Nishant Singh

Dominant negative mutations affect oligomerization of human pyruvate kinase M2 isozyme and promote cellular growth and polyploidy.

This study was designed to understand the mechanism and functional implication of the two heterozygous mutations (H391Y and K422R) of human pyruvate kinase M2 isozyme (PKM2) observed earlier in a Bloom syndrome background. The co-expression of homotetrameric wild type and mutant PKM2 in the cellular milieu resulting in the interaction between the two at the monomer level was substantiated further by in vitro experiments. The cross-monomer interaction significantly altered the oligomeric state of PKM2 by favoring dimerization and heterotetramerization. In silico study provided an added support in showing that hetero-oligomerization was energetically favorable. The hetero-oligomeric populations of PKM2 showed altered activity and affinity, and their expression resulted in an increased growth rate of Escherichia coli as well as mammalian cells, along with an increased rate of polyploidy. These features are known to be essential to tumor progression. This study provides insight in understanding the modulated role of large oligomeric multifunctional proteins such as PKM2 by affecting cellular behavior, which is an essential observation to understand tumor sustenance and progression and to design therapeutic intervention in future.

Homologous Recombination Occurs in Entamoeba and Is Enhanced during Growth Stress and Stage Conversion

Homologous recombination (HR) has not been demonstrated in the parasitic protists Entamoeba histolytica or Entamoeba invadens, as no convenient method is available to measure it. However, HR must exist to ensure genome integrity, and possible genetic exchange, especially during stage conversion from trophozoite to cyst. Here we show the up regulation of mitotic and meiotic HR genes in Entamoeba during serum starvation, and encystation. To directly demonstrate HR we use a simple PCR-based method involving inverted repeats, which gives a reliable read out, as the recombination junctions can be determined by sequencing the amplicons. Using this read out, we demonstrate enhanced HR under growth stress in E. histolytica, and during encystation in E. invadens. We also demonstrate recombination between chromosomal inverted repeats. This is the first experimental demonstration of HR in Entamoeba and will help future investigations into this process, and to explore the possibility of meiosis in Entamoeba.

Entamoeba invadens: Dynamics of DNA synthesis during differentiation from trophozoite to cyst

The DNA dynamics which mediate conversion of uni-nucleate trophozoite into quadrinucleate cyst in Entamoeba histolytica is not well understood. Here, we have addressed this question in Entamoeba invadens (a model system for encystation) through a detailed time course study of the differentiation process. We combined flow cytometric analysis with the change in rate of thymidine incorporation and the number of nuclei per cell. Our data shows that during encystment the cell population passes through three phases: (1) Early phase (0-8h); of rapid DNA synthesis which may correspond to completion of ongoing DNA replication. Bi-nucleated cells increase with concomitant drop in uni-nucleated cells. (2) Commitment phase (8-24h); in which DNA synthesis rate slows down. Possibly new rounds of replication are initiated which proceed slowly, followed by mitosis at 20 h. After this the number of bi- and uni-nucleated cells gradually decline and the tri- and tetra-nucleated cells begin to increase. (3) Consolidation phase (24-72 h); in which the rate of DNA synthesis shows a small increase till 32 h and then begins to decline. The G2/M peak reappears at 48 h, showing that more rounds of DNA replication may be getting completed, followed by nuclear division. By 72 h the encystment is virtually complete. The bi-nucleated stage could be an intermediate both in the conversion of trophozoite to cyst and back. Our study provides a comprehensive view of DNA dynamics during encystation and excystation of E. invadens.

Stable transfection and continuous expression of heterologous genes in Entamoeba invadens

Amoebiasis is spread by the ingestion of dormant Entamoeba histolytica cysts. Intervention of encystation could break the transmission cycle, thereby reducing disease burden. The model system used to study trophozoite to cyst differentiation is Entamoeba invadens. Here we describe an electroporation-based method for stable transfection of E. invadens with a plasmid pEiNEO-LUC containing the neomycin phosphotransferase gene under the control of E. invadens ribosomal protein gene S10 promoter. The plasmid also contains luciferase reporter gene expressed from the promoter of ribosomal protein gene L3. After electroporation, cells receiving the plasmid were selected by growth in 10μgml(-1) G418 and stable lines were obtained in four to five weeks. The plasmid was replicated episomally to ∼10 copies per haploid genome. In the absence of drug selection 50% of the plasmid copies were lost in 9-10 days. In cells growing under drug selection the reporter gene was continuously expressed throughout the differentiation process from trophozoite to cyst and back, making this system suitable for analysis of genes involved in differentiation.

Establishment of a transient transfection system and expression of firefly luciferase in Entamoeba invadens.

Entamoeba invadens is used as a model system to study trophozoite to cyst differentiation since Entamoeba histolytica, the causative agent of amoebiasis cannot encyst in culture. However, a system for introduction of cloned genes in E. invadens is not available. Here we report an electroporation-based method for transfection of E. invadens tophozoites and demonstrate the expression of firefly luciferase reporter gene driven from the E. invadens ribosomal protein L3 promoter. The efficiency of luciferase expression driven from the promoters of three different E. invadens genes (rpl3, rps10 and h2b) was tested and found to correlate with the in vivo expression levels of the respective gene. This system will permit the analysis of regulatory elements required for gene expression in E. invadens.

Differential Expression and Immunolocalization of Antioxidant Enzymes in Entamoeba histolytica Isolates during Metronidazole Stress

Entamoeba histolytica infections are endemic in the Indian subcontinent. Five to eight percent of urban population residing under poor sanitary conditions suffers from Entamoeba infections. Metronidazole is the most widely prescribed drug used for amoebiasis. In order to understand the impact of metronidazole stress on the parasite, we evaluated the expression of two antioxidant enzymes, peroxiredoxin and FeSOD, in Entamoeba histolytica isolates during metronidazole stress. The results reveal that, under metronidazole stress, the mRNA expression levels of these enzymes did not undergo any significant change. Interestingly, immunolocalization studies with antibodies targeting peroxiredoxin indicate differential localization of the protein in the cell during metronidazole stress. In normal conditions, all the Entamoeba isolates exhibit presence of peroxiredoxin in the nucleus as well as in the membrane; however with metronidazole stress the protein localized mostly to the membrane. The change in the localization pattern was more pronounced when the cells were subjected to short term metronidazole stress compared to cells adapted to metronidazole. The protein localization to the cell membrane could be the stress response mechanism in these isolates. Colocalization pattern of peroxiredoxin with CaBp1, a cytosolic protein, revealed that the membrane and nuclear localization was specific to peroxiredoxin during metronidazole stress.