Esha Pandita scite author profile

Esha Pandita

4Publications

73Citation Statements Received

255Citation Statements Given

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National Institute of Immunology

Publications

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Tetrameric assembly of hGBP1 is crucial for both stimulated GMP formation and antiviral activity

Pandita

Rajan

Rahman

et al. 2016

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Interferon-γ inducible human guanylate binding protein-1 (hGBP1) shows a unique characteristic that hydrolyses GTP to a mixture of GDP and GMP through successive cleavages, with GMP being the major product. Like other large GTPases, hGBP1 undergoes oligomerization upon substrate hydrolysis, which is essential for the stimulation of activity. It also exhibits antiviral activity against many viruses including hepatitis C. However, which oligomeric form is responsible for the stimulated activity leading to enhanced GMP formation and its influence on antiviral activity, are not properly understood. Using mutant and truncated proteins, our data indicate that transition-state-induced tetramerization is associated with higher rate of GMP formation. This is supported by chimaeras that are defective in both tetramerization and enhanced GMP formation. Unlike wild-type protein, chimaeras did not show allosteric interactions, indicating that tetramerization and enhanced GMP formation are allosterically coupled. Hence, we propose that after the cleavage of the first phosphoanhydride bond GDP·Pi-bound protein dimers transiently associate to form a tetramer that acts as an allosteric switch for higher rate of GMP formation. Biochemical and biophysical studies reveal that sequential conformational changes and interdomain communications regulate tetramer formation via dimer. Our studies also show that overexpression of the mutants, defective in tetramer formation in Rep2a cells do not inhibit proliferation of hepatitis C virus, indicating critical role of a tetramer in the antiviral activity. Thus, the present study not only highlights the importance of hGBP1 tetramer in stimulated GMP formation, but also demonstrates its role in the antiviral activity against hepatitis C virus.

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Understanding the lower GMP formation in large GTPase hGBP‐2 and role of its individual domains in regulation of GTP hydrolysis

et al. 2019

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The interferon γ‐inducible large GTPases, human guanylate‐binding protein (hGBP)‐1 and hGBP‐2, mediate antipathogenic and antiproliferative effects in human cells. Both proteins hydrolyse GTP to GDP and GMP through successive cleavages of phosphate bonds, a property that functionally distinguishes them from other GTPases. However, it is unclear why hGBP‐2 yields lower GMP than hGBP‐1 despite sharing a high sequence identity (~ 78%). We previously reported that the hGBP‐1 tetramer is crucial for enhanced GMP formation. We show here that the hGBP‐2 tetramer has no role in GMP formation. Using truncated hGBP‐2 variants, we found that its GTP‐binding domain alone hydrolyses GTP only to GDP. However, this domain along with the intermediate region enabled dimerization and hydrolysed GTP further to GMP. We observed that unlike in hGBP‐1, the helical domain of hGBP‐2 has an insignificant role in the regulation of GTP hydrolysis, suggesting that the differences in GMP formation between hGBP‐2 and hGBP‐1 arise from differences in their GTP‐binding domains. A large sequence variation seen in the guanine cap may be responsible for the lower GMP formation in hGBP‐2. Moreover, we identified the sites in the hGBP‐2 domains that are critical for both dimerization and tetramerization. We also found the existence of hGBP‐2 tetramer in mammalian cells, which might have a role in the suppression of the carcinomas. Our study suggests that sequence variation near the active site in these two close homologues leads to differential second phosphate cleavage and highlights the role of individual hGBP‐2 domains in the regulation of GTP hydrolysis.

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Stimulation of GMP formation in hGBP1 is mediated by W79 and its effect on the antiviral activity

et al. 2020

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Interferon-inducible large GTPases are critical for innate immunity. The distinctive feature of a large GTPase, human guanylate binding protein-1 (hGBP1), is the sequential hydrolysis of GTP into GMP via GDP. Despite several structural and biochemical studies, the underlying mechanism of assembly-stimulated GMP formation by hGBP1 and its role in immunity are not fully clarified. Using a series of biochemical, biophysical, and in silico experiments, we studied four tryptophan residues, located near switch I-II (in and around the active site) to understand the conformational changes near these regions and also to investigate their effect on enhanced GMP formation. The W79A mutation showed significantly reduced GMP formation, whereas the W81A and W180A substitutions exhibited only a marginal defect. The W114A mutation showed a long-range effect of further enhanced GMP formation, which was mediated through W79. We also observed that after first phosphate cleavage, the W79-containing region undergoes a conformational change, which is essential for stimulated GMP formation. We suggest that this conformational change helps to reposition the active site for the next cleavage step, which occurs through a stable contact between the indole moiety of W79 and the main chain carbonyl of K76. We also showed that stimulated GMP formation is crucial for antiviral activity against hepatitis C. Thus, the present study not only provides new insight for the stimulation of GMP formation in hGBP1, but also highlights the importance of the enhanced second phosphate cleavage product in the antiviral activity.

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Insight into Temperature Dependence of GTPase Activity in Human Guanylate Binding Protein-1

et al. 2012

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Interferon-γ induced human guanylate binding protein-1(hGBP1) belongs to a family of dynamin related large GTPases. Unlike all other GTPases, hGBP1 hydrolyzes GTP to a mixture of GDP and GMP with GMP being the major product at 37°C but GDP became significant when the hydrolysis reaction was carried out at 15°C. The hydrolysis reaction in hGBP1 is believed to involve with a number of catalytic steps. To investigate the effect of temperature in the product formation and on the different catalytic complexes of hGBP1, we carried out temperature dependent GTPase assays, mutational analysis, chemical and thermal denaturation studies. The Arrhenius plot for both GDP and GMP interestingly showed nonlinear behaviour, suggesting that the product formation from the GTP-bound enzyme complex is associated with at least more than one step. The negative activation energy for GDP formation and GTPase assay with external GDP together indicate that GDP formation occurs through the reversible dissociation of GDP-bound enzyme dimer to monomer, which further reversibly dissociates to give the product. Denaturation studies of different catalytic complexes show that unlike other complexes the free energy of GDP-bound hGBP1 decreases significantly at lower temperature. GDP formation is found to be dependent on the free energy of the GDP-bound enzyme complex. The decrease in the free energy of this complex at low temperature compared to at high is the reason for higher GDP formation at low temperature. Thermal denaturation studies also suggest that the difference in the free energy of the GTP-bound enzyme dimer compared to its monomer plays a crucial role in the product formation; higher stability favours GMP but lower favours GDP. Thus, this study provides the first thermodynamic insight into the effect of temperature in the product formation of hGBP1.

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Esha Pandita

Tetrameric assembly of hGBP1 is crucial for both stimulated GMP formation and antiviral activity

Understanding the lower GMP formation in large GTPase hGBP‐2 and role of its individual domains in regulation of GTP hydrolysis

Stimulation of GMP formation in hGBP1 is mediated by W79 and its effect on the antiviral activity

Insight into Temperature Dependence of GTPase Activity in Human Guanylate Binding Protein-1

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