The nonmutagenic (R)- and (S)-beta-(N(6)-adenyl)styrene oxide adducts are oriented in the major groove and show little perturbation to DNA structure

Conformations of (R)-beta-(N(6)-adenyl)styrene oxide and (S)-beta-(N(6)-adenyl)styrene oxide adducts at position X(6) in d(CGGACXAGAAG).d(CTTCTTGTCCG), incorporating codons 60, 61 (underlined), and 62 of the human N-ras protooncogene, were refined from (1)H NMR data. These were designated as the beta-R(61,2) and beta-S(61,2) adducts. A total of 533 distance restraints and 162 dihedral restraints were used for the molecular dynamics calculations of the beta-S(61,2) adduct, while 518 distances and 163 dihedrals were used for the beta-R(61,2) adduct. The increased tether length of the beta-adducts results in two significant changes in adduct structure as compared to the corresponding alpha-styrenyl adducts [Stone, M. P., and Feng, B. (1996) Magn. Reson. Chem. 34, S105-S114]. First, it reduces the distortion introduced into the DNA duplex. For both the beta-R(61,2) and beta-S(61,2) adducts, the styrenyl moiety was positioned in the major groove of the duplex with little steric hindrance. Second, it mutes the influence of stereochemistry at the alpha-carbon such that both the beta-R(61,2) and beta-S(61,2) adducts exhibit similar conformations. The results were correlated with site-specific mutagenesis experiments that revealed the beta-R(61,2) and beta-S(61,2) adducts were not mutagenic and did not block polymerase bypass.     

Actin surface structure revealed by antibody imprints: evaluation of phage-display analysis of anti-actin antibodies

Phage-display peptide library analysis of an anti-F actin polyclonal antibody identified 12 amino acid residues of actin that appear, in its X-ray crystal structure, to be grouped together in a surface accessible conformational epitope. Phage epitope mapping was carried out by isolating immune complexes containing members of the J404 nonapeptide phage-display library formed in diluted antiserum and isolated on a protein A affinity matrix. Immunoreactive clones were grown as plaques, replica plated onto nitrocellulose, and labeled with anti-actin immune serum. One hundred and forty-four positively staining clones identified in this way were sequenced. Of these, 54 displayed peptides with sequence similarities. When the most abundantly selected sequence, KQTWQQLWD, was produced as a synthetic peptide and derivatized to ovalbumin, the complex was strongly recognized by the antiserum on Western blots and inhibited the binding of the antibody to immobilized F-actin by 60%. A scrambled version of this sequence WQDK WLQTQ, when coupled to ovalbumin, was not recognized by the antiserum and minimally inhibited binding of antiserum to immobilized F-actin by 10%. KQTWQQLWD contained four residues that corresponded, in frame, to a highly conserved six residue region of the chicken beta-actin sequence 351TFQQMW356 (identical residues are shown in bold). Examination of the rabbit skeletal muscle X-ray crystal structure suggested that within a 15 A radius of W356, nine additional residues were arranged on the actin surface in such a way that they could be mimicked by several of the selected phage sequences with root-mean-square deviation fits of 2.1-2.5 A. We conclude that phage-display analysis can provide information about the relative location of amino acids on the surfaces of proteins using antibody imprints of the protein surface structure.     

Backbone dynamics of the human CC-chemokine eotaxin

Eotaxin is a CC chemokine with potent chemoattractant activity towards eosinophils. ¹⁵N NMR relaxation data have been used to characterize the backbone dynamics of recombinant human eotaxin. ¹⁵N longitudinal (R₁) and transverse (R₂) auto relaxation rates, heteronuclear ¹H-¹⁵N steady-state NOEs, and transverse cross-relaxation rates (_xy) were obtained at 30 °C for all resolved backbone secondary amide groups using ¹ H-detected two-dimensional NMR experiments. Ratios of transverse auto and cross relaxation rates were used to identify NH groups influenced by slow conformational rearrangement. Relaxation data were fit to the extended model free dynamics formalism, yielding parameters describing axially symmetric molecular rotational diffusion and the internal dynamics of each NH group. The molecular rotational correlation time (_m) is 5.09±0.02 ns, indicating that eotaxin exists predominantly as a monomer under the conditions of the NMR study. The ratio of diffusion rates about unique and perpendicular axes (D/D) is 0.81±0.02. Residues with large amplitudes of subnanosecond motion are clustered in the N-terminal region (residues 1–19), the C-terminus (residues 68–73) and the loop connecting the first two -strands (residues 30–37). N-terminal flexibility appears to be conserved throughout the chemokine family and may have implications for the mechanism of chemokine receptor activation. Residues exhibiting significant dynamics on the microsecond–millisecond time scale are located close to the two conserved disulfide bonds, suggesting that these motions may be coupled to disulfide bond isomerization.     

DNA abasic lesions in a different light: solution structure of an endogenous topoisomerase II poison

Topoisomerase II is the target for several anticancer drugs that "poison" the enzyme and convert it to a cellular toxin by increasing topoisomerase II-mediated DNA cleavage. In addition to these "exogenous topoisomerase II poisons," DNA lesions such as abasic sites act as "endogenous poisons" of the enzyme. Drugs and lesions are believed to stimulate DNA scission by altering the structure of the double helix within the cleavage site of the enzyme. However, the structural alterations that enhance cleavage are unknown. Since abasic sites are an intrinsic part of the genetic material, they represent an attractive model to assess DNA distortions that lead to altered topoisomerase II function. Therefore, the structure of a double-stranded dodecamer containing a tetrahydrofuran apurinic lesion at the +2 position of a topoisomerase II DNA cleavage site was determined by NMR spectroscopy. Three major features distinguished the apurinic structure ( = 0.095) from that of wild-type ( = 0.077). First, loss of base stacking at the lesion collapsed the major groove and reduced the distance between the two scissile phosphodiester bonds. Second, the apurinic lesion induced a bend that was centered about the topoisomerase II cleavage site. Third, the base immediately opposite the lesion was extrahelical and relocated to the minor groove. All of these structural alterations have the potential to influence interactions between topoisomerase II and its DNA substrate.     

Differential phosphoproteome profiling by affinity capture and tandem matrix-assisted laser desorption/ionization mass spectrometry

Protein phosphorylation is a ubiquitous post-translational modification that affects a significant subset of the proteome and plays an especially important role in signal transduction and cell cycle control in eukaryotic organisms. Recently developed methods that couple multidimensional liquid chromatography to electrospray mass spectrometers can be used to analyze entire phosphoproteomes. However, they require considerable investments and technical skills that are only available in a few highly specialized laboratories. These methods also appear to be biased. Statistical analyses show that peptides from abundant proteins and multiply phosphorylated peptides are disproportionately identified. We describe an economic alternative that utilizes a phospho-affinity step to isolate the intact phosphoproteins. These are subsequently characterized by electrophoresis and identified by direct de novo sequencing using tandem mass spectrometry. We applied this technique to probe signal-induced changes in the phosphoproteome of human U937 cells, and found that the pools of two cancer-related phosphoproteins implicated in intracellular hormones signaling are dramatically altered in the course of monocyte to macrophage differentiation.     

Latent homologues for the neural crest as an evolutionary novelty

The neural crest is a craniate synapomorphy and a bona fide evolutionary novelty. Recently, researchers considering intriguingly similar patterns of gene expression, cell behaviors, and embryogenetic processes in noncraniate deuterostomes have suggested that cephalochordates, urochordates, and echinoderms or their ancestors might have possessed cells that were precursors to the neural crest or its constituent cells. To emphasize the caution with which similarities at genetic, cellular, or embryological levels should be interpreted as substantiations for cell, germ layer, or tissue homologies, we present and evaluate additional tantalizing evidence that could be considered as documenting neural crest precursors in precraniates. Furthermore, we propose an evolutionary context--latent homologue--within which these data should be interpreted.     

Disentangling DNA during replication: a tale of two strands

The seminal papers by Watson and Crick in 1953 on the structure and function of DNA clearly enunciated the challenge their model presented of how the intertwined strands of DNA are unwound and separated for replication to occur. We first give a historical overview of the major discoveries in the past 50 years that address this challenge. We then describe in more detail the cellular mechanisms responsible for the unlinking of DNA. No single strategy on its own accounts for the complete unlinking of chromosomes required for DNA segregation to proceed. Rather, it is the combined effects of topoisomerase action, chromosome organization and DNA-condensing proteins that allow the successful partitioning of chromosomes into dividing cells. Finally, we propose a model of chromosome structure, consistent with recent findings, that explains how the problem of unlinking is alleviated by the division of chromosomal DNA into manageably sized domains.