Biophysical Characterization of Interaction between E. coli Alanyl-tRNA Synethase with its Promoter DNA.

BACKGROUND: Aminoacyl-tRNA Synthetases (aaRSs) are well known for their role in the translation process. Lately investigators have discovered that this family of enzymes are also capable of executing a broad repertoire of functions that not only impact protein synthesis, but extend to a number of other activities. Till date, transcriptional regulation has so far only been described in E. coli Alanyl-tRNA synthetase and it was demonstrated that alaRS binds specifically to the palindromic DNA sequence flanking the gene's transcriptional start site and thereby regulating its own transcription. OBJECTIVE: In the present study, we have characterized some of the features of the alaRS-DNA binding using various biophysical techniques. METHODS: To understand the role of full length protein and oligomerization of alaRS in promoter DNA binding, two mutants were constructed, namely, N700 (a monomer, containing the N-terminal aminoacylation domain but without the C-terminal part) and G674D (previously demonstrated to form full-length monomer). Protein-DNA binding study using fluorescence spectroscopy, analytical ultracentrifugation, Isothermal Titration Calorimetry was conducted. RESULTS: Sedimentation equilibrium studies clearly demonstrated that monomeric variants were unable to bind promoter DNA. Isothermal Calorimetry (ITC) experiment was employed for further characterization of wild type alaRS-DNA interaction. It was observed that full length E. coli Alanyl-tRNA synthetase binds specifically with its promoter DNA and forms a dimer of dimers. On the other hand the two mutant variants were unable to bind with the DNA. CONCLUSION: In this study it was concluded that full length E. coli Alanyl-tRNA synthetase undergoes a conformational change in presence of its promoter DNA leading to formation of higher order structures. However, the exact mechanism behind this binding is currently unknown and beyond the scope of this study.

Urea Unfolding Study of E. coli Alanyl-tRNA Synthetase and Its Monomeric Variants Proves the Role of C-Terminal Domain in Stability.

E. coli alanyl-tRNA exists as a dimer in its native form and the C-terminal coiled-coil part plays an important role in the dimerization process. The truncated N-terminal containing the first 700 amino acids (1-700) forms a monomeric variant possessing similar aminoacylation activity like wild type. A point mutation in the C-terminal domain (G674D) also produces a monomeric variant with a fivefold reduced aminoacylation activity compared to the wild type enzyme. Urea induced denaturation of these monomeric mutants along with another alaRS variant (N461 alaRS) was studied together with the full-length enzyme using various spectroscopic techniques such as intrinsic tryptophan fluorescence, 1-anilino-8-naphthalene-sulfonic acid binding, near- and far-UV circular dichroism, and analytical ultracentrifugation. Aminoacylation activity assay after refolding from denatured state revealed that the monomeric mutants studied here were unable to regain their activity, whereas the dimeric full-length alaRS gets back similar activity as the native enzyme. This study indicates that dimerization is one of the key regulatory factors that is important in the proper folding and stability of E. coli alaRS.

Guanidine hydrochloride mediated denaturation of E. coli Alanyl-tRNA synthetase: identification of an inactive dimeric intermediate.

E. coli Alanyl-tRNA synthetase (AlaRS) not only catalyzes tRNA charging but also can bind to its own promoter DNA sequence and repress its own transcription. It exists as a dimer in its native form and so far this is the only aminoacyl-tRNA synthetase whose full length structure is unresolved. Guanidine hydrochloride mediated unfolding of AlaRS has been studied under equilibrium conditions using various spectroscopic techniques such as intrinsic tryptophan fluorescence, 1-anilino-8-naphthalene-sulfonic acid binding, near and far-UV circular dichroism and analytical ultracentrifugation. These studies revealed that in presence of gdnHCl AlaRS unfolded in a multistep pathway. At 0.8 M gdnHCl, AlaRS formed a molten globule like intermediate, which was enzymatically inactive. Further characterization of this intermediate proved that there was no oligomer breakdown at this denaturant concentration. This study clearly indicates that unlike many other oligomeric proteins AlaRS unfolding does not follow the hierarchical model as in this enzyme tertiary structure gets disrupted well before the disruption of quaternary interaction.

Critical role of zinc ion on E. coli glutamyl-queuosine-tRNA(Asp) synthetase (Glu-Q-RS) structure and function.

Glutamyl-queuosine-tRNA(Asp) synthetase (Glu-Q-RS) and glutamyl-tRNA synthetase (GluRS), differ widely by their function although they share close structural resemblance within their catalytic core of GluRS. In particular both Escherichia coli GluRS and Glu-Q-RS contain a single zinc-binding site in their putative tRNA acceptor stem-binding domain. It has been shown that the zinc is crucial for correct positioning of the tRNA(Glu) acceptor-end in the active site of E. coli GluRS. To address the role of zinc ion in Glu-Q-RS, the C101S/C103S Glu-Q-RS variant is constructed. Energy dispersive X-ray fluorescence show that the zinc ion still remained coordinated but the variant became structurally labile and acquired aggregation capacity. The extent of aggregation of the protein is significantly decreased in presence of the small substrates and more particularly by adenosine triphosphate. Addition of zinc increased significantly the solubility of the variant. The aminoacylation assay reveals a decrease in activity of the variant even after addition of zinc as compared to the wild-type, although the secondary structure of the protein is not altered as shown by the Fourier transform infrared spectroscopy study.

Characterization of DNA binding property of the HIV-1 host factor and tumor suppressor protein Integrase Interactor 1 (INI1/hSNF5).

Integrase Interactor 1 (INI1/hSNF5) is a component of the hSWI/SNF chromatin remodeling complex. The INI1 gene is either deleted or mutated in rhabdoid cancers like ATRT (Atypical terratoid and rhabdoid tumor). INI1 is also a host factor for HIV-1 replication. INI1 binds DNA non-specifically. However, the mechanism of DNA binding and its biological role are unknown. From agarose gel retardation assay (AGRA), Ni-NTA pull-down and atomic force microscopy (AFM) studies we show that amino acids 105-183 of INI1 comprise the minimal DNA binding domain (DBD). The INI1 DBD is absent in plants and in yeast SNF5. It is present in Caenorhabditis elegans SNF5, Drosophila melanogaster homologue SNR1 and is a highly conserved domain in vertebrates. The DNA binding property of this domain in SNR1, that is only 58% identical to INI1/hSNF5, is conserved. Analytical ultracentrifugation studies of INI1 DBD and INI1 DBD:DNA complexes at different concentrations show that the DBD exists as a monomer at low protein concentration and two molecules of monomer binds one molecule of DNA. At high protein concentration, it exists as a dimer and binds two DNA molecules. Furthermore, isothermal calorimetry (ITC) experiments demonstrate that the DBD monomer binds DNA with a stoichiometry (N) of ∼0.5 and Kd  = 0.94 µM whereas the DBD dimer binds two DNA molecules sequentially with K'd1 = 222 µM and K'd2 = 1.16 µM. Monomeric DBD binding to DNA is enthalpy driven (ΔH = -29.9 KJ/mole). Dimeric DBD binding to DNA is sequential with the first binding event driven by positive entropy (ΔH'1 = 115.7 KJ/mole, TΔS'1 = 136.8 KJ/mole) and the second binding event driven by negative enthalpy (ΔH'2 = -106.3 KJ/mole, TΔS'2 = -75.7 KJ/mole). Our model for INI1 DBD binding to DNA provides new insights into the mechanism of DNA binding by INI1.