Sonja A. Dames

NMR- and Circular Dichroism-monitored Lipid Binding Studies Suggest a General Role for the FATC Domain as Membrane Anchor of Phosphatidylinositol 3-Kinase-related Kinases (PIKK)

Background: PIKKs regulate cellular processes such as growth, DNA repair, and stress responses. Results: The ATM, ATR, DNA-PKcs, SMG-1, and TRRAP FATC domains interact with membrane mimetics, resulting in an increase of α-helical secondary structure. Conclusion: All PIKK FATC domains may function as membrane anchors. Significance: The regulation of PIKK localization by a network of interactions may allow a specific and localized cellular signaling output. The FATC domain is shared by all members of the family of phosphatidylinositol-3 kinase-related kinases (PIKKs). It has been shown that the FATC domain plays an important role for the regulation of each PIKK. However, other than an involvement in protein-protein interactions, a common principle for the action of the FATC domain has not been detected. A detailed characterization of the structure and lipid binding properties of the FATC domain of the Ser/Thr kinase target of rapamycin (TOR) revealed that it contains a redox-sensitive membrane anchor in its C terminus. Because the C-terminal regions of the FATC domains of all known PIKKs are rather hydrophobic and especially rich in aromatic residues, we examined whether the ability to interact with lipids and membranes might be a general property. Here, we present the characterization of the interactions with lipids and different membrane mimetics for the FATC domains of human DNA-PKcs, human ATM, human ATR, human SMG-1, and human TRRAP by NMR and CD spectroscopy. The data indicate that all of these can interact with different membrane mimetics and may have different preferences only for membrane properties such as surface charge, curvature, and lipid packing. The oxidized form of the TOR FATC domain is well structured overall and forms an α-helix that is followed by a disulfide-bonded loop. In contrast, the FATC domains of the other PIKKs are rather unstructured in the isolated form and only significantly populate α-helical secondary structure upon interaction with membrane mimetics.

A fast and simple method for probing the interaction of peptides and proteins with lipids and membrane-mimetics using GB1 fusion proteins and NMR spectroscopy.

The expression of peptides and proteins as fusions to the B1 domain of streptococcal protein G (GB1) is very popular since GB1 often improves the solubility of the target protein and because the first purification step using IgG affinity chromatography is simple and efficient. However, the following protease digest is not always complete or can result in a digest of the target protein. In addition, a further purification step such as RP‐HPLC has to be used to get rid of the GB1 tag and undigested fusion protein. Because the protease digest and the following purification step are not only time‐consuming but generally also expensive, we tested if GB1 fusion proteins can directly be used for NMR interaction studies using lipids or membrane‐mimetics. Based on NMR binding studies using only the GB1 part, this fusion tag does not significantly interact with different membrane‐mimetics such as micelles, bicelles, or liposomes. Thus spectral changes observed using GB1‐fusion proteins indicate lipid‐ and membrane interactions of the target protein. The method was initially established to probe membrane interactions of a large number of mutants of the FATC domain of the ser/thr kinase TOR. To demonstrate the usefulness of the approach, we show NMR binding data for the wild type protein and a leucine to alanine mutant.

Subtype-specific modulation of estrogen receptor-coactivator interaction by phosphorylation.

The estrogen receptor (ER) is the number one target for the treatment of endocrine responsive breast cancer and remains a highly attractive target for new drug development. Despite considerable efforts to understand the role of ER post-translational modifications (PTMs), the complexity of these modifications and their impact, at the molecular level, are poorly understood. Using a chemical biology approach, fundamentally rooted in an efficient protein semisynthesis of tyrosine phosphorylated ER constructs, the complex role of the ER tyrosine phosphorylation is addressed here for the first time on a molecular level. The semisynthetic approach allows for the site-specific introduction of PTMs as well as biophysical probes. A combination of biophysical techniques, including NMR, with molecular dynamics studies reveals the role of the phosphorylation of the clinically relevant tyrosine 537 (Y537) in ERα and the analogous tyrosine (Y488) in ERβ. Phosphorylation has important effects on the dynamics of the ER Helix 12, which is centrally involved in receptor activity regulation, and on its interplay with ligand and cofactor binding, but with differential regulatory effects of the analogous PTMs on the two ER subtypes. Combined, the results bring forward a novel molecular model of a phosphorylation-induced subtype specific ER modulatory mechanism, alternative to the widely accepted ligand-induced activation mechanism.

Characterization of residue-dependent differences in the peripheral membrane association of the FATC domain of the kinase ‘target of rapamycin’ by NMR and CD spectroscopy

The conserved C‐terminal FATC domain of the kinase ‘target of rapamycin’ is important for its regulation and was suggested to contain a peripheral membrane anchor. Here, we present the characterization of the interactions of the yeast TOR1 FATC domain (2438–2470 = y1fatc) and 15 mutants with membrane mimetic micelles, bicelles, and small unilamellar vesicles (SUVs) by NMR and CD spectroscopy. Replacement of up to 6–7 residues did not result in a significant abrogation of the association with micelles or bicelles. However, replacement of only one residue could result in an impairment of the interaction with SUVs that are usually used at low concentrations. Some mutants not binding liposomes may be introduced in full‐length TOR for future functional and localization studies in vivo.

Oxidative Unfolding of the Rubredoxin Domain and the Natively Disordered N-terminal Region Regulate the Catalytic Activity of Mycobacterium tuberculosis Protein Kinase G.

Mycobacterium tuberculosis escapes killing in human macrophages by secreting protein kinase G (PknG). PknG intercepts host signaling to prevent fusion of the phagosome engulfing the mycobacteria with the lysosome and, thus, their degradation. The N-terminal NORS (no regulatory secondary structure) region of PknG (approximately residues 1–75) has been shown to play a role in PknG regulation by (auto)phosphorylation, whereas the following rubredoxin-like metal-binding motif (RD, residues ∼74–147) has been shown to interact tightly with the subsequent catalytic domain (approximately residues 148–420) to mediate its redox regulation. Deletions or mutations in NORS or the redox-sensitive RD significantly decrease PknG survival function. Based on combined NMR spectroscopy, in vitro kinase assay, and molecular dynamics simulation data, we provide novel insights into the regulatory roles of the N-terminal regions. The NORS region is indeed natively disordered and rather dynamic. Consistent with most earlier data, autophosphorylation occurs in our assays only when the NORS region is present and, thus, in the NORS region. Phosphorylation of it results only in local conformational changes and does not induce interactions with the subsequent RD. Although the reduced, metal-bound RD makes tight interactions with the following catalytic domain in the published crystal structures, it can also fold in its absence. Our data further suggest that oxidation-induced unfolding of the RD regulates substrate access to the catalytic domain and, thereby, PknG function under different redox conditions, e.g. when exposed to increased levels of reactive oxidative species in host macrophages.

Expression and purification of the natively disordered and redox sensitive metal binding regions of Mycobacterium tuberculosis protein kinase G.

Mycobacterium tuberculosis protein kinase G (PknG) is secreted into host macrophages to block lysosomal degradation. The catalytic domain (∼147-405) is C-terminally flanked by a tetratricopeptide repeat domain (TPRD). The preceding rubredoxin-like metal-binding motif (RD, ∼74-147) mediates PknG redox regulation. The N-terminal ∼75 residues were predicted to show no regulatory secondary structure (NORS) and harbor the only site (T63) phosphorylated in vivo. Deletions or mutations in the NORS or the redox-sensitive RD significantly decrease the survival function. Here, we show that the RD appears only to be present in the folded, metal-bound state if ZnCl2 is added upon induction of protein expression in minimal medium. Since factor Xa cleaves at the end of its recognition site (IEGR), a modified expression plasmid for PknG1-147 was obtained by mutating the N-terminal thrombin to a factor Xa recognition site. This allows preparing PknG1-147 with its native N-terminus. We further present a fast approach to generate expression plasmids for only the NORS or the RD by site-directed mutagenesis of the expression plasmid for His-tagged PknG1-147. An expression plasmid for PknG1-75 was obtained by introducing a stop codon at position 76 and one for PknG74-174 by introducing a factor Xa recognition site before position 74. SDS-PAGE analysis shows that all fragments are highly expressed in E. coli and can be purified to high purity. Thereby, the established preparation protocols pave the route for the NMR structural characterization of PknG regulation by its N-terminal regions, which is demonstrated by the recorded initial (1)H-(15)N-HSQC spectra.

NMR analysis of the backbone dynamics of the small GTPase Rheb and its interaction with the regulatory protein FKBP38

Ras homolog enriched in brain (Rheb) is a small GTPase that regulates mammalian/mechanistic target of rapamycin complex 1 (mTORC1) and, thereby, cell growth and metabolism. Here we show that cycling between the inactive GDP‐ and the active GTP‐bound state modulates the backbone dynamics of a C‐terminal truncated form, RhebΔCT, which is suggested to influence its interactions. We further investigated the interactions between RhebΔCT and the proposed Rheb‐binding domain of the regulatory protein FKBP38. The observed weak interactions with the GTP‐analogue‐ (GppNHp‐) but not the GDP‐bound state, appear to accelerate the GDP to GTP exchange, but only very weakly compared to a genuine GEF. Thus, FKBP38 is most likely not a GEF but a Rheb effector that may function in membrane targeting of Rheb.

One short cysteine‐rich sequence pattern – two different disulfide‐bonded structures – a molecular dynamics simulation study

The nematocyst walls of Hydra are formed by proteins containing small cysteine‐rich domains (CRDs) of ~25 amino acids. The first CRD of nematocyst outer all antigen (NW1) and the C‐terminal CRD of minicollagen‐1 (Mcol1C) contain six cysteines at identical sequence positions, however adopt different disulfide bonded structures. NW1 shows the disulfide connectivities C2‐C14/C6‐C19/C10‐C18 and Mcol1C C2‐C18/C6‐C14/C10‐C19. To analyze if both show structural preferences in the open, non‐disulfide bonded form, which explain the formation of either disulfide connectivity pattern, molecular dynamics (MD) simulations at different temperatures were performed. NW1 maintained in the 100‐ns MD simulations at 283 K a rather compact fold that is stabilized by specific hydrogen bonds. The Mcol1C structure fluctuated overall more, however stayed most of the time also rather compact. The analysis of the backbone Φ/ψ angles indicated different turn propensities for NW1 and Mcol1C, which mostly can be explained based on published data about the influence of different amino acid side chains on the local backbone conformation. Whereas a folded precursor mechanism may be considered for NW1, Mcol1C may fold according to the quasi‐stochastic folding model involving disulfide bond reshuffling and conformational changes, locking the native disulfide conformations. The study further demonstrates the power of MD simulations to detect local structural preferences in rather dynamic systems such as the open, non‐disulfide bonded forms of NW1 and Mcol1C, which complement published information from NMR backbone residual dipolar couplings. Because the backbone structural preferences encoded by the amino acid sequence embedding the cysteines influence which disulfide connectivities are formed, the data are generally interesting for a better understanding of oxidative folding and the design of disulfide stabilized therapeutics. Copyright

Target of rapamycin FATC domain as a general membrane anchor : the FKBP-12 like domain of FKBP38 as a case study

Increased efforts have been undertaken to better understand the formation of signaling complexes at cellular membranes. Since the preparation of proteins containing a transmembrane domain or a prenylation motif is generally challenging an alternative membrane anchoring unit that is easy to attach, water‐soluble and binds to different membrane mimetics would find broad application. The 33‐residue long FATC domain of yeast TOR1 (y1fatc) fulfills these criteria and binds to neutral and negatively charged micelles, bicelles, and liposomes. As a case study, we fused it to the FKBP506‐binding region of the protein FKBP38 (FKBP38‐BD) and used 1H–15N NMR spectroscopy to characterize localization of the chimeric protein to micelles, bicelles, and liposomes. Based on these and published data for y1fatc, its use as a C‐terminally attachable membrane anchor for other proteins is compatible with a wide range of buffer conditions (pH circa 6–8.5, NaCl 0 to >150 mM, presence of reducing agents, different salts such as MgCl2 and CaCl2). The high water‐solubility of y1fatc enables its use for titration experiments against a membrane‐localized interaction partner of the fused target protein. Results from studies with peptides corresponding to the C‐terminal 17–11 residues of the 33‐residue long domain by 1D 1H NMR and CD spectroscopy indicate that they still can interact with membrane mimetics. Thus, they may be used as membrane anchors if the full y1fatc sequence is disturbing or if a chemically synthesized y1fatc peptide shall be attached by native chemical ligation, for example, unlabeled peptide to 15N‐labeled target protein for NMR studies.

1 H, 15 N, and 13 C chemical shift assignments of the micelle immersed FAT C-terminal (FATC) domains of the human protein kinases ataxia-telangiectasia mutated (ATM) and DNA-dependent protein kinase catalytic subunit (DNA-PKcs) fused to the B1 domain of streptococcal protein G (GB1)

FAT C-terminal (FATC) is a circa 33 residue-long domain. It controls the kinase functionality in phosphatidylinositol-3 kinase-related kinases (PIKKs). Recent NMR- and CD-monitored interaction studies indicated that the FATC domains of all PIKKs can interact with membrane mimetics albeit with different preferences for membrane properties such as surface charge and curvature. Thus they may generally act as membrane anchoring unit. Here, we present the 1H, 15N, and 13C chemical shift assignments of the DPC micelle immersed FATC domains of the human PIKKs ataxia-telangiectasia mutated (ATM, residues 3024–3056) and DNA protein kinase catalytic subunit (DNA-PKcs, residues 4096–4128), both fused to the 56 residue long B1 domain of Streptococcal protein G (GB1). Each fusion protein is 100 amino acids long and contains in the linking region between the GB1 tag and the FATC region a thrombin (LVPRGS) and an enterokinase (DDDDK) protease site. The assignments pave the route for the detailed structural characterization of the membrane mimetic bound states, which will help to better understand the role of the proper cellular localization at membranes for the function and regulation of PIKKs. The chemical shift assignment of the GB1 tag is useful for NMR spectroscopists developing new experiments or using GB1 otherwise for case studies in the field of in-cell NMR spectroscopy or protein folding. Moreover it is often used as purification tag. Earlier we showed already that GB1 does not interact with membrane mimetics and thus does not disturb the NMR monitoring of membrane mimetic interactions of attached proteins.