The in vivo and in vitro cross-binding of the colicin endonuclease-specific immunity proteins toward the DNase domain of colicin E9 is described. In vivo cross-protection was tested by toxin plate assays in which bacterial cells overexpressing each immunity (Im2, Im7, Im8, and Im9) were challenged with the ColE9 toxin. Im9, the cognate immunity protein, renders cells completely resistant toward very high concentrations of the toxin (> 1 mg/mL), whereas the noncognate immunities display a spectrum of weaker cross-reactivities (< 0.01 mg/mL). The order of biological protection in this assay was Im9 >> Im2 > Im8, with Im7 providing no colicin E9 resistance. In vitro binding between the immunity proteins and the E9 DNase was analyzed by determining the dissociation constants for E9 DNase-Im protein complexes at pH 7.0 in the presence of 200 mM salt and at 25 degrees C. Stopped-flow fluorescence experiments suggest that both Im2 and Im8 associate with the E9 DNase by a two-step mechanism, in which the rate constants for both the bimolecular association (k1 = approximately 6 x 10(7) M-1 s-1) and the subsequent conformational change (k2 + k-2 = 4-5 s-1) are very similar to Im9 binding under the same conditions. Fluorescence chase experiments defined the dissociation rate constants for Im2 and Im8. The estimated values are 10(6)- and 10(8)-fold, respectively, faster than the off-rate for the Im9 protein.(ABSTRACT TRUNCATED AT 250 WORDS)
Poly(ADP-ribose)polymerase-1 (PARP-1) is a highly abundant chromatin-associated enzyme present in all higher eukaryotic cell nuclei, where it plays key roles in the maintenance of genomic integrity, chromatin remodeling and transcriptional control. It binds to DNA single- and double-strand breaks through an N-terminal region containing two zinc fingers, F1 and F2, following which its C-terminal catalytic domain becomes activated via an unknown mechanism, causing formation and addition of polyadenosine-ribose (PAR) to acceptor proteins including PARP-1 itself. Here, we report a biophysical and structural characterization of the F1 and F2 fingers of human PARP-1, both as independent fragments and in the context of the 24-kDa DNA-binding domain (F1 + F2). We show that the fingers are structurally independent in the absence of DNA and share a highly similar structural fold and dynamics. The F1 + F2 fragment recognizes DNA single-strand breaks as a monomer and in a single orientation. Using a combination of NMR spectroscopy and other biophysical techniques, we show that recognition is primarily achieved by F2, which binds the DNA in an essentially identical manner whether present in isolation or in the two-finger fragment. F2 interacts much more strongly with nicked or gapped DNA ligands than does F1, and we present a mutational study that suggests origins of this difference. Our data suggest that different DNA lesions are recognized by the DNA-binding domain of PARP-1 in a highly similar conformation, helping to rationalize how the full-length protein participates in multiple steps of DNA single-strand breakage and base excision repair.
Ribosomes are universal translators of the genetic code into protein and represent macromolecular structures that are asymmetric, often heterogeneous, and contain dynamic regions. These properties pose considerable challenges for modern-day structural biology. Despite these obstacles, high-resolution x-ray structures of the 30S and 50S subunits have revealed the RNA architecture and its interactions with proteins for ribosomes from Thermus thermophilus, Deinococcus radiodurans, and Haloarcula marismortui. Some regions, however, remain inaccessible to these highresolution approaches because of their high conformational dynamics and potential heterogeneity, specifically the so-called L7͞ L12 stalk complex. This region plays a vital role in protein synthesis by interacting with GTPase factors in translation. Here, we apply tandem MS, an approach widely applied to peptide sequencing for proteomic applications but not previously applied to MDa complexes. Isolation and activation of ions assigned to intact 30S and 50S subunits releases proteins S6 and L12, respectively. Importantly, this process reveals, exclusively while attached to ribosomes, a phosphorylation of L12, the protein located in multiple copies at the tip of the stalk complex. Moreover, through tandem MS we discovered a stoichiometry for the stalk protuberance on Thermus thermophilus and other thermophiles and contrast this assembly with the analogous one on ribosomes from mesophiles. Together with evidence for a potential interaction with the degradosome, these results show that important findings on ribosome structure, interactions, and modifications can be discovered by tandem MS, even on well studied ribosomes from Thermus thermophilus.bacterial ribosomes ͉ L7͞L12 stalk complex ͉ mass spectrometry T he advent of atomic structures of the 30S and 50S subunits from Thermus thermophilus (1, 2), Deinococcus radiodurans (3), and Haloarcula marismortui (4) has revealed detailed information on the proteins that interact with rRNA. However, protein-protein interactions, particularly those in the stalk complex, are not well defined. In the 5.5-Å 70S structure of ribosomes from Thermus thermophilus density could not be assigned to L10, and only two of the four L7͞L12 proteins that have been proposed for Escherichia coli (5) were tentatively placed at the base of the stalk (6). Interestingly, the stalk complex is readily studied by MS where dissociation of proteins is governed primarily by the extent of protein-RNA interaction (7).The process of electrospray MS, first applied to the study of intact proteins in 1989 (8), is carried out by evaporation of protein-containing droplets to form multiply charged ions in the gas phase. Although not readily applied to MDa particles such as ribosomes, the dissociation of individual proteins and stalk complexes from the intact particle has been shown (7, 9, 10). Such spectra are extremely difficult to interpret in part because of the number of proteins (Ͼ50), their numerous posttranslational modifications, and the presence ...
Protein synthesis in mammalian cells requires initiation factor eIF3, an ϳ800-kDa protein complex that plays a central role in binding of initiator methionyl-tRNA and mRNA to the 40 S ribosomal subunit to form the 48 S initiation complex. The eIF3 complex also prevents premature association of the 40 and 60 S ribosomal subunits and interacts with other initiation factors involved in start codon selection. The molecular mechanisms by which eIF3 exerts these functions are poorly understood. Since its initial characterization in the 1970s, the exact size, composition, and post-translational modifications of mammalian eIF3 have not been rigorously determined. Two powerful mass spectrometric approaches were used in the present study to determine post-translational modifications that may regulate the activity of eIF3 during the translation initiation process and to characterize the molecular structure of the human eIF3 protein complex purified from HeLa cells. In the first approach, the bottom-up analysis of eIF3 allowed for the identification of a total of 13 protein components (eIF3a-m) with a sequence coverage of ϳ79%. Furthermore 29 phosphorylation sites and several other post-translational modifications were unambiguously identified within the eIF3 complex. The second mass spectrometric approach, involving analysis of intact eIF3, allowed the detection of a complex with each of the 13 subunits present in stoichiometric amounts. Using tandem mass spectrometry four eIF3 subunits (h, i, k, and m) were found to be most easily dissociated and therefore likely to be on the periphery of the complex. It is noteworthy that none of these four subunits were found to be phosphorylated. These data raise interesting questions about the function of phosphorylation as it relates to the core subunits of the complex. Molecular & Cellular Proteomics 6:1135-1146, 2007.The initiation phase of eukaryotic protein synthesis involves formation of an 80 S ribosomal complex containing the initiator methionyl-tRNA i bound to the initiation codon in the mRNA. This is a multistep process promoted by proteins called eukaryotic initiation factors (eIFs).1 Currently at least 12 eIFs, composed of at least 29 distinct subunits, have been identified (1). Mammalian eIF3, the largest initiation factor, is a multisubunit complex with an apparent molecular mass of ϳ800 kDa. This protein complex plays an essential role in translation by binding directly to the 40 S ribosomal subunit and promoting formation of the 43 S preinitiation complex consisting of the Met-tRNA i ⅐eIF2⅐GTP ternary complex, eIF1, eIF1A, and the 40 S ribosomal subunit (2, 3). The ability of eIF3 to bind to 40 S subunits in the absence of other initiation factors is enhanced by the presence of its loosely associated eIF3j subunit (4). The eIF3 complex also promotes binding of 5Ј-m 7 G-capped mRNA through its interaction with eIF4G, the largest member of the eIF4F cap-binding complex (5, 6). The 43 S preinitiation complex then scans the mRNA (together forming the 48 S complex) in a 5Ј ...
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