Structural dynamics of native and V260E mutant C-terminal domain of HIV-1 integrase

Effects of Peutz-Jeghers syndrome (PJS) causing missense mutations L67P, L182P, G242V and R297S on the structural dynamics of LKB1 (Liver kinase B1) protein

The liver kinase B1 (LKB1) is encoded by LKB1 gene. Several pathogenic mutations of LKB1 causing Peutz-Jeghers syndrome and also cancers in breast, gastric, pancreas, and colon have been reported. The present study is focused to analyze the effects on the structural dynamics of LKB1 caused by the 4 pathogenic missense mutations (L67P, L182P, G242V, and R297S), which are reported to reduce the catalytic activity. In this study, the structural changes of LKB1 in apo- and in heterotrimeric complex (LKB1-STRADα-MO25α) form with wild and mutated LKB1 are investigated using all atomistic molecular dynamic simulation. The present study reveals that these four mutations initiate local structural distortions and the solvent accessibility of the surrounding regions of ATP-binding pocket such as glycine-rich loop, αB and αC loop, activation and catalytic loops. The mutations of L67P, L182P, and G242 V induce distortions of the secondary structure of β1-β3 sheets, π - π interaction (observed between Phe204 of LKB1 and Phe243 of MO25α), and increase the helical properties (both helical twist and length) of the adjacent αH-helix, respectively. The active kinase features like the conformation of catalytic and activation loops, salt bridge and, finally, the formation of stable R- and C-hydrophobic spines are also found to be perturbed by these mutations. Hence, the observed mutation-induced structural distortions fail to coordinate the essential binding nature of LKB1 with STRADα and MO25α, which eventually affects the native function of LKB1. These observations are in line with the experimentally reported reduced kinase activity of LKB1.

The conformational feasibility for the formation of reaching dimer in ASV and HIV integrase: a molecular dynamics study

Retroviral integrases are reported to form alternate dimer assemblies like the core-core dimer and reaching dimer. The core-core dimer is stabilized predominantly by an extensive interface between two catalytic core domains. The reaching dimer is stabilized by N-terminal domains that reach to form intermolecular interfaces with the other subunit's core and C-terminal domains (CTD), as well as CTD-CTD interactions. In this study, molecular dynamics (MD), Brownian dynamics (BD) simulations, and free energy analyses, were performed to elucidate determinants for the stability of the reaching dimer forms of full-length Avian Sarcoma Virus (ASV) and Human Immunodeficiency Virus (HIV) IN, and to examine the role of the C-tails (the last ~16-18 residues at the C-termini) in their structural dynamics. The dynamics of an HIV reaching dimer derived from small angle X-ray scattering and protein crosslinking data, was compared with the dynamics of a core-core dimer model derived from combining the crystal structures of two-domain fragments. The results showed that the core domains in the ASV reaching dimer express free dynamics, whereas those in the HIV reaching dimer are highly stable. BD simulations suggest a higher rate of association for the HIV core-core dimer than the reaching dimer. The predicted stability of these dimers was therefore ranked in the following order: ASV reaching dimer < HIV reaching dimer < composite core-core dimer. Analyses of MD trajectories have suggested residues that are critical for intermolecular contacts in each reaching dimer. Tests of these predictions and insights gained from these analyses could reveal a potential pathway for the association and dissociation of full-length IN multimers.

Insights into the structural dynamics of Liver kinase B1 (LKB1) by the binding of STe20 Related Adapterα (STRADα) and Mouse protein 25α (MO25α) co-activators

LKB1, the tumour suppressor, is found mutated in Peutz-Jeghers syndrome (PJS). The LKB1 is a serine-threonine kinase protein that is allosterically activated by the binding of STRADα and MO25α without phosphorylating the Thr212 present at activation loop. The present study aims to highlight the structural dynamics and complexation mechanism during the allosteric activation of LKB1 by these co-activators using molecular dynamics simulations. The all atom simulations performed on the complexes of LKB1 with ATP, STRADα, and MO25α for a period of 30 ns reveal that binding of STRADα and MO25α significantly stabilizes the highly flexible regions of LKB1 such as ATP binding region (β1-β2 loop), catalytic & activation loop segments and αG helix. Also, binding of STRADα and MO25α to LKB1 promotes coordinated motion between N- and C-lobes along with the catalytic & activation loops by forming H-bonds between LKB1 and co-activators, which further facilitate to establish the conserved attributes of active LKB1 such as (i) formation of salt bridge between Lys78 and Glu98, (ii) formation of stable hydrophobic R- and C-spines, and (iii) interaction between both catalytic and activation loops. Especially, the residues of LKB1 interacting with STRADα (Arg74, Glu342) and MO25α (Glu165, Pro203 and Phe204) are observed to play a significant role in stabilizing the (LKB1-ATP)-(STRADα-ATP)-MO25α complex. Overall, the present work highlighting the structural dynamics of LKB1 by the binding of allosteric co-activators is expected to provide a basic understanding on drug design specific to PJS syndrome.

Conformational analysis on the wild type and mutated forms of human ORF1p: a molecular dynamics study

The protein ORF1p, encoded by the LINE-1 retrotransposon, is responsible for the packaging and transposition of its RNA transcript and is reported to be involved in various genetic disorders. The three domains of ORF1p co-ordinate together to facilitate the transposition, and the mechanism of nucleic acid binding is not yet clear. The C-terminal domain of ORF1p adopts a lifted, twisted or rested state, which is regulated by several inter- and intra-domain interactions that are explored in this study. The residues, Glu147, Asp151, Lys154, Arg261 and Tyr282, are majorly involved in mediating the functional dynamics of ORF1p by forming H-bonds and π-interactions. The importance of these residues was elucidated by performing molecular dynamics simulations on both native as well as mutated ORF1p. The Q147A-D151A-K154A mutant expressed unique dynamics featuring the lifting motion of the CTD core alone, while the R261A mutant resulted in the oscillatory motion of CTD. In both cases, the CTDs were held in place by Tyr282 and in its absence, the structural stability of CTDs in the trimeric unit was significantly affected. Additional interactions responsible for stabilizing the trimeric ORF1p to express its native dynamics were extracted in this study. The central role of Tyr282 in maintaining the functional state of ORF1p to facilitate nucleic acid binding and formation of ribonucleoprotein complex is well highlighted. The knowledge gained from this study forms the basis for understanding the nucleic acid binding mechanism of ORF1p, which could further provide additional support in exploring various genetic disorders.