Thermophilic proteins function at high temperature, unlike mesophilic proteins. Thermo-stability of these proteins is due to the unique buried and networked salt-bridge (BNSB). However, it is known that the desolvation cost of BNSB is too high compared to other favorable energy terms. Nonetheless, it is known that stability is provided generally by hydrophobic isosteres without the need for BNSB. We show in this analysis that the BNSB is the optimal evolutionary design of salt-bridge to offset desolvation cost efficiently. Hence, thermophilic proteins with a high level of BNSB provide thermo-stability.
Hyper thermophilic archaea not only tolerate high temperature but also operate its biochemical machineries, normally under these
conditions. However, the structural signatures in proteins that answer for the hyper thermo-stability relative to its mesophilic homologue
remains poorly understood. We present comparative analyses of sequences, structures and salt-bridges of prolyl-oligopeptidase from
Pyrococcus furiosus (pfPOP - PDB ID: 5T88) and human (huPOP - PDB ID: 3DDU). A similar level of hydrophobic and hydrophilic residues
in pfPOP and huPOP is observed. A low level of interactions between shell-waters and atom-types in pfPOP indicated hyper thermophilic
features are negligible. Salt-bridge-forming-residues (sbfrs) are high in pfPOP's core and surface (pfPOP). Increased sbfrs largely indicate
specific-electrostatic is important for thermo stability in pfPOP. Four classes of sbfrs are found namely positionally non-conservative
(PNCS), conservative (PCS), unchanged (PU) and interchanged (PIC) type of substitutions. PNCS-sbfrs constitutes 28% and it is associated
with the topology of pfPOP at high temperature. PCS helps to increase the salt-bridge population. It is also found that PU maintains similar
salt-bridges at the active site and other binding sites while PIC abolishes mesophilic patterns.
Halophilic proteins have greater abundance of acidic over basic residues in sequence. In structure, the surface is decorated by negative
charges, with lower content of Lysine. Using sequence BLOCKs and 3D model of malate dehydrogenase from halophilic archaea
(Halobacterium salinarum; hsMDH) and X-ray structure from mesophilic bacteria (E. coli; ecMDH), we show that not only acidic and basic
residues have higher mean relative abundance (MRA) and thus, impart higher polarity to the sequences, but also show their presence in
the surface of the structure of hsMDH relative to its mesophilic counterpart. These observations may indicate that both the acidic and the
basic residues have a concerted role in the stability of hsMDH. Analysis on salt bridges from hsMDH and ecMDH show that in the former,
salt bridges are highly intricate, newly engineered and global in nature. Although, these salt bridges are abundant in hsMDH, in the active
site the design remains unperturbed. In high salt where hydrophobic force is weak, these salt bridges seem to play a major role in the
haloadaptation of the tertiary structure of hsMDH. This is the first report of such an observation.
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