Details of the nucleic acid binding site of T4 gene 32 protein revealed by proteolysis and DNA Tm depression methods

The affinities and location of oligonucleotides bound to intact and truncated bacteriophage T4 gene 32 protein have been elucidated by two independent and sensitive methods. The nucleic acid binding site is located within the core domain of 32 protein, residues 22-253. Oligonucleotides protect the core domain against proteolysis catalyzed by mammalian endoproteinase Arg-C. Of the three cleavage sites, Arg111, within the internal "LAST" ((Lys/Arg)3(Ser/Thr)2) motif, is selectively protected. We have previously suggested that these LAST residues, Lys-Arg-Lys-Thr-Ser, residues 110-114, are involved in nucleic acid binding, and our results are also consistent with crystallographic studies. The inhibitory effects of oligonucleotides on the kinetics of core domain proteolysis were used to quantify binding affinities. In addition, affinities of oligonucleotides for both core domain and intact protein were obtained from their effect on the Tm-depressing activities of these proteins. For both core and intact protein, the degree of affinity increases with oligonucleotide length. The presence of a 5' terminal phosphate increases the affinity two- to fourfold. Placement of methylphosphonodiester (uncharged) linkages at alternating linkages vastly lowers binding affinity for the intact protein and core domain. We conclude that at least two and likely three adjacent phosphodiester linkages are a minimal requirement for binding, further defining the electrostatic component of the interaction. The length-dependence of binding affinity suggests that additional interactions, both ionic and non-ionic, likely occur with longer oligonucleotides.     

A consensus DNA-binding site for the androgen receptor.

We have used a DNA-binding site selection assay to determine a consensus binding sequence for the androgen receptor (AR). A purified fusion protein containing the AR DNA-binding domain was incubated with a pool of random sequence oligonucleotides, and complexes were isolated by gel mobility shift assays. Individually selected sites were characterised by nucleotide sequencing and compiled to give a consensus AR-binding element. This sequence is comprised of two 6-basepair (bp) asymmetrical elements separated by a 3-bp spacer, 5'-GGA/TACANNNTGTTCT-3', similar to that described for the glucocorticoid response element. Inspection of the consensus revealed a slight preference for G or A nucleotides at the +1 position in the spacer and for A and T nucleotides in the 3'-flanking region. Therefore, a series of oligonucleotides was designed in which the spacer and flanking nucleotides were changed to the least preferred sequence. Competition experiments with these oligonucleotides and the AR fusion protein indicated that an oligonucleotide with both the spacer and flanking sequences changed had greater than 3-fold less affinity than the consensus sequence. The functional activity of these oligonucleotides was also assessed by placing them up-stream of a reporter gene in a transient transfection assay and correlated with the affinity with which the AR fusion protein bound to DNA. Therefore, sequences surrounding the two 6-bp half-sites influence both the binding affinity for the receptor and the functional activity of the response element.     

Signal-mediated retrieval of a membrane protein from the Golgi to the ER in yeast

The Saccharomyces cerevisiae Wbp1 protein is an endoplasmic reticulum (ER), type I transmembrane protein which contains a cytoplasmic dilysine (KKXX) motif. This motif has previously been shown to direct Golgi-to-ER retrieval of type I membrane proteins in mammalian cells (Jackson, M. R., T. Nilsson, and P. A. Peterson. 1993. J. Cell Biol. 121: 317-333). To analyze the role of this motif in yeast, we constructed a SUC2-WBP1 chimera consisting of the coding sequence for the normally secreted glycoprotein invertase fused to the coding sequence of the COOH terminus (including the transmembrane domain and 16-amino acid cytoplasmic tail) of Wbplp. Carbohydrate analysis of the invertase-Wbp1 fusion protein using mannose linkage-specific antiserum demonstrated that the fusion protein was efficiently modified by the early Golgi initial alpha 1,6 mannosyltransferase (Och1p). Subcellular fractionation revealed that > 90% of the alpha 1,6 mannose-modified fusion protein colocalized with the ER (Wbp1p) and not with the Golgi Och1p-containing compartment or other membrane fractions. Amino acid changes within the dily sine motif (KK-->QK, KQ, or QQ) did not change the kinetics of initial alpha 1,6 mannose modification of the fusion protein but did dramatically increase the rate of modification by more distal Golgi (elongating alpha 1,6 and alpha 1,3) mannosyltransferases. These mutant fusion proteins were then delivered directly from a late Golgi compartment to the vacuole, where they were proteolytically cleaved in a PEP4-dependent manner. While amino acids surrounding the dilysine motif played only a minor role in retention ability, mutations that altered the position of the lysines relative to the COOH terminus of the fusion protein also yielded a dramatic defect in ER retention. Collectively, our results indicate that the KKXX motif does not simply retain proteins in the ER but rather directs their rapid retrieval from a novel, Och1p-containing early Golgi compartment. Similar to observations in mammalian cells, it is the presence of two lysine residues at the appropriate COOH-terminal position which represents the most important features of this sorting determinant.     

1H, 15N and 13C resonance assignments and secondary structure determination of the RNA-binding domain of E. coli rho protein

Summary Protein fragments containing the RNA-binding domain of Escherichia coli rho protein have been over-expressed in E. coli. NMR spectra of the fragment containing residues 1–116 of rho protein (Rho116) show that a region of this protein is unfolded in solution. Addition of (dC)₁₀ to this fragment stabilizes the folded form of the protein. The fragment comprising residues 1–130 of rho protein (Rho130) is found to be stably folded, both in the absence and presence of nucleic acid. NMR studies of the complex of Rho 130 with RNA and DNA oligonucleotides indicate that the binding-site size, affinity, and specificity of Rho 130 are similar to those of intact rho protein; therefore, Rho 130 is a suitable model of the RNA-binding domain of rho protein. NMR line widths as well as titration experiments of Rho130 complexed with oligonucleotides of various lengths suggest that Rho130 forms oligomers in the presence of longer oligonucleotides. ¹H, ¹⁵N and ¹³C resonance assignments were facilitated by the utilization of two pulse sequences, CN-NOESY and CCH-TOCSY. The secondary structure of unliganded Rho130 has been determined by NMR techniques, and it is clear that the RNA-binding domain of rho is more structurally similar to the cold shock domain than to the RNA recognition motif.Abbreviations Rho116, Rho130 protein containing the first 116 (130) residues of rho - CSD cold shock domain - RRM RNA recognition motif - RBD RNA-binding domain - IPTG isopropyl -D-thiogalactopyranoside - EDTA ethylenediaminetetraacetic acid - NOE nuclear Overhauser enhancement     

Purification and characterization of the Streptomyces lividans initiator protein DnaA.

The Streptomyces lividans DnaA protein (73 kDa) consists, like the Escherichia coli DnaA protein (52 kDa), of four domains. The larger size of the S. lividans protein is due to an additional stretch of 120 predominantly acidic amino acids within domain II. The S. lividans protein was overproduced as a His-tagged fusion protein. The purified protein (isoelectric point, 5.7) has a weak ATPase activity. By DNase I footprinting studies, each of the 17 DnaA boxes (consensus sequence, TTGTCCACA) in the S. lividans oriC region was found to be protected by the DnaA fusion protein. Purified mutant proteins carrying a deletion of the C-terminally located helix-loop-helix (HLH) motif or with amino acid substitutions in helix A (L577G) or helix B (R595A) no longer interact with DnaA boxes. A substitution of basic amino acids in the loop of the HLH motif (R587A or R589A) entailed the formation of S. lividans mutant DnaA proteins with little or no capacity for binding to DnaA boxes. Thus, like in E. coli, the C-terminally located domain IV is absolutely necessary for the specific binding of DnaA. A mutant protein lacking a stretch of acidic amino acids corresponding to domain II is not affected in its DNA binding capacity. Whether the acidic domain II interacts with accessory proteins remains to be elucidated.     

Functional analysis of conserved structural elements in yeast syntaxin Vam3p

Vam3p, a syntaxin-like SNARE protein involved in yeast vacuole fusion, is composed of a three-helical N-terminal domain, a canonical SNARE motif, and a C-terminal transmembrane region (TMR). Surprisingly, we find that the N-terminal domain of Vam3p is not essential for fusion, although analogous domains in other syntaxins are indispensible for fusion and/or protein-protein interactions. In contrast to the N-terminal domain, mutations in the SNARE motif of Vam3p or replacement of the SNARE motif of Vam3p with the SNARE motif from other syntaxins inhibited fusion. Furthermore, the precise distance between the SNARE motif and the TMR was critical for fusion. Insertion of only three residues after the SNARE motif significantly impaired fusion and insertion of 12 residues abolished fusion. As judged by co-immunoprecipitation experiments, the SNARE motif mutations and the insertions did not alter the association of Vam3p with Vam7p, Vti1p, Nyv1p, and Ykt6p, other vacuolar SNARE proteins implicated in fusion. In contrast, the SNARE motif substitutions interfered with the stable formation of Vam3p complexes with Nyv1p and Vti1p, although Vam3p complexes with Vam7p and Ykt6p were still present. Our data suggest that in contrast to previously characterized syntaxins, Vam3p contains only two domains essential for fusion, the SNARE motif and the TMR, and these domains have to be closely coupled to function in fusion.     

Mutational analysis of the leucine zipper motif in the Newcastle disease virus fusion protein.

The paramyxovirus fusion proteins have a highly conserved leucine zipper motif immediately upstream from the transmembrane domain of the F1 subunit (R. Buckland and F. Wild, Nature [London] 338:547, 1989). To determine the role of the conserved leucines in the oligomeric structure and biological activity of the Newcastle disease virus (NDV) fusion protein, the heptadic leucines at amino acids 481, 488, and 495 were changed individually and in combination to an alanine residue. While single amino acid changes had little effect on fusion, substitution of two or three leucine residues abolished the fusogenic activity of the protein, although cell surface expression of the mutants was higher than that of the wild-type protein. Substitution of all three leucine residues with alanine did not alter the size of the fusion protein oligomer as determined by sedimentation in sucrose gradients. Furthermore, deletion of the C-terminal 91 amino acids, including the leucine zipper motif and transmembrane domain, resulted in secretion of an oligomeric polypeptide. These results indicate that the conserved leucines are not necessary for oligomer formation but are required for the fusogenic ability of the protein. When the polar face of the potential alpha helix was altered by nonconservative changes of serine to alanine (position 473), glutamic acid to lysine or alanine (position 482), asparagine to lysine (position 485), or aspartic acid to alanine (position 489), the fusogenic ability of the protein was not significantly disrupted. In addition, a double mutant (E482A,D489A) which removed negative charges along one side of the helix had negligible effects on fusion activity.     

Structural and functional characterization of the TgDRE multidomain protein, a DNA repair enzyme from Toxoplasma gondii

The parasite Toxoplasma gondii expresses a 55 kDa protein or TgDRE that belongs to a novel family of proteins characterized by the presence of three domains, a human splicing factor 45-like motif (SF), a glycine-rich motif (G-patch), and a RNA recognition motif (RRM). The two latter domains are mainly known as RNA-binding domains, and their presence in TgDRE, whose partial DNA repair function was demonstrated, suggests that the protein could also be involved in the RNA metabolism. In this work, we characterized the structure and function of the different domains by using single or multidomain proteins to define their putative role. The SF45-like domain has a helical conformation and is involved in the oligomerization of the protein. The G-patch domain, mainly unstructured on its own as well as in the presence of the SF upstream and RRM downstream domains, is able to bind small RNA oligonucleotides. We also report the structure determination of the RRM domain from the NMR data. It adopts a classical betaalphabetabetaalphabeta topology consisting of a four-stranded beta sheet packed against two alpha helices but does not present the key residues for the RNA interaction. In contrast, our analysis shows that the RRM of TgDRE is not only unable to bind small RNA oligonucleotides but it also shares the protein-protein interaction characteristics with two unusual RRMs of the U2AF heterodimeric splicing factor. The presence of both RNA- and protein-binding domains seems to indicate that TgDRE could also be involved in RNA metabolism.     

The C-terminal dilysine motif confers endoplasmic reticulum localization to type I membrane proteins in plants

The tomato Cf-9 disease resistance gene encodes a type I membrane protein carrying a cytosolic dilysine motif. In mammals and yeast, this motif promotes the retrieval of type I membrane proteins from the Golgi apparatus to the endoplasmic reticulum (ER). To test whether the C-terminal KKXX signal of Cf-9 is functional as a retrieval motif and to investigate its role in plants, green fluorescent protein (GFP) was fused to the transmembrane domain of Cf-9 and expressed in yeast, Arabidopsis, and tobacco cells. The fusion protein was targeted to the ER in each of these expression systems, and mutation of the KKXX motif to NNXX led to secretion of the fusion protein. In yeast, the mutant protein reached the vacuole, but plants secreted it as a soluble protein after proteolytic removal of the transmembrane domain. Triple hemagglutinin (HA)-tagged full-length Cf-9 was also targeted to the ER in tobacco cells, and cleavage was also observed for the NNXX mutant protein, suggesting an endoprotease recognition site located within the Cf-9 lumenal sequence common to both the GFP- and the HA-tagged fusions. Our results indicate that the KKXX motif confers ER localization in plants as well as mammals and yeast and that Cf-9 is a resident protein of the ER.     

The essential DNA-binding protein sap1 of Schizosaccharomyces pombe contains two independent oligomerization interfaces that dictate the relative orientation of the DNA-binding domain.

The sap1 gene from Schizosaccharomyces pombe, which is essential for mating-type switching and for growth, encodes a sequence-specific DNA-binding protein with no homology to other known proteins. We have used a reiterative selection procedure to isolate binding sites for sap1, using a bacterially expressed protein and randomized double-strand oligonucleotides. The sap1 homodimer preferentially selects a pentameric motif, TA(A/G)CG, organized as a direct repeat and spaced by 5 nucleotides. Removal of a C-terminal dimerization domain abolishes recognition of the direct repeat and creates a new specificity for a DNA sequence containing the same pentameric motif but organized as an inverted repeat. We present evidence that the orientation of the DNA-binding domain is controlled by two independent oligomerization interfaces. The C-terminal dimerization domain allows a head-to-tail organization of the DNA-binding domains in solution, while an N-terminal domain is involved in a cooperative interaction on the DNA target between pairs of dimers.     

Characterization of the DNA-binding activity of GCR1: in vivo evidence for two GCR1-binding sites in the upstream activating sequence of TPI of Saccharomyces cerevisiae.

GCR1 gene function is required for high-level glycolytic gene expression in Saccharomyces cerevisiae. Recently, we suggested that the CTTCC sequence motif found in front of many genes encoding glycolytic enzymes lay at the core of the GCR1-binding site. Here we mapped the DNA-binding domain of GCR1 to the carboxy-terminal 154 amino acids of the polypeptide. DNase I protection studies showed that a hybrid MBP-GCR1 fusion protein protected a region of the upstream activating sequence of TPI (UASTPI), which harbored the CTTCC sequence motif, and suggested that the fusion protein might also interact with a region of the UAS that contained the related sequence CATCC. A series of in vivo G methylation protection experiments of the native TPI promoter were carried out with wild-type and gcr1 deletion mutant strains. The G doublets that correspond to the C doublets in each site were protected in the wild-type strain but not in the gcr1 mutant strain. These data demonstrate that the UAS of TPI contains two GCR1-binding sites which are occupied in vivo. Furthermore, adjacent RAP1/GRF1/TUF- and REB1/GRF2/QBP/Y-binding sites in UASTPI were occupied in the backgrounds of both strains. In addition, DNA band-shift assays were used to show that the MBP-GCR1 fusion protein was able to form nucleoprotein complexes with oligonucleotides that contained CTTCC sequence elements found in front of other glycolytic genes, namely, PGK, ENO1, PYK, and ADH1, all of which are dependent on GCR1 gene function for full expression. However, we were unable to detect specific interactions with CTTCC sequence elements found in front of the translational component genes TEF1, TEF2, and CRY1. Taken together, these experiments have allowed us to propose a consensus GCR1-binding site which is 5'-(T/A)N(T/C)N(G/A)NC(T/A)TCC(T/A)N(T/A)(T/A)(T/G)-3'.     

Soluble expression and purification of tumor suppressor WT1 and its zinc finger domain

Full length murine WT1 and its zinc finger domain were separately inserted into Escherichia coli expression vectors with various fusion tags on either terminus by Gateway technology (Invitrogen) and expression of soluble protein was assessed. Fusion proteins including the four zinc finger domains of WT1 were used to optimize expression and purification conditions and to characterize WT1:DNA interactions in the absence of WT1:WT1 interactions. Zinc finger protein for in vitro characterization was prepared by IMAC purification of WT1 residues 321-443 with a thioredoxin-hexahistidine N-terminal fusion, followed by 3C protease cleavage to liberate the zinc fingers and cation exchange chromatography to isolate the zinc fingers and reduce the level of the truncated forms. Titration of zinc finger domain with a binding site from the PDGFA promoter gave a K(d) of 100±30nM for the -KTS isoform and 130±40nM for the +KTS isoform. The zinc finger domain was also co-crystallized with a double-stranded DNA oligonucleotide, yielding crystals that diffract to 5.5?. Using protocols established for the zinc finger domain, we expressed soluble full-length WT1 with an N-terminal thioredoxin domain and purified the fusion protein by IMAC. In electro-mobility shift assays, purified full-length WT1 bound double-stranded oligonucleotides containing known WT1 binding sites, but not control oligonucleotides. Two molecules of WT1 bind an oligonucleotide presenting the full PDGFA promoter, demonstrating that active full-length WT1 can be produced in E. coli and used to investigate WT1 dimerization in complex with DNA in vitro.     

Identification of lysosomal and Golgi localization signals in GAP and ARF domains of ARF domain protein 1

ADP ribosylation factors (ARFs) are approximately 20-kDa guanine nucleotide-binding proteins that activate cholera toxin and phospholipase D and are critical components of vesicular trafficking pathways. ARF domain protein 1 (ARD1), a member of the ARF superfamily, contains a 46-kDa amino-terminal extension, which acts as a GTPase-activating protein (GAP) with activity towards its ARF domain. When overexpressed, ARD1 was associated with lysosomes and the Golgi apparatus. In agreement with this finding, lysosomal and Golgi membranes isolated from human liver by immunoaffinity contained native ARD1. ARD1, expressed as a green fluorescent fusion protein, was initially associated with the Golgi network and subsequently appeared on lysosomes, suggesting that ARD1 might undergo vectorial transport between the two organelles. Here we show by microscopic colocalization that GAP and ARF domains determine lysosomal and Golgi localization, respectively, consistent with the presence of more than one signal motif. Using truncated ARD1 molecules, expressed as green fluorescent fusion proteins, it was found that the signal for lysosomal localization was present in residues 301 to 402 of the GAP domain. Site-specific mutagenesis demonstrated that the sequence (369)KXXXQ(373) in the GAP domain was responsible for lysosomal localization. Association of ARD1 with the Golgi apparatus required tyrosine-based motifs. A green fluorescent fusion protein containing the QKQQQQF motif was partially associated with lysosomes, suggesting that this motif contains the information sufficient for lysosomal targeting. These results suggest that ARD1 is a multidomain protein with ARF and GAP regions, which contain Golgi and lysosomal localization signals, respectively, that could function in vesicular trafficking.