Phosphorylation influences the binding of the yeast RAP1 protein to the upstream activating sequence of the PGK gene.

Yeast repressor activator protein 1 (RAP1) binds in vitro to specific DNA sequences that are found in diverse genetic elements. Expression of the yeast phosphoglycerate kinase gene (PGK) requires the binding of RAP1 to the activator core sequence within the upstream activating sequence (UAS) of PGK. A DNA fragment Z+ which contains the activator core sequence of the PGK(UAS) has been shown to bind RAP1. Here we report that phosphatase treatment of RAP1 affected its binding to the PGK(UAS) but that this depended on the nature of the sequence flanking the 5' end of the activator core sequence. When the sequence flanking the 5' end of the activator core sequence was different from the PGK RAP1-binding site, phosphatase treatment of RAP1 decreased its binding to the DNA. When the 5' end of the binding site was a match to the PGK RAP1-binding site dephosphorylation of RAP1 increased RAP1 binding to the DNA. These observations were reproduced when the minimal functional DNA-binding domain of the RAP1 protein was used, implicating a phosphorylation-dependent binding of RAP1. This is the first evidence for phosphorylation-dependent binding of RAP1.     

The yeast telomere-binding protein RAP1 binds to and promotes the formation of DNA quadruplexes in telomeric DNA.

The protein RAP1 is essential for the maintenance of the telomeres of Saccharomyces cerevisiae and binds in vitro to multiple sites found within the TG1-3 telomeric repeats. We show here that, in addition to its known binding activity for double-stranded DNA, RAP1 binds sequence-specifically to the GT-strands. This indicates that RAP1 is the protein that binds to the telomeric terminal GT-tails. Furthermore, we have found that RAP1 binds to and promotes the formation of G-tetrads, i.e. DNA quadruplexes, in GT-strand oligonucleotides at nanomolar concentrations. The formation of DNA quadruplexes appears to involve the intermolecular association of GT-strands. The minimal DNA-binding domain of RAP1 (DBD) binds only to double-stranded DNA, so that the novel DNA-binding activity we have found involves regions of the protein located outside of the DBD. The finding that a telomeric protein promotes the formation of G-tetrads argues for the use of DNA quadruplexes in telomere association.     

Structural homology between DNA binding sites of DNA polymerase beta and DNA topoisomerase II

Unsaturated long-chain fatty acids selectively bind to the DNA binding sites of DNA polymerase beta and DNA topoisomerase II, and inhibit their activities, although the amino acid sequences of these enzymes are markedly different from each other. Computer modeling analysis revealed that the fatty acid interaction interface in both enzymes has a group of four amino acid residues in common, forming a pocket which binds to the fatty acid molecule. The four amino acid residues were Thr596, His735, Leu741 and Lys983 for yeast DNA topoisomerase II, corresponding to Thr79, His51, Leu11 and Lys35 for rat DNA polymerase beta. Using three-dimensional structure model analysis, we determined the spatial positioning of specific amino acid residues binding to the fatty acids in DNA topoisomerase II, and subsequently obtained supplementary information to build the structural model.     

A human protein specific for the immunoglobulin octamer DNA motif contains a functional homeobox domain

The homeobox domain is shared by Drosophila homeotic proteins, yeast mating type proteins, and some functionally uncharacterized mammalian proteins. A lymphoid-restricted human protein that binds to the immunoglobulin octamer regulatory motif was shown to contain an amino acid sequence that has 33% amino acid identity with the consensus sequence of the previously cloned homebox domains. This homeobox gene was localized to chromosome 19, thus mapping separately from other human homebox genes. A mutant protein containing amino acid substitutions within a putative helix-turn-helix motif in the homeobox domain did not bind DNA detectably. This human homeobox protein was shown to bind the same DNA sequence as the homeobox domains of the yeast mating type proteins and Drosophila homeotic protein, suggesting that homeobox proteins may have closely related DNA binding characteristics.     

Identification of domains of the human papillomavirus type 11 E1 helicase involved in oligomerization and binding to the viral origin

The E1 helicase of papillomavirus is required, in addition to host cell DNA replication factors, during the initiation and elongation phases of viral episome replication. During initiation, the viral E2 protein promotes the assembly of enzymatically active multimeric E1 complexes at the viral origin of DNA replication. In this study we used the two-hybrid system and chemical cross-linking to demonstrate that human papillomavirus type 11 (HPV11) E1 can self-associate in yeast and form hexamers in vitro in a reaction stimulated by single-stranded DNA. Self-association in yeast was most readily detected using constructs spanning the E1 C-terminal domain (amino acids 353 to 649) and was dependent on a minimal E1-E1 interaction region located between amino acids 353 and 431. The E1 C-terminal domain was also able to oligomerize in vitro but, in contrast to wild-type E1, did so efficiently in the absence of single-stranded DNA. Sequences located between amino acids 191 and 353 were necessary for single-stranded DNA to modulate oligomerization of E1 and were also required, together with the rest of the C terminus, for binding of E1 to the origin. Two regions within the C-terminal domain were identified as important for oligomerization: the ATP-binding domain and region A, which is located within the minimal E1-E1 interaction domain and is one of four regions of E1 that is highly conserved with the large T antigens of simian virus 40 and polyomavirus. Amino acid substitutions of highly conserved residues within the ATP-binding domain and region A were identified that reduced the ability of E1 to oligomerize and bind to the origin in vitro and to support transient DNA replication in vivo. These results support the notion that oligomerization of E1 occurs primarily through the C-terminal domain of the protein and is allosterically regulated by DNA and ATP. The bipartite organization of the E1 C-terminal domain is reminiscent of that found in other hexameric proteins and suggests that these proteins may oligomerize by a similar mechanism.     

A new alpha-helical extension promotes RNA binding by the dsRBD of Rnt1p RNAse III

Rnt1 endoribonuclease, the yeast homolog of RNAse III, plays an important role in the maturation of a diverse set of RNAs. The enzymatic activity requires a conserved catalytic domain, while RNA binding requires the double-stranded RNA-binding domain (dsRBD) at the C-terminus of the protein. While bacterial RNAse III enzymes cleave double-stranded RNA, Rnt1p specifically cleaves RNAs that possess short irregular stem-loops containing 12–14 base pairs interrupted by internal loops and bulges and capped by conserved AGNN tetraloops. Consistent with this substrate specificity, the isolated Rnt1p dsRBD and the 30–40 amino acids that follow bind to AGNN-containing stem-loops preferentially in vitro. In order to understand how Rnt1p recognizes its cognate processing sites, we have defined its minimal RNA-binding domain and determined its structure by solution NMR spectroscopy and X-ray crystallography. We observe a new carboxy-terminal helix following a canonical dsRBD structure. Removal of this helix reduces binding to Rnt1p substrates. The results suggest that this helix allows the Rnt1p dsRBD to bind to short RNA stem-loops by modulating the conformation of helix α1, a key RNA-recognition element of the dsRBD.     

In vitro assembly complex formation of TRAIP CC and RAP 80 zinc finger motif revealed by our study

BackgroundTumor necrosis factor interacting protein (TRAIP/TRIP) is an important cell-signaling molecule that prevents the TNF-induced-nuclear factor kappa-light-chain-enhancer of activated B cells (NF-κB) activation via direct interaction with TRAF 2 protein. TRAIP is a crucial downstream signaling molecule, implicated in several signaling pathways. Due to these multifunctional effects, TRAIP is more related to cellular mitosis, chromosome segregation, and DNA damage response. Tumor necrosis factor interacting protein is a downstream signaling molecule that contains a RING domain with E3 ubiquitin ligase activity at the N terminal side followed by coiled-coil and C terminal leucine zipper domain. Human TRAIP is constituted of 469 amino acids with 76% sequence similarity with the mouse TRAIP protein. Although, the main inhibitory function of TRAIP has been known for decades, however, in vitro interaction of TRAIPCC domain with RAP80 Zinc finger motif has not been reported yet. Besides, RAP80, the binding partner of TRAIPCC protein has been implicated in DNA damage response.ResultsOur in vitro study shows that the TRAIP CC (64–166) associates with the RAP80 zinc finger of corresponding amino acid 490–584. However, TRAIP CCLZ (66–260) and TRAIP RINGCC (1 = 157) failed to interact with the RAP80 zinc finger of corresponding amino acid 490–584. The current study reinforces TRAIP CC (64–166) and RAP80 zinc finger of corresponding amino acid 490–584 associates to form a complex. Moreover, SDS PAGE arbitrated the homogeneity of RAP80 Zinc finger and TRAIP CC of corresponding amino acid 490–584 and 64–166, respectively.ConclusionIn vitro, a specific interaction was observed between the TRAIP CC (64–166) and the RAP80 zinc finger of the corresponding amino acid 490–584 and a specific binding area of the RAP80 zinc finger motif were investigated. The TRAIPCC region is required for the complex to bind to the RAP80-Zn finger motif. This strategy may be necessary for the RAP80 zinc finger activity to the TRAIP CC protein.     

Novel structural and functional mode of a knot essential for RNA binding activity of the Esa1 presumed chromodomain

Chromodomains are methylated histone binding modules that have been widely studied. Interestingly, some chromodomains are reported to bind to RNA and/or DNA, although the molecular basis of their RNA/DNA interactions has not been solved. Here we propose a novel binding mode for chromodomain-RNA interactions. Essential Sas-related acetyltransferase 1 (Esa1) contains a presumed chromodomain in addition to a histone acetyltransferase domain. We initially determined the solution structure of the Esa1 presumed chromodomain and showed it to consist of a well-folded structure containing a five-stranded β-barrel similar to the tudor domain rather than the canonical chromodomain. Furthermore, the domain showed no RNA/DNA binding ability. Because the N-terminus of the protein forms a helical turn, we prepared an N-terminally extended construct, which we surprisingly found to bind to poly(U) and to be critical for in vivo function. This extended protein contains an additional β-sheet that acts as a knot for the tudor domain and binds to oligo(U) and oligo(C) with greater affinity compared with other oligo-RNAs and DNAs examined thus far. The knot does not cause a global change in the core structure but induces a well-defined loop in the tudor domain itself, which is responsible for RNA binding. We made 47 point mutants in an esa1 mutant gene in yeast in which amino acids of the Esa1 knotted tudor domain were substituted to alanine residues and their functional abilities were examined. Interestingly, the knotted tudor domain mutations that were lethal to the yeast lost poly(U) binding ability. Amino acids that are related to RNA interaction sites, as revealed by both NMR and affinity binding experiments, are found to be important in vivo. These findings are the first demonstration of how the novel structure of the knotted tudor domain impacts on RNA binding and how this influences in vivo function.     

H1 family histones in the nucleus. Control of binding and localization by the C-terminal domain

H1 histones bind to DNA as they enter and exit the nucleosome. H1 histones have a tripartite structure consisting of a short N-terminal domain, a highly conserved central globular domain, and a lysine-and arginine-rich C-terminal domain. The C-terminal domain comprises approximately half of the total amino acid content of the protein, is essential for the formation of compact chromatin structures, and contains the majority of the amino acid variations that define the individual histone H1 family members. This region contains several cell cycle-regulated phosphorylation sites and is thought to function through a charge-neutralization process, neutralizing the DNA phosphate backbone to allow chromatin compaction. In this study, we use fluorescence microscopy and fluorescence recovery after photobleaching to define the behavior of the individual histone H1 subtypes in vivo. We find that there are dramatic differences in the binding affinity of the individual histone H1 subtypes in vivo and differences in their preference for euchromatin and heterochromatin. Further, we show that subtype-specific properties originate with the C terminus and that the differences in histone H1 binding are not consistent with the relatively small changes in the net charge of the C-terminal domains.     

C-terminal truncation of RAP1 results in the deregulation of telomere size, stability, and function in Saccharomyces cerevisiae.

The Saccharomyces cerevisiae DNA-binding protein RAP1 is capable of binding in vitro to sequences from a wide variety of genomic loci, including upstream activating sequence elements, the HML and HMR silencer regions, and the poly(G1-3T) tracts of telomeres. Recent biochemical and genetic studies have suggested that RAP1 physically and functionally interacts with the yeast telomere. To further investigate the role of RAP1 at the telomere, we have identified and characterized three intragenic suppressors of a temperature-sensitive allele of RAP1, rap1-5. These telomere deficiency (rap1t) alleles confer several novel phenotypes. First, telomere tract size elongates to up to 4 kb greater than sizes of wild-type or rap1-5 telomeres. Second, telomeres are highly unstable and are subject to rapid, but reversible, deletion of part or all of the increase in telomeric tract length. Telomeric deletion does not require the RAD52 or RAD1 gene product. Third, chromosome loss and nondisjunction rates are elevated 15- to 30-fold above wild-type levels. Sequencing analysis has shown that each rap1t allele contains a nonsense mutation within a discrete region between amino acids 663 and 684. Mobility shift and Western immunoblot analyses indicate that each allele produces a truncated RAP1 protein, lacking the C-terminal 144 to 165 amino acids but capable of efficient DNA binding. These data suggest that RAP1 is a central regulator of both telomere and chromosome stability and define a C-terminal domain that, while dispensable for viability, is required for these telomeric functions.     

Sequence-specific DNA recognition by the myb-like domain of the human telomere binding protein TRF1: a model for the protein-DNA complex.

Telomeres consist of tandem arrays of short G-rich sequence motifs packaged by specific DNA binding proteins. In humans the double-stranded telomeric TTAGGG repeats are specifically bound by TRF1 and TRF2. Although telomere binding proteins from evolutionarily distant species are not sequence homologues, they share a Myb-like DNA binding motif. Here we have used gel retardation, primer extension and DNase I footprinting analyses to define the binding site of the isolated Myb-like domain of TRF1 and present a three-dimensional model for its interaction with human telomeric DNA. Our results suggest that the Myb-like domain of TRF1 recognizes a binding site centred on the sequence GGGTTA and that its DNA binding mode is similar to that of the homeodomain-like motifs of the yeast telomere binding protein RAP1. The implications of these findings for recognition of telomeric DNA in general are discussed.     

Differential affinity and cooperativity functions of the amino-terminal 70 residues of lambda integrase

The site-specific recombinase (Int) of bacteriophage lambda is a heterobivalent DNA-binding protein that binds two different classes of DNA-binding sites within its recombination target sites. The several functions of Int are apportioned between a large carboxy-terminal domain that cleaves and ligates DNA at each of its four "core-type" DNA-binding sites and a small amino-terminal domain, whose primary function is binding to each of its five "arm-type" DNA sites, which are distant from the core region. Int bridges between the two classes of binding sites are facilitated by accessory DNA-bending proteins that along with Int comprise higher-order recombinogenic complexes. We show here that although the 64 amino-terminal residues of Int bind efficiently to a single arm site, this protein cannot form doubly bound complexes on adjacent arm sites. However, 1-70 Int does show the same cooperative binding to adjacent arm sites as the full length protein. We also found that 1-70 Int specifies cooperative interactions with the accessory protein Xis when the two are bound to their adjacent cognate sites P2 and X1, respectively. To complement the finding that these two amino-terminal domain functions (along with arm DNA binding) are all specified by residues 1-70, we determined that Thr75 is the first residue of the minimal carboxy-terminal domain, thereby identifying a specific interdomain linker region. We have measured the affinity constants for Int binding to each of the five arm sites and the cooperativity factors for Int binding to the two pairs of adjacent arm sites, and we have identified several DNA structural features that contribute to the observed patterns of Int binding to arm sites. Taken together, the results highlight several interesting features of arm DNA binding that invite speculation about additional levels of complexity in the regulation of lambda site-specific recombination.     

Dominant thermodynamic role of the third independent receptor binding site in the receptor-associated protein RAP.

The 39 kDa receptor-associated protein (RAP) is a three-domain escort protein in the secretory pathway for several members of the low-density lipoprotein receptor (LDLR) family of endocytic receptors, including the LDLR-related protein (LRP). The minimal functional unit of LRP required for efficient binding to RAP is composed of complement-type repeat (CR)-domain pairs, located in clusters on the extracellular part of LRP. Here we investigate the binding of full-length RAP and isolated RAP domains 1-3 to an ubiquitin-fused CR-domain pair consisting of the fifth and sixth CR domains of LRP (U-CR56). As shown by isothermal titration calorimetric analysis of simple RAP domains as well as adjoined RAP domains, all three RAP domains bind to this CR-domain pair in a noncooperative way. The binding of U-CR56 to RAP domains 1 and 2 is (at room temperature) enthalpically driven with an entropy penalty (K(D) = 2.77 x 10(-6) M and 1.85 x 10(-5) M, respectively), whereas RAP domain 3 binds with a substantially lower enthalpy, but is favored due to a positive entropic contribution (K(D) = 1.71 x 10(-7) M). The heat capacity change for complex formation between RAP domain 1 and the CR-domain pair is -1.65 kJ K(-1) mol(-1). There is an indication of a conformational change in RAP domain 3 upon binding in the surface plasmon resonance analysis of the interaction. The different mechanisms of binding to RAP domains 1 and 3 are further substantiated by the different effects on binding of mutations of the Asp and Trp residues in the LRP CR5 or CR6 domains, which are important for the recognition of several ligands.