Iterative cloning, overexpression, purification and isotopic labeling of an engineered dimer of a Ca(2+)-binding protein of the βγ-crystallin superfamily from Methanosarcina acetivorans

βγ-Crystallins are a large superfamily of proteins found in vertebrate eye lens. They are hetero-dimers (linked in tandem by a specific peptide) and are shown to bind calcium. The monomers possess two β-strand rich greek-key motifs. Recently, a structurally closest member to the family of lens βγ-crystallins has been described, for the first time, from the archaea Methanosarcina acetivorans, which is named as M-crystallin. Unlike lens βγ-crystallins, M-crystallin exits as a monomer. Here, we synthesized a dimeric gene of M-crystallin in which two monomers are linked by a 10-amino acid residue coding sequence. The linker sequence in the target protein is long and flexible enough to reduce the proximity between the individual crystallins in the dimer. This methodology would be highly beneficial in designing polyproteins (two or more proteins linked in tandem to aid mechanical stretching studies) that are regularly used in single-molecule force spectroscopy. The dimer of M-crystallin was overexpressed in Escherichia coli BLR(DE3) strain. The overexpressed protein containing an N-terminal hexa-histidine tag was purified using nickel affinity chromatography and then by size-exclusion chromatography. Further, a method to purify isotopically ((15)N) labeled protein with high yield for NMR studies is reported. The uniformly (15)N-labeled M-crystallin dimer thus produced has been characterized by recording sensitivity enhanced 2D [(15)N-(1)H] HSQC and other optical spectroscopy techniques. Observation of only one set of peaks in the HSQC, along with the structural characterization using optical spectroscopy, suggests that the domains in the dimer possess similar structure as that of the monomer.     

Conformational heterogeneity and dynamics in a βγ-crystallin from Hahella chejuensis

Most of the βγ-crystallins are structural proteins with high intrinsic stability, which gets enhanced by Ca(2+)-binding in microbial members. Functions of most of these proteins are yet to be known. However, a few of them were reported to be involved in Ca(2+)-dependent and stress-related functions. Hahellin, a microbial homolog, is a natively unfolded protein that acquires a well-folded structure upon Ca(2+) binding. Although the structure of βγ-crystallin domains is well understood, the dynamical features are yet to be explored. We have investigated for the first time the equilibrium dynamics, conformational heterogeneity and associated low-lying free-energy states of hahellin in its Ca(2+)-bound form using NMR spectroscopy to understand the dynamics of a βγ-crystallin domain. Hahellin shows large conformational heterogeneity with nearly 40% of the residues, some of which are part of Ca(2+)-binding loops, accessing alternative states. Further, out of the two Greek key motifs, which together constitute the βγ-crystallin domain, the second Greek key motif is floppy as compared to its relatively rigid counterpart. Taken together, we believe that these characteristics might be of importance to understand the stability and functions of βγ-crystallin domains.     

Structural change in a B-DNA helix with hydrostatic pressure

Study of the effects of pressure on macromolecular structure improves our understanding of the forces governing structure, provides details on the relevance of cavities and packing in structure, increases our understanding of hydration and provides a basis to understand the biology of high-pressure organisms. A study of DNA, in particular, helps us to understand how pressure can affect gene activity. Here we present the first high-resolution experimental study of B-DNA structure at high pressure, using NMR data acquired at pressures up to 200 MPa (2 kbar). The structure of DNA compresses very little, but is distorted so as to widen the minor groove, and to compress hydrogen bonds, with AT pairs compressing more than GC pairs. The minor groove changes are suggested to lead to a compression of the hydration water in the minor groove.     

<Superscript>1</Superscript>H, <Superscript>13</Superscript>C and <Superscript>15</Superscript>N NMR assignments of a bacterial immunoglobulin-like domain (group 2) of a protein of a bacterium <Emphasis Type="Italic">Paenarthrobacter aurescens</Emphasis> TC1

The bacterial immunoglobulin-like (Big) domain is one of the prevalent domain types, which facilitates cell–cell adhesion by assembling into multi-domain architectures. We selected a four Big_2 domain protein (named ‘Arig’) from a Gram positive, Paenarthrobacter aurescens TC1 (known earlier as Arthrobacter aurescens TC1). In an attempt to characterize structural and ligand-binding features of individual Big_2 domains, we have cloned, overexpressed, isolated and purified the second Big_2 domain of Arig along with a few of its adjacent Big_2 domain residues (residue 143 to 269) referred to as ‘Arig2’. The ¹³C/¹⁵N-doubly-labeled His-tagged Arig2 (133 residues long) showed an ordered conformation as revealed by the well dispersed 2D [¹⁵N-¹H]-HSQC spectrum. Subsequently, a suite of heteronuclear 3D NMR experiments has enabled almost complete ¹H, ¹³C and ¹⁵N NMR resonance assignments of Arig2.     

Synthesis, SAR, and antibacterial activity of novel oxazolidinone analogues possessing urea functionality

The syntheses of a number of novel oxazolidinone analogues possessing an urea functionality are reported. While the urea derivatives possessing aliphatic and aromatic groups were prepared by the more conventional isocyanate method, the derivatives possessing heterocyclic rings were synthesized by a relatively uncommon but otherwise efficient carbamate chemistry. Though the SAR resulted in novel compounds possessing in vitro activity equivalent to Linezolid, the compounds possess a range of substituents that are amenable for altering physicochemical properties of the resultant drug. The antibacterial activity was found to be not sensitive to the functional groups attached to the urea site regardless of the size and electronic characteristics. Based on in vivo results, one molecule has been identified as a candidate and additional work such as salt selection, scale-up, etc., are currently underway to take the molecule further through development.     

Incoming nucleotide binds to Klenow ternary complex leading to stable physical sequestration of preceding dNTP on DNA

Klenow–DNA complex is known to undergo a rate-limiting, protein conformational transition from an ‘open’ to ‘closed’ state, upon binding of the ‘correct’ dNTP at the active site. In the ‘closed’ state, Mg²⁺ mediates a rapid chemical step involving nucleophilic displacement of pyrophosphate by the 3′ hydroxyl of the primer terminus. The enzyme returns to the ‘open’ state upon the release of PPi and translocation permits the next round of reaction. To determine whether Klenow can translocate to the next site on the addition of the next dNTP, without the preceding chemical step, we studied the ternary complex (Klenow–DNA–dNTP) in the absence of Mg²⁺. While the ternary complex is proficient in chemical addition of dNTPs in Mg²⁺, as revealed by primer extensions, the same in Mg²⁺-deficient conditions lead to non-covalent (physical) sequestration of first two ‘correct’ dNTPs in the ternary complex. Moreover, the second dNTP traps the first one in the DNA-helix of the ternary complex. Such a dNTP–DNA complex is found to be stable even after the dissociation of Klenow. This reveals the novel state of the dNTP–DNA complex where the complementary base is stacked in a DNA-helix non-covalently, without the phosphodiester linkage. Further, shuttling of the DNA between the polymerase and the exonuclease site mediates the release of such a DNA complex. Interestingly, Klenow in such a Mg²⁺-deficient ternary complex exhibits a ‘closed’ conformation.