Ranajeet Ghose

A novel, specific interaction involving the Csk SH3 domain and its natural ligand

C-terminal Src kinase (Csk) takes part in a highly specific, high affinity interaction via its Src homology 3 (SH3) domain with the proline-enriched tyrosine phosphatase PEP in hematopoietic cells. The solution structure of the Csk-SH3 domain in complex with a 25-residue peptide from the Pro/Glu/Ser/Thr-rich (PEST) domain of PEP reveals the basis for this specific peptide recognition motif involving an SH3 domain. Three residues, Ala 40, Thr 42 and Lys 43, in the SH3 domain of Csk specifically recognize two hydrophobic residues, Ile 625 and Val 626, in the proline-rich sequence of the PEST domain of PEP. These two residues are C-terminal to the conventional proline-rich SH3 domain recognition sequence of PEP. This interaction is required in addition to the classic polyproline helix (PPII) recognition by the Csk-SH3 domain for the association between Csk and PEP in vivo. NMR relaxation analysis suggests that Csk-SH3 has different dynamic properties in the various subsites important for peptide recognition.

Structure and Dynamics of ASC2, a Pyrin Domain-only Protein That Regulates Inflammatory Signaling

Pyrin domain (PYD)-containing proteins are key components of pathways that regulate inflammation, apoptosis, and cytokine processing. Their importance is further evidenced by the consequences of mutations in these proteins that give rise to autoimmune and hyperinflammatory syndromes. PYDs, like other members of the death domain (DD) superfamily, are postulated to mediate homotypic interactions that assemble and regulate the activity of signaling complexes. However, PYDs are presently the least well characterized of all four DD subfamilies. Here we report the three-dimensional structure and dynamic properties of ASC2, a PYD-only protein that functions as a modulator of multidomain PYD-containing proteins involved in NF-κB and caspase-1 activation. ASC2 adopts a six-helix bundle structure with a prominent loop, comprising 13 amino acid residues, between helices two and three. This loop represents a divergent feature of PYDs from other domains with the DD fold. Detailed analysis of backbone 15N NMR relaxation data using both the Lipari-Szabo model-free and reduced spectral density function formalisms revealed no evidence of contiguous stretches of polypeptide chain with dramatically increased internal motion, except at the extreme N and C termini. Some mobility in the fast, picosecond to nanosecond timescale, was seen in helix 3 and the preceding α2-α3 loop, in stark contrast to the complete disorder seen in the corresponding region of the NALP1 PYD. Our results suggest that extensive conformational flexibility in helix 3 and the α2-α3 loop is not a general feature of pyrin domains. Further, a transition from complete disorder to order of the α2-α3 loop upon binding, as suggested for NALP1, is unlikely to be a common attribute of pyrin domain interactions.

Accurate Sampling of High-Frequency Motions in Proteins by Steady-State 15N−{1H} Nuclear Overhauser Effect Measurements in the Presence of Cross-Correlated Relaxation

The steady-state {(1)H}-(15)N NOE experiment is used in most common NMR analyses of backbone dynamics to accurately ascertain the effects of the fast dynamic modes. We demonstrate here that, in its most common implementation, this experiment generates an incorrect steady state in the presence of CSA/dipole cross-correlated relaxation leading to large errors in the characterization of these high-frequency modes. This affects both the quantitative and qualitative interpretation of (15)N backbone relaxation in dynamic terms. We demonstrate further that minor changes in the experimental implementation effectively remove these errors and allow a more accurate interpretation of protein backbone dynamics.

NMR structure determination and investigation using a reduced proton (REDPRO) labeling strategy for proteins

We present here a stable isotope labeling technique for proteins, which seeks the appropriate compromise between the advantages of (a) random isotope labeling, with its large number of protons available for structure determination, and (b) selective labeling to generate isolated proton spins decreasing spectral complexity and improving relaxation properties of NMR experiments. The described reduced proton (REDPRO) procedure results in side‐chain specific protonation of overexpressed proteins, which is highly selective. The REDPRO labeling scheme provides a sufficient number of NOE constraints for structure calculation. Dramatically improved relaxation properties of the heteronuclear magnetization transfer coupled with TROSY advantages make the proposed labeling scheme an attractive approach for study of high molecular weight protein targets, their ligand sites, and interdomain interactions.

Efficient determination of angles subtended by C(alpha)-H(alpha) and N-H(N) vectors in proteins via dipole-dipole cross-correlation

The angle ΘCαHα,NHN subtended by the internuclear vectors 13Cα-Hα and 15N-HN in doubly-labeled proteins can be determined by observing the effect of cross-correlation between the dipolar interactions on zero- and double-quantum coherences involving 13Cα and 15N. Two complementary 2D experiments with the appearance of 15N-HN correlation spectra yield signal intensities that depend on the rate of interconversion through cross-correlated relaxation of in-phase and doubly antiphase zero- and double-quantum coherences. The ratio of the signal intensities in the two experiments bears a simple relationship to the cross-correlation rate, and hence to the angle ΘCαHα,NHN. Assuming planarity of the peptide bond, the dihedral angle Ψ (between Cα and C′) can be determined from the knowledge of ΘCαHα,NHN. The experiments are very time-effective and provide good sensitivity and excellent spectral resolution.

Solution NMR insights into docking interactions involving inactive ERK2.

The mitogen-activated protein (MAP) kinase ERK2 contains recruitment sites that engage canonical and noncanonical motifs found in a variety of upstream kinases, regulating phosphatases and downstream targets. Interactions involving two of these sites, the D-recruitment site (DRS) and the F-recruitment site (FRS), have been shown to play a key role in signal transduction by ERK/MAP kinases. The dynamic nature of these recruitment events makes NMR uniquely suited to provide significant insight into these interactions. While NMR studies of kinases in general have been greatly hindered by their large size and complex dynamic behavior leading to the suboptimal performance of standard methodologies, we have overcome these difficulties for inactive full-length ERK2 and obtained an acceptable level of backbone resonance assignments. This allowed a detailed investigation of the structural perturbations that accompany interactions involving both canonical and noncanonical recruitment events. No crystallographic information exists for the latter. We found that the chemical shift perturbations in inactive ERK2, indicative of structural changes in the presence of canonical and noncanonical motifs, are not restricted to the recruitment sites but also involve the linker that connects the N- and C-lobes and, in most cases, a gatekeeper residue that is thought to exert allosteric control over catalytic activity. We also found that, even though the canonical motifs interact with the DRS utilizing both charge-charge and hydrophobic interactions, the noncanonical interactions primarily involve the latter. These results demonstrate the feasibility of solution NMR techniques for a comprehensive analysis of docking interactions in a full-length ERK/MAP kinase.

Simultaneous determination of y and F angles in proteins from measurements of cross-correlated relaxation effects

AbstractA method is presented to determine both φ and ψ backbone angles in proteins simultaneously. This is achieved by measuring the effect on two-spin coherences of cross-correlation between 15 N-1HN and 13

Dynamics on multiple timescales in the RNA-directed RNA polymerase from the cystovirus ϕ6

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