Chad K. Park

A Transmembrane Domain and GxxxG Motifs within L2 Are Essential for Papillomavirus Infection

ABSTRACT During cellular invasion, human papillomavirus type 16 (HPV16) must transfer its viral genome (vDNA) across the endosomal membrane prior to its accumulation at nuclear PML bodies for the establishment of infection. After cellular uptake, the capsid likely undergoes pH-dependent disassembly within the endo-/lysosomal compartment, thereby exposing hidden domains in L2 that facilitate membrane penetration of L2/vDNA complexes. In an effort to identify regions of L2 that might physically interact with membranes, we have subjected the L2 sequence to multiple transmembrane (TM) domain prediction algorithms. Here, we describe a conserved TM domain within L2 (residues 45 to 67) and investigate its role in HPV16 infection. In vitro, the predicted TM domain adopts an alpha-helical structure in lipid environments and can function as a real TM domain, although not as efficiently as the bona fide TM domain of PDGFR. An L2 double point mutant renders the TM domain nonfunctional and blocks HPV16 infection by preventing endosomal translocation of vDNA. The TM domain contains three highly conserved GxxxG motifs. These motifs can facilitate homotypic and heterotypic interactions between TM helices, activities that may be important for vDNA translocation. Disruption of some of these GxxxG motifs resulted in noninfectious viruses, indicating a critical role in infection. Using a ToxR-based homo-oligomerization assay, we show a propensity for this TM domain to self-associate in a GxxxG-dependent manner. These data suggest an important role for the self-associating L2 TM domain and the conserved GxxxG motifs in the transfer of vDNA across the endo-/lysosomal membrane.

Adhesion and coalescence of ductile metal surfaces and nanoparticles

Much more is known about material failure, such as fracture and crack propagation, than the reverse effect of material formation, i.e., how bulk materials form or consolidate during material processing or crack healing. Using the Surface Forces Apparatus, optical interferometry, optical and scanning probe microscopy, and x-ray diffraction, we have studied how gold and platinum films sinter or cold-weld at the nano-scale to form continuous bulk films when two initially rough surfaces composed of nanometer-scale asperities are pressed together. We find that coalescence of these ductile materials occurs abruptly, like a first order phase transition, once a critical local pressure or interparticle separation is reached. Simple thermodynamic and kinetic considerations suggest that it may be a more general phenomenon for ductile materials interacting at the nano-scale. We also make some qualitative comparisons with the very different behavior observed with hard, brittle materials.

Domain Swapping in Allosteric Modulation of DNA Specificity

The structure of two DNA-bound SgrAI enzyme dimers is presented, along with mutagenesis experiments supporting a role for this structure in polymer formation and the activation of DNA cleavage by SgrAI.

Allosteric Regulation of DNA Cleavage and Sequence-Specificity through Run-On Oligomerization

SgrAI is a sequence specific DNA endonuclease that functions through an unusual enzymatic mechanism that is allosterically activated 200- to 500-fold by effector DNA, with a concomitant expansion of its DNA sequence specificity. Using single-particle transmission electron microscopy to reconstruct distinct populations of SgrAI oligomers, we show that in the presence of allosteric, activating DNA, the enzyme forms regular, repeating helical structures characterized by the addition of DNA-binding dimeric SgrAI subunits in a run-on manner. We also present the structure of oligomeric SgrAI at 8.6 Å resolution, demonstrating the conformational state of SgrAI in its activated form. Activated and oligomeric SgrAI displays key protein-protein interactions near the helix axis between its N termini, as well as allosteric protein-DNA interactions that are required for enzymatic activation. The hybrid approach reveals an unusual mechanism of enzyme activation that explains SgrAIs oligomerization and allosteric behavior.

Activation of DNA Cleavage by Oligomerization of DNA Bound SgrAI

SgrAI is a type II restriction endonuclease that cuts an unusually long recognition sequence and exhibits allosteric self-modulation of DNA activity and sequence specificity. Precleaved primary site DNA has been shown to be an allosteric effector [Hingorani-Varma, K., and Bitinaite, J. (2003) J. Biol. Chem. 278, 40392-40399], stimulating cleavage of both primary (CR|CCGGYG, where the vertical bar indicates a cut site, R denotes A or G, and Y denotes C or T) and secondary [CR|CCGGY(A/C/T) and CR|CCGGGG] site DNA sequences. The fact that DNA is the allosteric effector of this endonuclease suggests at least two DNA binding sites on the functional SgrAI molecule, yet crystal structures of SgrAI [Dunten, P. W., et al. (2008) Nucleic Acids Res. 36, 5405-5416] show only one DNA duplex bound to one dimer of SgrAI. We show that SgrAI forms species larger than dimers or tetramers [high-molecular weight species (HMWS)] in the presence of sufficient concentrations of SgrAI and its primary site DNA sequence that are dependent on the concentration of the DNA-bound SgrAI dimer. Analytical ultracentrifugation indicates that the HMWS is heterogeneous, has sedimentation coefficients of 15-20 s, and is composed of possibly 4-12 DNA-bound SgrAI dimers. SgrAI bound to secondary site DNA will not form HMWS itself but can bind to HMWS formed with primary site DNA and SgrAI. Uncleaved, as well as precleaved, primary site DNA is capable of stimulating HMWS formation. Stimulation of DNA cleavage by SgrAI, at primary as well as secondary sites, is also dependent on the concentration of primary site DNA (cleaved or uncleaved) bound SgrAI dimers. SgrAI bound to secondary site DNA does not have significant stimulatory activity. We propose that the oligomers of DNA-bound SgrAI (i.e., HMWS) are the activated, or activatable, forms of the enzyme.

Structural analysis of activated SgrAI-DNA oligomers using ion mobility mass spectrometry.

SgrAI is a type IIF restriction endonuclease that cuts an unusually long recognition sequence and exhibits self-modulation of DNA cleavage activity and sequence specificity. Previous studies have shown that SgrAI forms large oligomers when bound to particular DNA sequences and under the same conditions where SgrAI exhibits accelerated DNA cleavage kinetics. However, the detailed structure and stoichiometry of the SgrAI-DNA complex as well as the basic building block of the oligomers have not been fully characterized. Ion mobility mass spectrometry (IM-MS) was employed to analyze SgrAI-DNA complexes and show that the basic building block of the oligomers is the DNA-bound SgrAI dimer (DBD) with one SgrAI dimer bound to two precleaved duplex DNA molecules each containing one-half of the SgrAI primary recognition sequence. The oligomers contain variable numbers of DBDs with as many as 19 DBDs. Observation of the large oligomers shows that nanoelectrospray ionization (nano-ESI) can preserve the proposed activated form of an enzyme. Finally, the collision cross section of the SgrAI-DNA oligomers measured by IM-MS was found to have a linear relationship with the number of DBDs in each oligomer, suggesting a regular, repeating structure.

Zinc enhances adiponectin oligomerization to octadecamers but decreases the rate of disulfide bond formation.

Adiponectin, a hormone secreted from adipocytes, has been shown to protect against development of insulin resistance, ischemia–reperfusion injury, and inflammation. Adiponectin assembles into multiple oligomeric isoforms: trimers, hexamers and several higher molecular weight (HMW) species. Of these, the HMW species are selectively decreased during the onset of type 2 diabetes. Despite the critical role of HMW adiponectin in insulin responsiveness, its assembly process is poorly understood. In this report, we investigated the role of divalent cations in adiponectin assembly. Purified adiponectin 18mers, the largest HMW species, did not collapse to smaller oligomers after treatment with high concentrations of EDTA. However, treatment with EDTA or another chelator DTPA inhibited the oligomerization of 18mers from trimers in vitro. Zn2+ specifically increased the formation of 18mers when compared with Cu2+, Mg2+, and Ca2+. Distribution of adiponectin oligomers secreted from zinc chelator TPEN-treated rat adipocytes skewed toward increased proportions of hexamers and trimers. While we observed presence of zinc in adiponectin purified from calf serum, the role of zinc in disulfide bonding between oligomers was examined because the process is critical for 18mer assembly. Surprisingly, Zn2+ inhibited disulfide bond formation early in the oligomerization process. We hypothesize that initial decreases in disulfide formation rates could allow adiponectin subunits to associate before becoming locked in fully oxidized conformations incapable of further oligomerization. These data demonstrate that zinc stimulates oligomerization of HMW adiponectin and possibly other disulfide-dependent protein assembly processes.

Dimerization in the Grb7 protein.

In previous studies, we showed that the tyrosine phosphorylation state of growth factor receptor–bound protein 7 (Grb7) affects its ability to bind to the transcription regulator FHL2 and the cortactin‐interacting protein, human HS‐1‐associated protein‐1. Here, we present results describing the importance of dimerization in the Grb7–Src homology 2 (SH2) domain in terms of its structural integrity and the ability to bind phosphorylated tyrosine peptide ligands. A tyrosine phosphorylation‐mimic mutant (Y80E–Grb7–SH2) is largely dimerization deficient and binds a tyrosine‐phosphorylated peptide representative of the receptor tyrosine kinase (RTK) erbB2 with differing thermodynamic characteristics than the wild‐type SH2 domain. Another dimerization‐deficient mutant (F99R–Grb7–SH2) binds the phosphorylated erbB2 peptide with similarly changed thermodynamic characteristics. Both Y80E–Grb7–SH2 and F99R–Grb7–SH2 are structured by circular dichroism measurements but show reduced thermal stability relative to the wild type–Grb7–SH2 domain as measured by circular dichroism and nuclear magnetic resonance. It is well known that the dimerization state of RTKs (as binding partners to adaptor proteins such as Grb7) plays an important role in their regulation. Here, we propose the phosphorylation state of Grb7–SH2 domain tyrosine residues could control Grb7 dimerization, and dimerization may be an important regulatory step in Grb7 binding to RTKs such as erbB2. In this manner, additional dimerization‐dependent regulation could occur downstream of the membrane‐bound kinase in RTK‐mediated signaling pathways. Copyright

Probing the run-on oligomer of activated SgrAI bound to DNA.

SgrAI is a type II restriction endonuclease with an unusual mechanism of activation involving run-on oligomerization. The run-on oligomer is formed from complexes of SgrAI bound to DNA containing its 8 bp primary recognition sequence (uncleaved or cleaved), and also binds (and thereby activates for DNA cleavage) complexes of SgrAI bound to secondary site DNA sequences which contain a single base substitution in either the 1st/8th or the 2nd/7th position of the primary recognition sequence. This modulation of enzyme activity via run-on oligomerization is a newly appreciated phenomenon that has been shown for a small but increasing number of enzymes. One outstanding question regarding the mechanistic model for SgrAI is whether or not the activating primary site DNA must be cleaved by SgrAI prior to inducing activation. Herein we show that an uncleavable primary site DNA containing a 3’-S-phosphorothiolate is in fact able to induce activation. In addition, we now show that cleavage of secondary site DNA can be activated to nearly the same degree as primary, provided a sufficient number of flanking base pairs are present. We also show differences in activation and cleavage of the two types of secondary site, and that effects of selected single site substitutions in SgrAI, as well as measured collisional cross-sections from previous work, are consistent with the cryo-electron microscopy model for the run-on activated oligomer of SgrAI bound to DNA.

Crystallization of Zinc Finger Proteins Bound to DNA

A method is presented for determining conditions for the cocrystallization of zinc finger proteins with DNA. The method describes steps beginning with protein expression, through purification, design of DNA for cocrystallization, and the conditions to screen for cocrystallization.