Nalam Madhusudhana Rao

Thermostable Bacillus subtilis lipases: in vitro evolution and structural insight

In vitro evolution methods are now being routinely used to identify protein variants with novel and enhanced properties that are difficult to achieve using rational design. However, one of the limitations is in screening for beneficial mutants through several generations due to the occurrence of neutral/negative mutations occurring in the background of positive ones. While evolving a lipase in vitro from mesophilic Bacillus subtilis to generate thermostable variants, we have designed protocols that combine stringent three-tier testing, sequencing and stability assessments on the protein at the end of each generation. This strategy resulted in a total of six stabilizing mutations in just two generations with three mutations per generation. Each of the six mutants when evaluated individually contributed additively to thermostability. A combination of all of them resulted in the best variant that shows a remarkable 15 degrees C shift in melting temperature and a millionfold decrease in the thermal inactivation rate with only a marginal increase of 3 kcal mol(-1) in free energy of stabilization. Notably, in addition to the dramatic shift in optimum temperature by 20 degrees C, the activity has increased two- to fivefold in the temperature range 25-65 degrees C. High-resolution crystal structures of three of the mutants, each with 5 degrees increments in melting temperature, reveal the structural basis of these mutations in attaining higher thermostability. The structures highlight the importance of water-mediated ionic networks on the protein surface in imparting thermostability. Saturation mutagenesis at each of the six positions did not result in enhanced thermostability in almost all the cases, confirming the crucial role played by each mutation as revealed through the structural study. Overall, our study presents an efficient strategy that can be employed in directed evolution approaches employed for obtaining improved properties of proteins.

Enzyme field effect transistor (ENFET) for estimation of triglycerides using magnetic nanoparticles

Ion-selective field effect transistor (ISFET) is a robust platform to develop biosensors. A variety of methods are used including covalent attachment or polymer entrapment, to associate enzymes or antibodies to the gate surface of a FET. We have employed a novel method of retaining the enzyme molecules at the gate surface by immobilizing the enzyme on magnetic nickelferrite nanoparticles and applying a permanent magnet below the gate of the FET. We were able to estimate the triglyceride concentrations in the range of 0.1-1.5% by immobilizing a thermostable lipase on nanoparticles. Tributyrin, trioctanoate and triolein have given similar results. The reaction volume could be scaled down to 0.2ml without a loss in slope or sensitivity. Ionic strength (>150mM NaCl) has a strong influence on the sensitivity of the measurement. The advantages of this configuration of enzyme biosensor are reduction of mass transfer problems, increasing the amount of enzyme at the gate surface besides providing an opportunity to use a single FET device for multiple analyte detection.

Haloperidol-associated Stealth Liposomes A POTENT CARRIER FOR DELIVERING GENES TO HUMAN BREAST CANCER CELLS

Sigma receptors are membrane-bound proteins that are overexpressed in certain human malignancies including breast cancer. These receptors show very high affinity for various sigma ligands including neuroleptics like haloperidol. We hypothesized that in associating haloperidol-linked lipid into the cationic lipid-DNA complex, we can specifically target and deliver genes to breast cancer cells that overexpress sigma receptors. In the present study, haloperidol was chemically modified to conjugate at the distal end of the polyethylene glycollinked phospholipid, which was then incorporated into the cationic liposome known to condense and deliver genes inside cells. The resulting haloperidol-conjugated targeted lipoplex showed at least 10-fold higher (p < 0.001) reporter gene expression in MCF-7 cells than control lipoplex. The reporter gene expression of the targeted lipoplex was significantly blocked by haloperidol (p < 0.001) and by another sigma ligand, 1,3-ditolylguanidine (p < 0.001) in the majority of cationic lipid to DNA charge ratios (±). Spironolactone-mediated sigma receptor down-regulation enabled MCF-7 to show 10-fold lower transgene expression with targeted lipoplex compared with that obtained in spironolactone-untreated cells. The targeted lipoplex generated nonspecific gene expression in sigma receptor-nonexpressing human cancer cells such as Hela, KB, HepG2, and Chinese hamster ovary cells. Moreover, the transgene expression remained unabated in physiologically relevant serum concentrations. This is the first study to demonstrate that haloperidol-targeted gene delivery systems can mediate efficient targeting of genes to sigma receptor-overexpressing breast cancer cells, thereby becoming a novel class of therapeutics for the treatment of human cancers.

Lipase in aqueous‐polar organic solvents: Activity, structure, and stability

Studying alterations in biophysical and biochemical behavior of enzymes in the presence of organic solvents and the underlying cause(s) has important implications in biotechnology. We investigated the effects of aqueous solutions of polar organic solvents on ester hydrolytic activity, structure and stability of a lipase. Relative activity of the lipase monotonically decreased with increasing concentration of acetone, acetonitrile, and DMF but increased at lower concentrations (upto ∼20% v/v) of dimethylsulfoxide, isopropanol, and methanol. None of the organic solvents caused any appreciable structural change as evident from circular dichorism and NMR studies, thus do not support any significant role of enzyme denaturation in activity change. Change in 2D [15N, 1H]‐HSQC chemical shifts suggested that all the organic solvents preferentially localize to a hydrophobic patch in the active‐site vicinity and no chemical shift perturbation was observed for residues present in proteins core. This suggests that activity alteration might be directly linked to change in active site environment only. All organic solvents decreased the apparent binding of substrate to the enzyme (increased Km); however significantly enhanced the kcat. Melting temperature (Tm) of lipase, measured by circular dichroism and differential scanning calorimetry, altered in all solvents, albeit to a variable extent. Interestingly, although the effect of all organic solvents on various properties on lipase is qualitatively similar, our study suggest that magnitudes of effects do not appear to follow bulk solvent properties like polarity and the solvent effects are apparently dictated by specific and local interactions of solvent molecule(s) with the protein.

Recombinant fusion proteins TAT‐Mu, Mu and Mu‐Mu mediate efficient non‐viral gene delivery

The inherent ability of certain peptides or proteins of viral, prokaryotic and eukaryotic origin to bind DNA was used to generate novel peptide‐based DNA delivery protocols. We have developed a recombinant approach to make fusion proteins with motifs for DNA‐binding ability, Mu and membrane transduction domains, TAT, and tested them for their DNA‐binding, uptake and transfection efficiencies. In one of the constructs, the recombinant plasmid was designed to encode the Mu moiety of sequence MRRAHHRRRRASHRRMRGG in‐frame with TAT of sequence YGRKKRRQRRR to generate TAT‐Mu, while the other two constructs, Mu and Mu‐Mu, harbor a single copy or two copies of the Mu moiety.

Anchor dependency for non-glycerol based cationic lipofectins: mixed bag of regular and anomalous transfection profiles.

Although detailed structure-activity, physicochemical and biophysical investigations in probing the anchor influence in liposomal gene delivery have been reported for glycerol-based transfection lipids, the corresponding investigation for non-glycerol based simple monocationic transfection lipids have not yet been undertaken. Towards this end, herein, we delineate our structure-activity and physicochemical approach in deciphering the anchor dependency in liposomal gene delivery using fifteen new structural analogues (lipids 1-15) of recently reported non-glycerol based monocationic transfection lipids. The C(14) analogues in both series 1 (lipids 1-6) and series 2 (lipids 7-15) showed maximum efficiency in transfecting COS-1 and CHO cells. However, the C(12) analogue of the ether series (lipid 3) exhibited a seemingly anomalous behavior compared with its transfection efficient C(10) and C(14) analogues (lipids 2 and 4) in being completely inefficient to transfect both COS-1 and CHO cells. The present structure-activity investigation also convincingly demonstrates that enhancement of transfection efficiencies through incorporation of membrane reorganizing unsaturation elements in the hydrophobic anchor of cationic lipids is not universal but cell dependent. The strength of the interaction of lipids 1-15 with DNA was assessed by their ability to exclude ethidium bromide bound to the DNA. Cationic lipids with long hydrophobic tails were found, in general, to be efficient in excluding EtBr from DNA. Gel to liquid crystalline transition temperatures of the lipids was measured by fluorescence anisotropy measurement technique. In general (lipid 2 being an exception), transfection efficient lipids were found to have their mid transition temperatures at or below physiological temperatures (37 degrees C).

Thermally denatured state determines refolding in lipase: Mutational analysis

Irreversibility of thermally denatured proteins due to aggregation limits thermodynamic characterization of proteins and also confounds the identification of thermostable mutants in protein populations. Identification of mutations that prevent the aggregation of unfolded proteins provides insights into folding pathways. In a lipase from Bacillus subtilis, evolved by directed evolution procedures, the irreversibility due to temperature‐mediated aggregation was completely prevented by a single mutation, M137P. Though the parent and the mutants unfold completely on heating, mutants having substitutions M137P, along with M134E and S163P, completely or partially prevent the formation of aggregation‐prone intermediate(s) at 75°C. The three mutants show only a marginal increase in free energy of unfolding (ΔG  H 2O ), however, the profiles of the residual activity with temperature shows remarkable shift to higher temperature compared to parent. The intermediate(s) were characterized by enhanced binding of bis‐ANS, a probe to titrate surface hydrophobicity, aggregation profiles and by estimation of soluble protein. Inclusion of salt in the refolding conditions prevents the reversibility of mutant having charge substitution, while the reversibility of mutant with the introduction of proline was unaffected, indicating the role of charge mediated interaction in M134E in preventing aggregation. Partial prevention of thermal aggregation in wild‐type lipase with single substitution, M137P, incorporated by site‐directed mutagenesis, suggests that the affect of M137P is independent of the intrinsic thermostability of lipase. Various effects of the mutations suggest their role is in prevention of the formation of aggregation prone intermediate(s). These mutations, describe yet another strategy to enhance the thermotolerance of proteins, where their influence is observed only on the denatured ensemble.

Multiplex-PCR-based recombination as a novel high-fidelity method for directed evolution.

A new and convenient method for the in vitro recombination of single point mutations is presented. This method efficiently reduces the introduction of novel point mutations, which usually occur during recombination processes. A multiplex polymerase chain reaction (multiplex‐PCR) generates gene fragments that contain preformed point mutations. These fragments are subsequently assembled into full‐length genes by a recombination‐PCR step. The process of multiplex‐PCR‐based recombination (MUPREC) does not require DNase I digestion for gene‐fragmentation and is therefore easy to perform, even with small amounts of target DNA. The protocol yields high frequencies of recombination without creating a wild‐type background. Furthermore, the low error rate results in high‐quality variant libraries of true recombinants, thereby minimizing the screening efforts and saving time and money. The MUPREC method was used in the directed evolution of a Bacillus subtilis lipase that can catalyse the enantioselective hydrolysis of a model meso‐compound. Thereby, the method was proved to be useful in producing a reliable second‐generation library of true recombinants from which better performing variants were identified by using a high‐throughput electrospray ionization mass spectrometry (ESI‐MS) screening system.

Engineering the loops in a lipase for stability in DMSO

Nearly 65% of the surface of a lipase, from Bacillus subtilis, is occupied by the loops. Since the loops are dynamic components of a protein, located on the surface and are tolerant to substitutions, we subjected all 91 amino acids of the loops to site saturation mutagenesis to identify mutations that improve the stability and activity of lipase in dimethyl sulfoxide (DMSO). Based on a novel screening system, we have identified six positions in the lipase, from a population of 18,000 transformants that contributed to higher activity in DMSO. We combined all the six mutations into one lipase gene (6SR), purified the protein to study its activity and structural properties. 6SR has shown eight times higher catalytic turnover in 60% DMSO and showed a marginal shift in DMSO tolerance. 6SR showed a similar secondary structure with little alteration in tertiary structure. The melting temperature of 6SR is lower than the wild type and binds the least to hydrophobic fluorescent probes, indicating that the surface has become more polar in nature. This study provides clues to the role of loop amino acids in modulating the activity in organic solvents.

Quantitative aspects of endocytic activity in lipid-mediated transfections

Variation in transfection efficiency observed in different cell‐types is poorly understood. To investigate the influence of endocytic activity on lipid‐mediated transfections, we have monitored both the processes in 12 different cell‐types. The endocytic activity shows a strong positive correlation (P < 0.01), with transfection efficiency. Treatment with wortmannin resulted in cell‐type‐dependent inhibition of transfection. Studies on M‐phase cells by confocal microscopy show that compared to interphase cells, uptake of cationic liposomes was substantially reduced. In addition, transfection efficiency of cells in mitotic phase was inhibited by >70% compared to controls. Our study based on several cell‐types demonstrates for the first time that quantitative aspects of endocytosis have decisive influence on the overall process of lipid‐mediated transgene expression.