Your search keyword '"Datta, Saumen"' showing total 7 results

1. Biophysical and Computational Approaches to Unravel pH-Dependent Conformational Change of PspA Assist PspA-PspF Complex Formation in Yersinia enterocolitica.

Author

Roy, Chittran, Kumar, Rajeev, Hossain, Md Maruf, Das, Arkaprava, and Datta, Saumen

Subjects

YERSINIA enterocolitica, INTERFEROMETRY

Abstract

In enteropathogen, Yersinia enterocolitica, the genes encoding phage shock proteins are organized in an operon (pspA-E), which is activated at the various types of cellular stress (i.e., extracytoplasmic or envelop stress) whereas, PspA negatively regulates PspF, a transcriptional activator of pspA-E and pspG, and is also involved in other cellular machinery maintenance processes. The exact mechanism of association and dissociation of PspA and PspF during the stress response is not entirely clear. In this concern, we address conformational change of PspA in different pH conditions using various in-silico and biophysical methods. At the near-neutral pH, CD and FTIR measurements reveal a ß-like conformational change of PspA; however, AFM measurement indicates the lower oligomeric form at the above-mentioned pH. Additionally, the results of the MD simulation also support the conformational changes which indicate salt-bridge strength takes an intermediate position compared to other pHs. Furthermore, the bio-layer interferometry study confirms the stable complex formation that takes place between PspA and PspF at the near-neutral pH. It, thus, appears that PspA conformational change in adverse pH conditions abandons PspF from having a stable complex with it, and thus, the latter can act as a trans-activator. Taken together, it seems that PspA alone can transduce adverse signals by changing its conformation. [ABSTRACT FROM AUTHOR]

Published

2022

2. Fun with colours: The standard model with two-colour QCD has radically different long-distance physics.

Author

Datta, Saumen, Gupta, Sourendu, and Sharma, Rishi

Abstract

In our world, the standard model of particle physics contains within it the fairly intractable theory called QCD. A toy version with two colours is often studied as a model confining and chiral symmetry breaking field theory. Here, we investigate the cascade of changes at various distance scales if we make this change within the standard model. It is possible to limit the changes at the hadronic scale. However, the minor changes that occur actually cascade down to the far infrared, into nuclear and atomic physics, and chemistry. Through this, it also possibly affects the evolution of stars and galaxies. We remark on this unexpected sensitivity of the universe to physics at the scale of quarks. [ABSTRACT FROM AUTHOR]

Published

2021

3. Structural analysis of inter-genus complexes of V-antigen and its regulator and their stabilization by divalent metal ions.

Author

Basu, Abhishek, Das, Atanu, Mondal, Abhisek, and Datta, Saumen

Subjects

ANTIGENS, METAL ions, CONFORMATIONAL analysis, STRUCTURAL stability, HYDROPHOBIC compounds

Abstract

Gram-negative bacteria like Yersinia, Pseudomonas, and Aeromonas need type III secretion system (T3SS) for their pathogenicity. V-antigen and its regulator are essential for functioning of T3SS. There is significant functional conservation amongst V-antigen and its regulator belonging to the Ysc family. In this study, we have structurally characterized the inter-genus complexes of V-antigen and its regulator. ConSurf analysis demonstrates that V-antigens belonging to the Ysc family show high structural identity predominantly confined to the two long helical regions. The regulator of V-antigen shows high conservation in its first intramolecular coiled-coil domain, responsible for interaction with V-antigen. ∆LcrG localizes within the groove formed by long helices of LcrV, as observed in PcrV-∆PcrG interaction. Inter-genus complexes of LcrV-PcrG and PcrV-LcrG exhibited elongated conformation and 1:1 heterodimeric state like the native complex of PcrV-PcrG and LcrV-LcrG. Both native and inter-genus complexes showed rigid tertiary structure, solvent-exposed hydrophobic patches, and cooperative melting behavior with high melting temperature. LcrV-PcrG and PcrV-LcrG showed nanomolar affinity of interaction, identical to PcrV-PcrG interaction, but stronger than LcrV-LcrG interaction. Calcium (a secretion blocker of T3SS) propels all the complexes towards a highly monodisperse form. Calcium and magnesium increase the helicity of the native and inter-genus complexes, and causes helix-helix stabilization. Stabilization of helices leads to a slight increase in the melting temperature by 1.5-2.0 °C. However, calcium does not alter the affinity of interaction of V-antigen and its regulator, emphasizing the effect of divalent of cations at the structural level without any regulatory implications. Therefore, the structural conservation of these inter-genus complexes could be the basis for their functional complementation. [ABSTRACT FROM AUTHOR]

Published

2016

4. Quarkonia at finite temperature in relativistic heavy-ion collisions.

Author

DATTA, SAUMEN

Subjects

*QUARK-gluon plasma, *TEMPERATURE effect, *RELATIVISTIC Heavy Ion Collider, *STATIC equilibrium (Physics), *PLASMA physics

Abstract

The behaviour of quarkonia in relativistic heavy-ion collisions is reviewed. After a detailed discussion of the current theoretical understanding of quarkonia in a static equilibriated plasma, we discuss quarkonia yield from the fireball created in ultrarelativistic heavy-ion collision experiments. We end with a brief discussion of the experimental results and outlook. [ABSTRACT FROM AUTHOR]

Published

2015

5. YspC: A Unique Translocator Exhibits Structural Alteration in the Complex form with Chaperone SycB.

Author

Basu, Abhishek, Chatterjee, Rakesh, and Datta, Saumen

Subjects

PROTEIN structure, SECRETION, MOLECULAR chaperones, YERSINIA enterocolitica, GEL permeation chromatography, BIOINFORMATICS, ENERGY transfer

Abstract

YspC is an annotated translocator of Yersinia secretion apparatus- Yersinia secretion protein type three secretion system of Yersinia enterocolitica, it forms an 1:1 complex with its cognate chaperone SycB. Unlike other translocators, YspC is highly soluble inspite of having a transmembrane region. Size exclusion chromatography shows that YspC exists predominantly in a monomeric form. Multiple sequence alignment and ConSurf (a web based bioinformatic tool) analysis confirm its significant deviation from the closest class of minor translocators. YspC also possesses a tertiary structure signal seen from near UV CD, further confirming its unique nature amongst the groups of translocators. Far UV CD depicts that YspC is predominantly an α-helical protein; however, its secondary structure alters in the YspC-SycB complex. Thermal denaturation curve predicts a cooperative melting behaviour for YspC which is altered in the YspC-SycB complex. Furthermore, trypsinolysis data confirms a different digestion pattern for YspC in isolation, when compared to the complex form with SycB. From the Forsters resonance energy transfer analysis, it can be predicted that the two tetratricopeptide repeat regions of SycB are masked while it forms a complex with YspC and this is further confirmed by the interaction studies of YspC with two truncated forms of SycB. YspC interacted with ∆SycB and ∆SycB (possessing only the two TPR regions). However, the complexes formed between YspC and truncated forms of SycB have altered physiological states. [ABSTRACT FROM AUTHOR]

Published

2012

6. Characterization of Molten Globule PopB in Absence and Presence of Its Chaperone PcrH.

Author

Dey, Supratim, Basu, Abhishek, and Datta, Saumen

Subjects

MOLECULAR chaperones, GENETIC code, PSEUDOMONAS aeruginosa, BACTERIAL proteins, PROTEIN structure, CIRCULAR dichroism, FLUORESCENCE microscopy

Abstract

The TTSS encoding 'translocator operon' of Pseudomonas aeruginosa consists of a major translocator protein PopB, minor translocator protein PopD and their cognate chaperone PcrH. Far-UV CD spectra and secondary structure prediction servers predict an α-helical model for PopB, PcrH and PopB-PcrH complex. PopB itself forms a single species of higher order oligomer (15 mer) as seen from AUC, but in complex with PcrH, both monomeric (1:1) and oligomeric form exist. PopB has large solvent-exposed hydrophobic patches and exists as an unordered molten globule in its native state, but on forming complex with PcrH it gets transformed into an ordered molten globule. Tryptophan fluorescence spectrum indicates that PopB interacts with the first TPR region of dimeric PcrH to form a stable PopB-PcrH complex that has a partial rigid structure with a large hydrodynamic radius and few tertiary contacts. The pH-dependent studies of PopB, PcrH and complex by ANS fluorescence, urea induced unfolding and thermal denaturation experiments prove that PcrH not only provides structural support to the ordered molten globule PopB in complex but also undergoes conformational change to assist PopB to pass through the needle complex of TTSS and form pores in the host cell membrane. ITC experiments show a strong affinity (K ~ 0.37 μM) of PopB for PcrH at pH 7.8, which reduces to ~0.68 μM at pH 5.8. PcrH also loses its rigid tertiary structure at pH 5 and attains a molten globule conformation. This indicates that the decrease in pH releases PopB molecules and thus triggers the TTSS activation mechanism for the formation of a functional translocon. [ABSTRACT FROM AUTHOR]

Published

2012

7. Expression, Purification, Structural and Functional Analysis of SycB: A Type Three Secretion Chaperone From Yersinia enterocolitica.

Author

Basu, Abhishek, Chatterjee, Rakesh, and Datta, Saumen

Subjects

HOMOLOGY (Biology), PROTEIN folding, GRAM-negative bacteria, MICROBIAL virulence, MOLECULAR chaperones, LIGANDS (Biochemistry)

Abstract

In Yersinia enterocolitica biovar 1B, a genome encoded TTSS designated as Ysa-Ysp system is used for virulence. SycB is an annotated chaperone to this system. SycB is soluble in presence of translocator YspC. SycB and its truncated form (∆SycB) exist as dimers. YspC forms a 1:1 complex with SycB. Homology model of SycB shows a flexible N-terminal may be required for solubility and dimerization; and concave core formed by antiparallel helices of TPRs. Far UV CD spectra confirm that SycB is predominantly alpha helical. Near UV CD spectra show that SycB has tertiary structure at pH 7.2 (native folded protein), which disappears at pH 5 (molten globule) and SycB releases YspC at pH 5. SycB has a cooperative melting behavior. At pH 7.2, SycB shows solvent accessible hydrophobic patches. Concave core in the model exhibits ANS binding within FRET distance of tyrosines in the TPR, allowing a range of interaction of SycB with its ligand. [ABSTRACT FROM AUTHOR]

Published

2012