cancer progression and eventually targeting those pathways for therapeutic interventions.

Leishmania donovani asparaginase variants exhibit cytosolic localization.

Asparaginase, a pivotal enzyme of the aspartate metabolic pathway is present as two variants in Leishmania donovani, causative agent of visceral leishmaniasis (VL). Our microscopy based analysis revealed that the green fluorescent protein tagged asparaginase variants were localized in the cytosol of the parasite. The finding was also supported by the in silico analysis of the L. donovani asparaginase variants. This finding is in stark contrast with other parasitic species such as M. tuberculosis where asparaginase is secreted out of the parasite. Further studies are required to decipher the exact function of asparaginase variants in the infectivity and growth of the parasite.

Fresh insights into the pyrimidine metabolism in the trypanosomatids.

The trypanosomatid parasites continue their killing spree resulting in significant annual mortality due to the lack of effective treatments and the prominence of these diseases in poorer countries. These dimorphic parasites thrive unchecked in the host system, outsmarting the immune mechanisms. An understanding of biology of these parasitic forms will help in the management and elimination of these fatal diseases. Investigation of various metabolic pathways in these parasites has shed light in the understanding of the unique biology of the trypansomatids. An understanding of these pathways have helped in tracing the soft targets in the metabolic pathways, which could be used as effective drug targets which would further impact the therupeutic implications. Pyrimidine pathway is a vital metabolic pathway which yields in the formation of pyrimidines, which are then integrated in nucleic acids (DNA and RNA) in sugars (UDP sugars) and lipids (CDP lipids). A wealth of data and information has been generated in the past decades by in-depth analyses of pyrimidine pathway in the trypanosomatid parasites, which can aid in the identification of anomalies between the parasitic and host counterpart which could be further harnessed to develop therapeutic interventions for the treatment of parasitic diseases. This review presents an updated and comprehensive detailing of the pyrimidine metabolism in the trypansomatids, their uniqueness and their distinctions, and its possible outcomes that would aid in the eradication of these parasitic diseases.

Apoptosis: Mediator Molecules, Interplay with Other Cell Death Processes and Therapeutic Potentials.

Apoptosis, a form of programmed cell death, plays a very crucial role in various physiological processes for maintaining cell homeostasis. This process has several characteristic features like membrane blebbing, nuclear condensation, DNA fragmentation and cell shrinkage. Any defect in this highly regulated process eventually leads to extended cell survival and could result in neoplastic cell expansion followed by genetic instability. The apoptotic machinery is mainly processed and regulated by various caspases, a family of cysteine proteases. Significant advancement has been made towards understanding the molecular mechanisms of apoptosis which provides new insights in modulating the life or death of a cell. The main goal of this review is to highlight recent updates on apoptosis, the cross-talk with other cellular death processes and its therapeutic potentials.

Methionine aminopeptidase 2 is a key regulator of apoptotic like cell death in Leishmania donovani.

We investigate the role of methionine aminopeptidase 2 (MAP2) in miltefosine induced programmed cell death (PCD) in promastigote form of L. donovani. We report that TNP-470, an inhibitor of MAP2, inhibits programmed cell death in miltefosine treated promastigotes. It inhibits the biochemical features of metazoan apoptosis, including caspase3/7 protease like activity, oligonucleosomal DNA fragmentation, collapse of mitochondrial transmembrane potential, and increase in cytosolic pool of calcium ions but did not prevent the cell death and phosphatidyl serine externalization. The data suggests that the MAP2 is involved in the regulation of PCD in parasite. Moreover, TNP-470 shows the leishmanicidal activity (IC50 = 15 µM) and in vitro inhibition of LdMAP2 activity (K i = 13.5 nM). Further studies on MAP2 and identification of death signaling pathways provide valuable information that could be exploited to understand the role of non caspase proteases in PCD of L. donovani.

Exploration of New and Potent Lead Molecules Against CAAX Prenyl Protease I of Leishmania donovani Through Pharmacophore Based Virtual Screening Approach.

AIM AND OBJECTIVE: Visceral leishmaniasis is a deadly disease left untreated in over 95% of cases. It is characterized by irregular bouts of fever, weight loss, enlargement of the spleen and liver, and anemia. It is highly endemic in the Indian subcontinent. CAAX prenyl protease I of Leishmania donovani is one of the important targets regulating the post translational modification process. Hence identifying potent drug candidate against the target is essential. This study mainly focuses on developing new and potent inhibitors against CAXX prenyl protease I of Leishmania donovani. MATERIALS AND METHODS: Pharmacophore based virtual screening was carried out using derivatives of bi-substrate analog farnesyl transferase inhibitors reported against CAAX prenyl proteases I. On the basis of ligand based pharmacophore model we have obtained 5 point pharmacophore AAADR with three hydrogen bond acceptors (A), one hydrogen bond donor (D) and one aromatic ring. The newly identified hits through pharmacophore model were further docked into the active site of the modeled protein. To get further insights of protein ligand interaction we have performed induced fit docking followed by molecular dynamics simulations. The DFT analysis depicts the electronic structure properties of the compounds. These results can be useful for the development of novel and potent CAAX prenyl protease I inhibitors. RESULTS: Initially, we have obtained a large number of newly identified hits by screening four different databases further docked into the active site of the protein and 20 compounds were selected on the basis of docking score. Perhaps Induced fit docking was performed to infer protein ligand interaction in a dynamic state and top 5 compounds 7118044, 7806909, LEG12866807, 9208535, SYN 19867403 were found to have good protein ligand interactions with key amino acid residues such as Glu287, His290 and additional interaction like Ile197, Asn209 Tyr253, Phe254, Gly256, Tyr266 with better binding energy -59.794 Kcal/mol, -66.305 Kcal/mol, -70.467 Kcal/mol, -82.474 Kcal/mol, -64.045. The predicted ADME properties are in desirable range and the HOMO/LUMO gap clearly indicates the electrons behavior of the ligands. Molecular dynamics simulations of the protein ligand complex for 20 ns clearly depicts the compounds are stable throughout the simulation time. CONCLUSION: The newly identified hits through pharmacophore based screening could be used as potential CAAX prenyl protease I inhibitors of Leishmania donovani.

Biochemical characterization of dihydroorotase of Leishmania donovani: Understanding pyrimidine metabolism through its inhibition.

De novo pyrimidine biosynthesis pathway is well developed and functional in protozoan parasite Leishmania donovani. The dihydroorotase (LdDHOase) is third enzyme of the pathway. The enzyme was cloned, expressed in E. coli BL21 (DE3), purified to homogeneity and biochemically characterized. The estimated kcat for the forward reaction and reverse reactions were 2.1 ± 0.1 s-1 and 1.1 ± 0.15 s-1, respectively. Homology modeling and docking studies were done to find out potential inhibitors for LdDHOase. Biotin sulfone and Kaempferol were found to be potential inhibitors of LdDHOase based on docking studies. These inhibitors were verified using recombinant LdDHOase and their anti-leishmanial effect was evaluated. Moreover, alterations in expressions of de novo as well as salvage pathways enzymes, after treatment of L. donovani with dihydroorotase inhibitor(s) were evaluated and discussed as survival mechanism of the pathogen. Further, effect of inhibition of cytidine deaminase, a key enzyme of salvage pathway of pyrimidine biosynthesis, was also evaluated on parasitic survival and alteration in gene expression of enzymes of both pathways. Further, effect of both pathways inhibition was also evaluated. The data suggests that the inhibition of single pathway can be overcome by increased expression of enzyme(s) of alternate pathway and both pathways seem to be equally important in the pathogen. When both pathways are simultaneously inhibited, parasite shows significant DNA damage and parasitic death.

Frequency distribution and assessment of genetic diversity of novel endophyte Alternaria alternata accessions isolated from Pongamia pinnata L.

Thepresent study discusses the frequency distribution and genetic diversity of novel fungal endopyte Alternaria alternata within the Pongammia pinnata plant samples. A total of ten plant samples of Pongammia pinnata, Pierre. (Karanja) were collected from specific locations of Sanganer region of Rajasthan for the isolation of fungal endophytes. Of these, maximum frequency of Alternaria alternata (22.29%) were recorded which are morphologically similar but ecologically variant. Efficacy of randomly amplified polymorphic DNA (RAPD), were assessed in seventeen individuals of the primers was GCC 180 where as 10 bands were generated by GCC 181. The similarity coefficient matrix generated for the primers was subjected to algorithm UPGMA (Unweighted Pair Group Method Analysis) and clusters were generated using NTSYS 2.02 pc program. To stabilize the level of relatedness among the seventeen ecologically variant Alternaria alternata accessions, the dendrogram was constructed, which showed that all the isolates were diversified endophytically with in the plant Pongamia pinnata.

Assessment of genetic diversity and distribution of endophytic fungal communities of Alternaria solani isolates associated with the dominant Karanja plants in Sanganer Region of Rajasthan.

Higher plants are ubiquitously colonized with fungal endophytes that often lack readily detectable structures. Current study examines the distribution of endophytic fungal communities within Karanja plants and diversity of novel fungal endophyte Alternaria solani isolates collected from different locations of Sanganer region of Rajasthan. Results confirmed that A. solani is a major fungal endophyte consortium associated with Karanja plants. PCR Amplified fragments using random amplified polymorphic DNA (RAPD) primers were subjected to unweighted pair group method analysis (UPGMA), which clearly distinguished twelve ecologically diverse A. solani isolates. A total of 58 RAPD loci were amplified, out of which 35 (60.34%) were polymorphic and 23 were monomorphic (39.66%) in nature. These polymorphic loci were identified with an average of 2.92 bands per primer. The efficacy of RAPD markers proved as an efficient marker system with respect to detection of polymorphism and number of loci scored and can be used for the identification of a particular isolates, thereby defining core collections and strengthening their exploitation in acquiring novel products produced by them.