Preferential binding and structural distortion by Fe2+ at RGGG-containing DNA sequences correlates with enhanced oxidative cleavage at such sequences.

Certain DNA sequences are known to be unusually sensitive to nicking via the Fe2+-mediated Fenton reaction. Most notable are a purine nucleotide followed by three or more G residues, RGGG, and purine nucleotides flanking a TG combination, RTGR. Our laboratory previously demonstrated that nicking in the RGGG sequences occurs preferentially 5' to a G residue with the nicking probability decreasing from the 5' to 3'end of these sequences. Using 1H NMR to characterize Fe2+ binding within the duplex CGAGTTAGGGTAGC/GCTACCCTAACTCG and 7-deazaguanine-containing (Z) variants of it, we show that Fe2+ binds preferentially at the GGG sequence, most strongly towards its 5' end. Substitutions of individual guanines with Z indicate that the high affinity Fe2+ binding at AGGG involves two adjacent guanine N7 moieties. Binding is accompanied by large changes in specific imino, aromatic and methyl proton chemical shifts, indicating that a locally distorted structure forms at the binding site that affects the conformation of the two base pairs 3' to the GGG sequence. The binding of Fe2+ to RGGG contrasts with that previously observed for the RTGR sequence, which binds Fe2+ with negligible structural rearrangements

NMR structure of the N-terminal domain of the replication initiator protein DnaA

DnaA is an essential component in the initiation of bacterial chromosomal replication. DnaA binds to a series of 9 base pair repeats leading to oligomerization, recruitment of the DnaBC helicase, and the assembly of the replication fork machinery. The structure of the N-terminal domain (residues 1-100) of DnaA from Mycoplasma genitalium was determined by NMR spectroscopy. The backbone r.m.s.d. for the first 86 residues was 0.6 +/- 0.2 Angstrom based on 742 NOE, 50 hydrogen bond, 46 backbone angle, and 88 residual dipolar coupling restraints. Ultracentrifugation studies revealed that the domain is monomeric in solution. Features on the protein surface include a hydrophobic cleft flanked by several negative residues on one side, and positive residues on the other. A negatively charged ridge is present on the opposite face of the protein. These surfaces may be important sites of interaction with other proteins involved in the replication process. Together, the structure and NMR assignments should facilitate the design of new experiments to probe the protein-protein interactions essential for the initiation of DNA replication

Structural and dynamic characterization of the heterodimeric and homodimeric complexes of distamycin and 1-methylimidazole-2-carboxamide-netropsin bound to the minor groove of DNA

NMR spectroscopy combined with molecular modeling was used to characterize a heterodimeric complex with Dst and 2-ImN bound in the minor groove of d(GCCTAACAAGG)•d(CCTTGTTAGGC) (1:1:1 2-ImN•Dst•DNA complex). The imidazole-pyrrole-pyrrole ligand 2-ImN spans 5'-GTTA-3' of the TAACA•TGTTA binding site with the imidazole nitrogen specifically recognizing the guanine amino group. The Dst ligand lies along the 5'-AACA-3' sequence and complements the 2-ImN ligand in the formation of the antiparallel side-by-side heterodimeric complex. Titrations of the same site with Dst or 2-ImN alone yield homodimeric complexes (2:1 ligand.DNA) of lower stability than the 1:1:1 2-ImN•Dst•DNA complex. Dst and 2-ImN binding to d(CGCAAACTGGC)•d(GCCAGTTTGCG) was also investigated. The 1:1:1 2-ImN•Dst•DNA complex is again the most stable complex with the AAACT•AGTTT site and is similar to the TAACA•TGTTA complex. No monomeric binding of either 2-ImN or Dst was observed to either site

Architecture and Membrane Interactions of the EGF Receptor

SummaryDimerization-driven activation of the intracellular kinase domains of the epidermal growth factor receptor (EGFR) upon extracellular ligand binding is crucial to cellular pathways regulating proliferation, migration, and differentiation. Inactive EGFR can exist as both monomers and dimers, suggesting that the mechanism regulating EGFR activity may be subtle. The membrane itself may play a role but creates substantial difficulties for structural studies. Our molecular dynamics simulations of membrane-embedded EGFR suggest that, in ligand-bound dimers, the extracellular domains assume conformations favoring dimerization of the transmembrane helices near their N termini, dimerization of the juxtamembrane segments, and formation of asymmetric (active) kinase dimers. In ligand-free dimers, by holding apart the N termini of the transmembrane helices, the extracellular domains instead favor C-terminal dimerization of the transmembrane helices, juxtamembrane segment dissociation and membrane burial, and formation of symmetric (inactive) kinase dimers. Electrostatic interactions of EGFR’s intracellular module with the membrane are critical in maintaining this coupling

NMR characterization of hairpin polyamide complexes with the minor groove of DNA

Polyamides containing N-methylimidazole (Im) and N-methylpyrrole (Py) amino acids can be combined in antiparallel side-by-side dimeric complexes for sequence-specific recognition in the minor groove of DNA. Covalently linking polyamide subunits has led to designed ligands with both increased affinity and specificity. Simple aliphatic amino acid linkers serve as internal guide residues for turn vs extended binding in a head-to-tail-linked polyamide motif. Polyamides of sequence composition ImPyPy-X-PyPyPy containing linkers of incremental length (X = 3-aminopropionic acid (β), 4-aminobutyric acid (γ), or 5-aminovaleric acid (δ)) in complex with an undecamer DNA duplex containing a 5'-(A,T)G(A,T)(3)-3' target site were structurally characterized using NMR spectroscopy. Previous quantitative DNase I footprinting studies identified gamma as the highest affinity of these "turn" linkers. NMR titrations and 2D NOESY data combined with restrained molecular modeling reveal that polyamides with β, γ, and δ linkers all may adopt a hairpin structure. Modeling supports the idea that the linkers in the βand δcomplexes adopt an energetically less favorable turn geometry than the γlinker and confirms that the three-carbon γ linker is sufficient and optimal for the hairpin conformation

Temperature Response of 129 Xe Depolarization Transfer and Its Application for Ultrasensitive NMR Detection

Trapping xenon in functionalized cryptophane cages makes the sensitivity of hyperpolarized (HP) 129Xe available for specific NMR detection of biomolecules. Here, we study the signal transfer onto a reservoir of unbound HP xenon by gating the residence time of the nuclei in the cage through the temperature-dependant exchange rate. Temperature changes larger than ∼0.6  K are detectable as an altered reservoir signal. The temperature response is adjustable with lower concentrations of caged xenon providing more sensitivity at higher temperatures. Ultrasensitive detection of functionalized cryptophane at 310 K is demonstrated with a concentration of 10 nM, corresponding to a ∼4000−fold sensitivity enhancement compared to conventional detection. This makes HPNMR capable of detecting such constructs in concentrations far below the detection limit of benchtop uv-visible light absorbance

An atypical receiver domain controls the dynamic polar localization of the Myxococcus xanthus social motility protein FrzS

The Myxococcus xanthus FrzS protein transits from pole-to-pole within the cell, accumulating at the pole that defines the direction of movement in social (S) motility. Here we show using atomic-resolution crystallography and NMR that the FrzS receiver domain (RD) displays the conserved switch Tyr102 in an unusual conformation, lacks the conserved Asp phosphorylation site, and fails to bind Mg2+ or the phosphoryl analogue, Mg2+·BeF3. Mutation of Asp55, closest to the canonical site of RD phosphorylation, showed no motility phenotype in vivo, demonstrating that phosphorylation at this site is not necessary for domain function. In contrast, the Tyr102Ala and His92Phe substitutions on the canonical output face of the FrzS RD abolished S-motility in vivo. Single-cell fluorescence microscopy measurements revealed a striking mislocalization of these mutant FrzS proteins to the trailing cell pole in vivo. The crystal structures of the mutants suggested that the observed conformation of Tyr102 in the wild-type FrzS RD is not sufficient for function. These results support the model that FrzS contains a novel ‘pseudo-receiver domain’ whose function requires recognition of the RD output face but not Asp phosphorylation

Analysis of hairpin polyamide complexes having DNA binding sites in close proximity

The binding of two hairpin polyamide ligands at adjacent sites on DNA has been studied using NMR spectroscopy. The ligands ImPyPy-γ-PyPyPy-Gly-Dp and Ac-ImPyPy-γ-PyPyPy-Gly-Dp were studied binding to oligomers containing one or two matched binding sites:  5‘-XGTTA-3‘ and 5‘-TAACX_NGTTA-3‘, where X is G, C, or A and N = 0, 1 or 2. At these sites the C-terminal ring shows an equilibrium between normal and inverted conformations. Better binding was observed with the ligand running 5‘ to 3‘ along the contacted strand than in the opposite direction. Complexes of DNAs with two binding sites indicated that at least one spacing base pair was required, and that the identity of this base pair was not critical. Binding with 5‘ to 3‘ contact is again preferred. Demonstrated binding at adjacent sites indicates that it may be possible to engineer cooperative binding for enhanced specificity or affinity

Analysis of hairpin polyamide complexes having DNA binding sites in close proximity

The binding of two hairpin polyamide ligands at adjacent sites on DNA has been studied using NMR spectroscopy. The ligands ImPyPy-γ-PyPyPy-Gly-Dp and Ac-ImPyPy-γ-PyPyPy-Gly-Dp were studied binding to oligomers containing one or two matched binding sites:  5‘-XGTTA-3‘ and 5‘-TAACX_NGTTA-3‘, where X is G, C, or A and N = 0, 1 or 2. At these sites the C-terminal ring shows an equilibrium between normal and inverted conformations. Better binding was observed with the ligand running 5‘ to 3‘ along the contacted strand than in the opposite direction. Complexes of DNAs with two binding sites indicated that at least one spacing base pair was required, and that the identity of this base pair was not critical. Binding with 5‘ to 3‘ contact is again preferred. Demonstrated binding at adjacent sites indicates that it may be possible to engineer cooperative binding for enhanced specificity or affinity