Grzegorz Piszczek

High-Precision Isothermal Titration Calorimetry with Automated Peak Shape Analysis

Isothermal titration calorimetry (ITC) is a powerful classical method that enables researchers in many fields to study the thermodynamics of molecular interactions. Primary ITC data comprise the temporal evolution of differential power reporting the heat of reaction during a series of injections of aliquots of a reactant into a sample cell. By integration of each injection peak, an isotherm can be constructed of total changes in enthalpy as a function of changes in solution composition, which is rich in thermodynamic information on the reaction. However, the signals from the injection peaks are superimposed by the stochastically varying time-course of the instrumental baseline power, limiting the precision of ITC isotherms. Here, we describe a method for automated peak assignment based on peak-shape analysis via singular value decomposition in combination with detailed least-squares modeling of local pre- and postinjection baselines. This approach can effectively filter out contributions of short-term noise and adventitious events in the power trace. This method also provides, for the first time, statistical error estimates for the individual isotherm data points. In turn, this results in improved detection limits for high-affinity or low-enthalpy binding reactions and significantly higher precision of the derived thermodynamic parameters.

SEDPHAT – A platform for global ITC analysis and global multi-method analysis of molecular interactions

Isothermal titration calorimetry experiments can provide significantly more detailed information about molecular interactions when combined in global analysis. For example, global analysis can improve the precision of binding affinity and enthalpy, and of possible linkage parameters, even for simple bimolecular interactions, and greatly facilitate the study of multi-site and multi-component systems with competition or cooperativity. A pre-requisite for global analysis is the departure from the traditional binding model, including an n-value describing unphysical, non-integral numbers of sites. Instead, concentration correction factors can be introduced to account for either errors in the concentration determination or for the presence of inactive fractions of material. SEDPHAT is a computer program that embeds these ideas and provides a graphical user interface for the seamless combination of biophysical experiments to be globally modeled with a large number of different binding models. It offers statistical tools for the rigorous determination of parameter errors, correlations, as well as advanced statistical functions for global ITC (gITC) and global multi-method analysis (GMMA). SEDPHAT will also take full advantage of error bars of individual titration data points determined with the unbiased integration software NITPIC. The present communication reviews principles and strategies of global analysis for ITC and its extension to GMMA in SEDPHAT. We will also introduce a new graphical tool for aiding experimental design by surveying the concentration space and generating simulated data sets, which can be subsequently statistically examined for their information content. This procedure can replace the c-value as an experimental design parameter, which ceases to be helpful for multi-site systems and in the context of gITC.

Tubulin tyrosine ligase structure reveals adaptation of an ancient fold to bind and modify tubulin

Tubulin tyrosine ligase (TTL) catalyzes the post-translational C-terminal tyrosination of α-tubulin. Tyrosination regulates recruitment of microtubule-interacting proteins. TTL is essential. Its loss causes morphogenic abnormalities and is associated with cancers of poor prognosis. We present the first crystal structure of TTL (from Xenopus tropicalis), defining the structural scaffold upon which the diverse TTL-like family of tubulin-modifying enzymes is built. TTL recognizes tubulin using a bipartite strategy. It engages the tubulin tail through low-affinity, high-specificity interactions, and co-opts what is otherwise a homo-oligomerization interface in structurally related ATP grasp-fold enzymes to form a tight hetero-oligomeric complex with the tubulin body. Small-angle X-ray scattering and functional analyses reveal that TTL forms an elongated complex with the tubulin dimer and prevents its incorporation into microtubules by capping the tubulin longitudinal interface, possibly modulating the partition of tubulin between monomeric and polymeric forms.

Glutathionylation of peroxiredoxin I induces decamer to dimers dissociation with concomitant loss of chaperone activity.

Reversible protein glutathionylation, a redox-sensitive regulatory mechanism, plays a key role in cellular regulation and cell signaling. Peroxiredoxins (Prxs), a family of peroxidases that is involved in removing H(2)O(2) and organic hydroperoxides, are known to undergo a functional change from peroxidase to molecular chaperone upon overoxidation of its catalytic cysteine. The functional change is caused by a structural change from low molecular weight oligomers to high molecular weight complexes that possess molecular chaperone activity. We reported earlier that Prx I can be glutathionylated at three of its cysteine residues, Cys52, -83, and -173 [Park et al. (2009) J. Biol. Chem., 284, 23364]. In this study, using analytical ultracentrifugation analysis, we reveal that glutathionylation of Prx I, WT, or its C52S/C173S double mutant shifted its oligomeric status from decamers to a population consisting mainly of dimers. Cys83 is localized at the putative dimer-dimer interface, implying that the redox status of Cys83 may play an important role in stabilizing the oligomeric state of Prx I. Studies with the Prx I (C83S) mutant show that while Cys83 is not essential for the formation of high molecular weight complexes, it affects the dimer-decamer equilibrium. Glutathionylation of the C83S mutant leads to accumulation of dimers and monomers. In addition, glutathionylation of Prx I, both the WT and C52S/C173S mutants, greatly reduces their molecular chaperone activity in protecting citrate synthase from thermally induced aggregation. Together, these results reveal that glutathionylation of Prx I promotes changes in its quaternary structure from decamers to smaller oligomers and concomitantly inactivates its molecular chaperone function.

Biochemical, proteomic, structural, and thermodynamic characterizations of integrin-linked kinase (ILK): cross-validation of the pseudokinase.

Integrin-linked kinase (ILK) is one of the few evolutionarily conserved focal adhesion proteins involved in diverse cell adhesion-dependent physiological and pathological responses. Despite more than a decade of studies and extensive literature, the kinase function of ILK is controversial. ILK contains a highly degraded kinase active site but it has been argued that ILK may be an unusual manganese (Mn)-dependent serine-threonine kinase that targets specific substrates such as glycogen synthase kinase-3β (GSK-3β). In this study, we have tackled this issue by a systematic bottom-up biochemical, proteomic, structural, and thermodynamic analysis of ILK. We show that recombinant ILK from either bacteria or mammalian cells exhibits no kinase activity on GSK-3β in the presence of either Mn2+ or the conventional kinase co-factor Mg2+. A comprehensive and unbiased whole cell-based kinase assay using entire mammalian CG-4 and C2C12 cell lysate did not identify any specific ILK substrates. High resolution crystallographic structure analysis further confirmed that the Mn-bound ILK adopts the same pseudo active site conformation as that of the Mg-bound ILK. More importantly, thermodynamic analysis revealed that the K220M mutation, previously thought to inactivate ILK by disrupting ATP binding, significantly impairs the structural integrity and stability of ILK, which provides a new basis for understanding how this mutation caused renal agenesis, a failure of fetal kidney development. Collectively, our data provide strong evidence that ILK lacks intrinsic kinase function. It is a bona fide pseudokinase that likely evolved from an ancestral catalytic counterpart to act as a distinct scaffold to mediate protein-protein interactions during focal adhesion assembly and many other cellular events.

Recorded scan times can limit the accuracy of sedimentation coefficients in analytical ultracentrifugation.

We report systematic and large inaccuracies in the recorded elapsed time in data files from the analytical ultracentrifuge, leading to overestimates of the sedimentation coefficients of up to 10%. This far exceeds previously considered factors contributing to the uncertainty in this parameter and has significant ramifications for derived parameters such as hydrodynamic shape and molar mass estimates. The source of this error is currently unknown, but we found it to be quantitatively consistent across different instruments, increasing with rotor speed. Furthermore, its occurrence appears to correlate with the use of the latest data acquisition software from the manufacturer, in use in some of our laboratories for nearly 2 years. Many of the recently published sedimentation coefficients may need to be reexamined. The problem can be easily recognized by comparing the file timestamps provided by the operating system with the elapsed scan times recorded within the data files. Therefore, we implemented a routine in SEDFIT that can automatically examine the data files, alert the user to significant discrepancies, and correct the scan times accordingly. This eliminates errors in the recorded scan times.

Solution NMR Characterizations of Oligomerization and Dynamics of Equine Infectious Anemia Virus Matrix Protein and Its Interaction with PIP2

Budding of retroviruses requires the structural precursor polyprotein, Gag, to target the plasma membrane through its N-terminal matrix (MA) domain. For HIV-1, the interaction between membrane signaling molecule phosphatidylinositol 4,5-diphosphate (PIP2) and MA induces the exposure of myristate and promotes membrane binding. Here we studied oligomerization of the naturally unmyristylated equine infectious anemia virus (EIAV) MA and its interaction with PIP2-C4 primarily using solution NMR spectroscopy. The measured 1H-15N residual dipolar coupling agrees with the atomic coordinates from the EIAV MA crystal structure. The analytical ultracentrifugation results show a dominant population of monomeric EIAV MA at a concentration of 63 microM and 20 degrees C, along with a small trimer and a broad distribution of other oligomers. The monomer-trimer equilibrium model and the quaternary packing of the trimer were further established by the concentration-dependent 15N spin relaxation rates and chemical shifts. Binding of MA to PIP2-C4 was detected by chemical shift mapping (CSM) with an apparent Kd of 182 +/- 56 microM, a value similar to that reported for HIV-1 MA. The PIP2 binding site includes the Loop region between Helix2 and Helix3 in the EIAV MA. CSM and spin relaxation dispersion reveal a coupling of conformational change and submillisecond dynamics, respectively, between the Loop and trimeric Interface Residues due to PIP2 binding. We infer that PIP2 participates in the initial trimer formation of EIAV MA, but more importantly, the concentration effect is dominant in shifting the equilibrium toward trimer, in line with the entropic switch mechanism proposed for myristylated HIV-1 MA.

Novel Protective Mechanism against Irreversible Hyperoxidation of Peroxiredoxin Nα-TERMINAL ACETYLATION OF HUMAN PEROXIREDOXIN II

Peroxiredoxins (Prxs) are a group of peroxidases containing a cysteine thiol at their catalytic site. During peroxidase catalysis, the catalytic cysteine, referred to as the peroxidatic cysteine (CP), cycles between thiol (CP-SH) and disulfide (–S–S–) states via a sulfenic (CP-SOH) intermediate. Hyperoxidation of the CP thiol to its sulfinic (CP-SO2H) derivative has been shown to be reversible, but its sulfonic (CP-SO3H) derivative is irreversible. Our comparative study of hyperoxidation and regeneration of Prx I and Prx II in HeLa cells revealed that Prx II is more susceptible than Prx I to hyperoxidation and that the majority of the hyperoxidized Prx II formation is reversible. However, the hyperoxidized Prx I showed much less reversibility because of the formation of its irreversible sulfonic derivative, as verified with CP-SO3H-specific antiserum. In an attempt to identify the multiple hyperoxidized spots of the Prx I on two-dimensional PAGE analysis, an N-acetylated Prx I was identified as part of the total Prx I using anti-acetylated Lys antibody. Using peptidyl-Asp metalloendopeptidase (EC 3.4.24.33) peptide fingerprints, we found that Nα-terminal acetylation (Nα-Ac) occurred exclusively on Prx II after demethionylation. Nα-Ac of Prx II blocks Prx II from irreversible hyperoxidation without altering its affinity for hydrogen peroxide. A comparative study of non-Nα-acetylated and Nα-terminal acetylated Prx II revealed that Nα-Ac of Prx II induces a significant shift in the circular dichroism spectrum and elevation of Tm from 59.6 to 70.9 °C. These findings suggest that the structural maintenance of Prx II by Nα-Ac may be responsible for preventing its hyperoxidation to form CP-SO3H.

Improving the Thermal, Radial and Temporal Accuracy of the Analytical Ultracentrifuge through External References

Sedimentation velocity (SV) is a method based on first principles that provides a precise hydrodynamic characterization of macromolecules in solution. Due to recent improvements in data analysis, the accuracy of experimental SV data emerges as a limiting factor in its interpretation. Our goal was to unravel the sources of experimental error and develop improved calibration procedures. We implemented the use of a Thermochron iButton temperature logger to directly measure the temperature of a spinning rotor and detected deviations that can translate into an error of as much as 10% in the sedimentation coefficient. We further designed a precision mask with equidistant markers to correct for instrumental errors in the radial calibration that were observed to span a range of 8.6%. The need for an independent time calibration emerged with use of the current data acquisition software (Zhao et al., Anal. Biochem., 437 (2013) 104-108), and we now show that smaller but significant time errors of up to 2% also occur with earlier versions. After application of these calibration corrections, the sedimentation coefficients obtained from 11 instruments displayed a significantly reduced standard deviation of approximately 0.7%. This study demonstrates the need for external calibration procedures and regular control experiments with a sedimentation coefficient standard.

The G18V CRYGS mutation associated with human cataracts increases γS-crystallin sensitivity to thermal and chemical stress

GammaS-crystallin, important in maintaining lens transparency, is a monomeric betagamma-crystallin comprising two paired homologous domains, each with two Greek key motifs. An autosomal dominant cortical progressive cataract has been associated with a G18V mutation in human gammaS-crystallin. To investigate the molecular mechanism of this cataract and confirm the causative nature of the G18V mutation, we examined resultant changes in conformation and stability. Human gammaS-crystallin cDNA was cloned into pET-20b(+), and the G18V mutant was generated by site-directed mutagenesis. Recombinant HgammaS-crystallins were expressed in Escherichia coli and purified by ion-exchange and size-exclusion chromatography. By analytical ultracentrifugation wild-type and mutant HgammaS-crystallins are monomers of about 21.95 +/- 0.21 and 20.89 +/- 0.18 kDa, respectively, and have similar secondary structures by far-UV CD. In increasing levels of guanidine hydrochloride (GuHCl), a sharp red shift in fluorescence lambda(max) and increase in emission correlating with exposure of tryptophans to the protein surface are detected earlier in the mutant protein. Under thermal stress, the G18V mutant begins to show changes in tryptophan fluorescence above 42 degrees C and shows a Tm of 65 degrees C as monitored by CD at 218 nm, while wild-type HgammaS-crystallin is very stable with Tm values of 75.5 and 75.0 degrees C as measured by fluorescence and CD, respectively. Equilibrium unfolding/refolding experiments as a function of GuHCl confirm the relative instability of the G18V mutant. Wild-type HgammaS-crystallin exhibits a two-state transition and reversible refolding above 1.0 M GuHCl, but the unfolding transition of mutant HgammaS-crystallin shows an intermediate state. The first transition (N --> I) shows a [GuHCl](1/2) of 0.5 M while the second transition (I --> U) has the same [GuHCl](1/2) as wild-type HgammaS-crystallin, about 2.0 M. Our present study confirms the high stability of wild-type HgammaS-crystallin and demonstrates that the G18V mutation destabilizes the protein toward heat and GuHCl-induced unfolding. These biophysical characteristics are consistent with the progressive cataract formation seen in the family members carrying this mutation.