David N.M. Jones, Ph.D.

Selected Abstracts

Structural studies of the high mobility group globular domain and basic tail of HMG-D bound to disulfide cross-linked DNA.

Dow LK, Jones DN, Wolfe SA, Verdine GL, Churchill ME Department of Pharmacology, University of Colorado Health Sciences Center, C236, 4200 East Ninth Avenue, Denver, Colorado 80262, USA.

Biochemistry 2000 Aug 15;39(32):9725-36

HMG-D is an abundant high mobility group chromosomal protein present during early embryogenesis in Drosophila melanogaster. It is a non-sequence-specific member of a protein family that uses the HMG domain for binding to DNA in the minor groove. The highly charged C-terminal tail of HMG-D contains AK motifs that contribute to high-affinity non-sequence-specific DNA binding. To understand the interactions of the HMG domain and C-terminal tail of HMG-D with DNA in solution, a complex between a high-affinity truncated form of the protein and a disulfide cross-linked DNA fragment was studied using heteronuclear NMR techniques. Despite its relatively high affinity for the single "prebent" site on the DNA, K(d) = 1.4 nM, HMG-D forms a non-sequence-specific complex with the DNA as indicated by exchange broadening of the protein resonances at the DNA interface in solution. The secondary structural elements of the protein are preserved when the protein is complexed with the DNA, and the DNA-binding interface maps to the regions of the protein where the largest chemical shift differences occur. The C-terminal tail of HMG-D confers high-affinity DNA binding, has an undefined structure, and appears to make direct contacts in the major groove of DNA via residues that are potentially regulated by phosphorylation. We conclude that while the HMG domain of HMG-D recognizes DNA with a mode of binding similar to that used by the sequence-specific HMG domain transcription factors, there are noteworthy differences in the structure and interactions of the C-terminal end of the DNA-binding domain and the C-terminal tail.

Novel multi-dimensional heteronuclear NMR techniques for the study of 13C-O-acetylated oligosaccharides: expanding the dimensions for carbohydrate structures.

Jones DN, Bendiak B Department of Pharmacology, University of Colorado Health Sciences Center, Denver 80262, USA.

J Biomol NMR 1999 Oct;15(2):157-68

Complex carbohydrates have critical roles in a wide variety of biological processes. An understanding of the molecular mechanisms that underlie these processes is essential in the development of novel oligosaccharide-based therapeutic strategies. Unfortunately, obtaining detailed structural information for larger oligosaccharides (> 10 residues) can be exceedingly difficult, especially where the amount of sample available is limited. Here we demonstrate the application of 13C O-acetylation in combination with novel NMR experiments to obtain much of the information required to characterize the primary structure of oligosaccharides. (H)CMe COH-HEHAHA and H(CMe)COH-HEHAHA experiments are presented that use heteronuclear Hartmann-Hahn transfer to correlate the acetyl groups with sugar ring protons in peracetylated oligosaccharides. The in-phase, pure absorption nature of the correlation peaks in these experiments allows measurement of both chemical shifts and, importantly, 1H-1H coupling constants that are used to define the stereochemistry of the sugar ring. The (HCMe)COH and (HCMe)COH-RELAY experiments provide additional methods for obtaining chemical shift assignments for larger oligosaccharides to define the sites of glycosidic linkages from the patterns of acetylation.

High-resolution structure of an archaeal zinc ribbon defines a general architectural motif in eukaryotic RNA polymerases.

Wang B, Jones DN, Kaine BP, Weiss MA Department of Chemistry, Center for Molecular Oncology, University of Chicago, Illinois 60637-5419, USA.

Structure 1998 May 15;6(5):555-69

BACKGROUND: Transcriptional initiation and elongation provide control points in gene expression. Eukaryotic RNA polymerase II subunit 9 (RPB9) regulates start-site selection and elongational arrest. RPB9 contains Cys4 Zn(2+)-binding motifs which are conserved in archaea and homologous to those of the general transcription factors TFIIB and TFIIS. RESULTS: The structure of an RPB9 domain from the hyperthermophilic archaeon Thermococcus celer was determined at high resolution by NMR spectroscopy. The structure consists of an apical tetrahedral Zn(2+)-binding site, central beta sheet and disordered loop. Although the structure lacks a globular hydrophobic core, the two surfaces of the beta sheet each contain well ordered aromatic rings engaged in serial edge-to-face interactions. Basic sidechains are clustered near the Zn(2+)-binding site. The disordered loop contains sidechains conserved in TFIIS, including acidic residues essential for the stimulation of transcriptional elongation. CONCLUSIONS: The planar architecture of the RPB9 zinc ribbon-distinct from that of a conventional globular domain-can accommodate significant differences in the alignment of polar, non-polar and charged sidechains. Such divergence is associated with local and non-local changes in structure. The RPB9 structure is distinguished by a fourth beta strand (extending the central beta sheet) in a well ordered N-terminal segment and also differs from TFIIS (but not TFIIB) in the orientation of its apical Zn(2+)-binding site. Cys4 Zn(2+)-binding sites with distinct patterns of polar, non-polar and charged residues are conserved among unrelated RNAP subunits and predicted to form variant zinc ribbons.

Structure-function relationships in side chain lactam cross-linked peptide models of a conserved N-terminal domain of apolipoprotein E.

Benzinger TL, Braddock DT, Dominguez SR, Burkoth TS, Miller-Auer H, Subramanian RM, Fless GM, Jones DN, Lynn DG, Meredith SC Department of Chemistry, The University of Chicago, Illinois 60637, USA.

Biochemistry 1998 Sep 22;37(38):13222-9

Bioactive peptides have multiple conformations in solution but adopt well-defined conformations at lipid surfaces and in interactions with receptors. We have used side chain lactam cross-links to stabilize secondary structures in the following peptide models of a conserved N-terminal domain of apolipoprotein E (cross-link periodicity in parentheses): I, H2N-GQTLSEQVQEELLSSQVTQELRAG-COOH (none); III, [sequence; see text] (i to i + 3); IV,[sequence; see text] (i to i + 4); IVa, [sequence, see text] (i to i + 4) (lactams above the sequence, potential salt bridges below the sequence). We previously demonstrated [Luo et al. (1994) Biochemistry 33, 12367-12377; Braddock et al. (1996) Biochemistry 35, 13975-13984] that peptide III, containing lactam cross-links between the i and i + 3 side chains, enhances specific binding of LDL via a receptor other than the LDL-receptor. Peptide III in solution consists of two short alpha helices connected by a non alpha helical segment. Here we examine the hypothesis that the domain modeled by peptide III is one antipode of a conformational switch. To model another antipode of the switch, we introduced two strategic modifications into peptide III to examine structure-function relationships in this domain: (1) the spacing of the lactam cross-links was changed (i to i + 4 in peptides IV and IVa) and (2) peptides IV and IVa contain the two alternative sequences at a site of a possible end-capping interaction in peptide III. The structure of peptide IV, determined by 2D-NMR, is alpha helical across its entire length. Despite the remarkable degree of structural order, peptide IV is biologically inactive. In contrast, peptides III and possibly IVa contain a central interruption of the alpha helix, which appears necessary for biological activity. These and other studies support the hypothesis that this domain is a conformational switch which, to the extent that it models apolipoprotein E itself, may modulate interactions between apo E and its various receptors.

Treatment of NOE constraints involving equivalent or nonstereoassigned protons in calculations of biomacromolecular structures.

Fletcher, C.M., Jones, D.N.M., Diamond, R., and Neuhaus, D.

J. Biomol. NMR, (1996), 8(3): p. 292-310.

Two modifications to the commonly used protocols for calculating NMR structures are developed, relating to the treatment of NOE constraints involving groups of equivalent protons or nonstereoassigned diastereotopic protons. Firstly, a modified method is investigated for correcting for multiplicity, which is applicable whenever all NOE intensities are calibrated as a single set and categorised in broad intensity ranges. Secondly, a new set of values for 'pseudoatom corrections' is proposed for use with calculations employing 'centre-averaging'. The effect of these protocols on structure calculations is demonstrated using two proteins, one of which is well defined by the NOE data, the other less so. It is shown that failure to correct for multiplicity when using 'r(-6) averaging' results in overly precise structures, higher NOE energies and deviations from geometric ideality, while failure to correct for multiplicity when using 'r(-6) summation' can cause an avoidable degradation of precision if the NOE data are sparse. Conversely when multiplicities are treated correctly, r(-6) averaging, r(-6) summation and centre averaging all give closely comparable results when the structure is well defined by the data. When the NOE data contain less information, r(-6) averaging or r(-6) summation offer a significant advantage over centre averaging, both in terms of precision and in terms of the proportion of calculations that converge on a consistent result.

HMG-D is an architecture-specific protein that preferentially binds to DNA containing the dinucleotide TG.

Churchill ME, Jones DN, Glaser T, Hefner H, Searles MA, Travers AA Department of Cell and Structural Biology, University of Illinois, Urbana 61801, USA.

EMBO J. 1995 Mar 15;14(6):1264-75.

The high mobility group (HMG) protein HMG-D from Drosophila melanogaster is a highly abundant chromosomal protein that is closely related to the vertebrate HMG domain proteins HMG1 and HMG2. In general, chromosomal HMG domain proteins lack sequence specificity. However, using both NMR spectroscopy and standard biochemical techniques we show that binding of HMG-D to a single DNA site is sequence selective. The preferred duplex DNA binding site comprises at least 5 bp and contains the deformable dinucleotide TG embedded in A/T-rich sequences. The TG motif constitutes a common core element in the binding sites of the well-characterized sequence-specific HMG domain proteins. We show that a conserved aromatic residue in helix 1 of the HMG domain may be involved in recognition of this core sequence. In common with other HMG domain proteins HMG-D binds preferentially to DNA sites that are stably bent and underwound, therefore HMG-D can be considered an architecture-specific protein. Finally, we show that HMG-D bends DNA and may confer a superhelical DNA conformation at a natural DNA binding site in the Drosophila fushi tarazu scaffold-associated region.

The solution structure and dynamics of the DNA-binding domain of HMG-D from Drosophila melanogaster.

Jones DN, Searles MA, Shaw GL, Churchill ME, Ner SS, Keeler J, Travers AA, Neuhaus D MRC Laboratory of Molecular Biology, Cambridge, UK.

Structure 1994 Jul 15;2(7):609-27

BACKGROUND: The HMG-box is a conserved DNA-binding motif that has been identified in many high mobility group (HMG) proteins. HMG-D is a non-histone chromosomal protein from Drosophila melanogaster that is closely related to the mammalian HMG-box proteins HMG-1 and HMG-2. Previous structures determined for an HMG-box domain from rat and hamster exhibit the same global topology, but differ significantly in detail. It has been suggested that these differences may arise from hinge motions which allow the protein to adapt to the shape of its target DNA. RESULTS: We present the solution structure of HMG-D determined by NMR spectroscopy to an overall precision of 0.85 A root mean squared deviation (rmsd) for the backbone atoms. The protein consists of an extended amino-terminal region and three alpha-helices that fold into a characteristic 'L' shape. The central core region of the molecule is highly stable and maintains an angle of approximately 80 degrees between the axes of helices 2 and 3. The backbone dynamics determined from 15N NMR relaxation measurements show a high correlation with the mean residue rmsd determined from the calculated structures. CONCLUSIONS: The structure determined for the HMG-box motif from HMG-D is essentially identical to the structure determined for the B-domain of mammalian HMG-1. Since these proteins have significantly different sequences our results indicate that the global fold and the mode of interaction with DNA are also likely to be conserved in all eukaryotes.