A conformational change in PBX1A is necessary for its nuclear localization

The fly homeodomain (HD) protein EXTRADENTICLE (EXD) is dependent on a second HD protein, HOMOTHORAX (HTH), for nuclear localization. We show here that in insect cells the mammalian homolog of EXD, PBX1A, shows a similar dependence on the HTH homologs MEIS1, 2, and 3 and the MEIS-like protein PREP1. Paradoxically, removal of residues N-terminal to the PBX1A HD abolishes interactions with MEIS/PREP but allows nuclear accumulation of PBX1A. We use deletion mapping and fusion to green fluorescent protein to map two cooperative nuclear localization signals (NLSs) in the PBX HD. The results of DNA-binding assays and pull-down experiments are consistent with a model whereby the PBX N-terminus binds to the HD and masks the two NLSs. In support of the model, a mutation in the PBX HD that disrupts contact with the N-terminus leads to constitutive nuclear localization. The HD mutation also increases sensitivity to protease digestion, consistent with a change in conformation. We propose that MEIS family proteins induce a conformational change in PBX that unmasks the NLS, leading to nuclear localization and increased DNA-binding activity. Consistent with this, PBX1 is nuclear only where Meis1 is expressed in the mouse limb bud.     

Respiratory syncytial virus G protein and G protein CX3C motif adversely affect CX3CR1+ T cell responses

Interactions between fractalkine (CX3CL1) and its receptor, CX3CR1, mediate leukocyte adhesion, activation, and trafficking. The respiratory syncytial virus (RSV) G protein has a CX3C chemokine motif that can bind CX3CR1 and modify CXCL1-mediated responses. In this study, we show that expression of the RSV G protein or the G protein CX3C motif during infection is associated with reduced CX3CR1+ T cell trafficking to the lung, reduced frequencies of RSV-specific, MHC class I-restricted IFN-gamma-expressing cells, and lower numbers of IL-4- and CX3CL1-expressing cells. In addition, we show that CX3CR1+ cells constitute a major component of the cytotoxic response to RSV infection. These results suggest that G protein and the G protein CX3C motif reduce the antiviral T cell response to RSV infection.     

Helix 2 of the paired domain plays a key role in the regulation of DNA-binding by the Pax-3 homeodomain.

Pax3 contains two structurally independent DNA-binding domains, a paired domain (PD) and a homeodomain (HD). Biochemical and mutagenesis studies have shown that both domains are functionally interdependent. In particular, it has been shown that the PD can regulate the DNA-binding specificity and dimerization potential of the HD. To delineate Pax3 protein segments that are involved in the regulation of HD DNA-binding, a series of chimeric proteins were created in which the HD and linker region were gradually replaced with corresponding sequences from a heterologous HD protein, Phox. Characterization of chimeric proteins by electrophoretic mobility shift analysis (EMSA) suggests that a portion of the linker region contributes to the functional interaction between the PD and HD. In addition, stepwise removal of sequences from the Pax3 PD was used to define regions within this domain that are involved in the regulation of HD DNA-binding. EMSA of these proteins in the context of the chimeric Pax3/Phox backbone provided two key findings: (i) the C-terminal subdomain of the PD does not play a major role in the regulation of HD DNA-binding and (ii) the N-terminal subdomain and, in particular, the second alpha-helix are essential for modulation of HD DNA-binding. Significantly, deletion of helix 2 was found to be sufficient to uncouple regulation of HD DNA-binding by the PD.     

Identification, cloning and expression of p25, an AT-rich DNA-binding protein from the extreme thermophile, Thermus aquaticus YT-1

Although the G+C content of Thermus aquaticus YT-1 chromosomal DNA is 67.4%, regions with lower G+C content have also been observed. AT-rich DNA-binding proteins may contribute to the thermostability and biological functions of these DNA regions at Thermus growth temperatures. Using double-stranded DNA (dsDNA)-cellulose chromatography, a T.aquaticus YT-1 protein, designated as p25, was identified to bind preferentially to AT-rich DNA. The gene encoding p25 was cloned and sequenced after immunoscreening T.aquaticus YT-1 expression libraries. The deduced primary structure of p25 is 211 amino acids in length with a molecular weight of 23 225 Da. Native p25 was purified and characterized as a homodimer with modification possibly at lysine and arginine residues. Its preferential and temperature-dependent binding to AT-rich DNA was confirmed with mobility-shift DNA-binding assays. The protein was demonstrated to bind preferentially to dsDNA instead of single-stranded DNA. The binding of p25 to dsDNA also improved the thermotolerence of this protein. Overexpression study of fusion p25 suggested that the N-terminus of the protein might form the DNA-binding domain or be closely involved in DNA-binding activity.     

Molecular cloning of a steroid-regulated 108K heat shock protein gene from hen oviduct.

The natural gene for a steroid inducible 108K heat shock protein has been isolated from a lambda genomic library prepared from hen oviduct tissue. Genomic DNA blots indicate that it exists as a single copy gene in the chick oviduct haploid genome. The 9.9 kilobase gene codes for a messenger RNA of 2733bp (21) and is split into 18 exons as established by sequence comparison of cDNA and genomic clones. The 3' end of the gene contains a repetitive element which shares homology with the CR1 family of repeats. The first exon contains both the untranslated leader and coding regions of the gene. The promoter region is rich in G + C residues (70%) and the dinucleotide CG. This 5' flanking segment contains bases similar both in sequence and location to the Goldberg-Hogness TATA homology and consensus sequence CCAAT. A consensus sequence located upstream of steroid hormone responsive chicken genes is found at -267 and on a reverse orientation at -593. The structure of this gene is of interest since the presence of introns in heat shock genes is rare in any species examined to date. Furthermore, this gene lacks the previously described heat shock promoter consensus sequence (C-GAA-TTC-G) present in other species.     

Insights into Lou Gehrig's disease from the structure and instability of the A4V mutant of human Cu,Zn superoxide dismutase

We have engineered enhanced DNA-binding function into the a1 homeodomain by making changes in a loop distant from the DNA-binding surface. Comparison of the free and bound a1 structures suggested a mechanism linking van der Waals stacking changes in this loop to the ordering of a final turn in the DNA-binding helix of a1. Inspection of the protein sequence revealed striking differences in amino acid identity at positions 24 and 25 compared to related homeodomain proteins. These positions lie in the loop connecting helix-1 and helix-2, which is involved in heterodimerization with the alpha 2 protein. A series of single and double amino acid substitutions (a1-Q24R, a1-S25Y, a1-S25F and a1-Q24R/S25Y) were engineered, expressed and purified for biochemical and biophysical study. Calorimetric measurements and HSQC NMR spectra confirm that the engineered variants are folded and are equally or more stable than the wild-type a1 homeodomain. NMR analysis of a1-Q24R/S25Y demonstrates that the DNA recognition helix (helix-3) is extended by at least one turn as a result of the changes in the loop connecting helix-1 and helix-2. As shown by EMSA, the engineered variants bind DNA with enhanced affinity (16-fold) in the absence of the alpha 2 cofactor and the variant alpha 2/a1 heterodimers bind cognate DNA with specificity and affinity reflective of the enhanced a1 binding affinity. Importantly, in vivo assays demonstrate that the a1-Q24R/S25Y protein binds with fivefold greater affinity than wild-type a1 and is able to partially suppress defects in repression by alpha 2 mutants. As a result of these studies, we show how subtle differences in residues at a surface distant from the functional site code for a conformational switch that allows the a1 homeodomain to become active in DNA binding in association with its cofactor alpha 2.