Rapid mapping by transposon mutagenesis of epitopes on the muscular dystrophy protein, dystrophin.

Antibody-binding epitopes in the central helical region of the muscular dystrophy protein, dystrophin, have been mapped using a new strategy of transposon mutagenesis. Tn1000 transposons carrying translation termination codons were introduced randomly by bacterial mating into a large fragment of dystrophin cDNA in a pEX2 plasmid to produce a library of transformants expressing truncated dystrophin fusion proteins. Epitopes were progressively lost as the expressed sequences were shortened, enabling the epitopes recognised by 22 monoclonal antibodies to be placed in order along the dystrophin molecule without in vitro manipulation of DNA. The C-terminus of each truncated fusion protein was precisely located within the dystrophin sequence by direct sequencing of pEX2 transformants using transposon-specific primers. Sequences as short as 7 and 17 amino-acids have been identified as essential for antibody binding in this way. Nineteen of the 22 monoclonal antibodies had been selected for their ability to bind both native and SDS-denatured dystrophin and 15 of these bind to one sequence of 74 amino-acids (residues 1431-1505 of the 3684 residue sequence). This may be an area of high immunogenicity or of close structural similarity between native dystrophin and the SDS-treated recombinant fragment used for immunization.     

Replication of bacteriophage M13. XII. In vivo cross-linking of a phage-specific DNA binding protein to the single-stranded DNA of bacteriophage M13 by ultraviolet irradiation.

Ultraviolet irradiation of bacteriophage M13-infected Escherichia coli induces the formation of a covalent crosslink between progeny single-stranded DNA and the M13 DNA binding protein, the product of gene 5. The crosslinked complex is readily isolated from detergent-treated lysates by sucrose-gradient velocity sedimentation and CsCl equilibrium sedimentation in the presence of detergent. The crosslinked complex produced with optimal levels of irradiation sediments 1.06 times faster than uncomplexed M13 single-stranded DNA, has a buoyant density of approximately 1.62 to 1.64 g/cm³ and a protein to DNA mass ratio of 2 mg protein per mg DNA. Cleavage of the crosslinked complex with cyanogen bromide or trypsin yields products similar to those produced by cleavage of purified M13 gene 5 protein. The crosslink is located close to the carboxyl terminus of the protein.     

An electron microscopic method for the mapping of proteins attached to nucleic acids.

An electron microscopic method for demonstrating the presence of and mapping the positions of proteins specifically bound to nucleic acids is described. The nucleic acid-protein complex is treated with dinitrofluorobenzene under conditions such that dinitrophenyl (DNP) groups are attached to nucleophilic groups on the protein, with only a low level of random attachment to the nuclei acid. This product is treated with rabbit anti-DNP IgG. The position of the protein-(DNP)n(IgG)m complex on the nucleic acid strand can be observed by electron microscopy by protein free spreading methods and, in many cases, by cytochrome-c spreading. If necessary for visualization by the latter method, the size of the labeled region can be increased by treatment with goat anti-rabbit IgG. High efficiency of electron microscopic labeling is achieved. Examples studied are: the adenovirus-2 DNA terminal protein, a protein covalently bound to SV40 DNA, DNA polymerase I bound to DNA, E. coli RNA polymerase bound to T7 DNA, and proteins UV crosslinked to avian sarcoma virus RNA.     

Histone-DNA interactions within chromatin. Isolation of histones from DNA-histone adducts induced in nuclei by UV light.

We have developed a method by which to isolate histones that have been crosslinked to DNA following irradiation of calf thymus nuclei by UV light. The procedure involves separation of protein-DNA adducts from uncrosslinked protein by Sepharose 4B chromatography under dissociating conditions. Histones which are crosslinked to DNA are released by chemical hydrolysis of the DNA and identified by SDS gel electrophoresis. The results indicate that, of the histones, H1 and H3 become crosslinked to the DNA most readily under our irradiation conditions.     

Photosynthesizing Leaves and Nodulated Roots as Donors of Carbon to Protein of the Shoot of the Field Pea (Pisum arvense L.)

In Pisum arvense, the amides and amino-acids normally suppliedto the shoot in the transpiration stream transfer carbon toprotein largely throught the amino-acids, aspartic acid (+asparagine),glutarnic acid (+glutamine), threonine, lysine, arginine, andproline. Carbon from carbon dioxide enters the protein of photosynthesizingtissues through an essentially complementary set of amino-acidsincluding glycine, alanine, serine, valine, and the aromaticamino-acids tyrosine, phenylalnine, and histidine. Young tissuesof the shoot synthesize certain amino-acids de novo by metabolismof sugars supplied from photosynthesizing leaves. Each mature leaf on a shoot contributes carbon to current synthesisof protein at the shoot apex. Sucrose accounts for more than90 per cent of the labelled carbon leaving any age of leaf whichhas been fed with ¹⁴CO₂. Upper leaves supply labelled assimilatesdirectly to the shoot apex, and the radiocarbon from these assimilatesis subsequently incorporated into a wide range of amino-acidunits of protein. The majority of the labelled assimilates exportedfrom a lower leaf move downwards to the root and nodules and,in consequence, the amino-acids and amides associated with rootmetabolism are strongly represented among the compounds eventuallylabelled in the apical region of the shoot.     

Identification of two functional regions in Fis: the N-terminus is required to promote Hin-mediated DNA inversion but not lambda excision.

The Fis protein of E. coli binds to a recombinational enhancer sequence that is required to stimulate Hin-mediated DNA inversion. Fis is also required for efficient lambda prophase excision in vivo. The properties of mutant Fis proteins were examined in vivo and in vitro with respect to their stimulatory effects on these two different site-specific DNA recombination reactions. Both recombination reactions are dramatically affected by mutations altering a helix-turn-helix DNA binding motif located near the Fis C-terminus (residues 74-93). These mutations invariably decrease DNA binding affinity and some cause reduced DNA bending. Mutations in the Fis N-terminal region reduce or abolish the stimulation of Hin-mediated DNA recombination by Fis, but have little or no effect on DNA binding or lambda excision. We conclude that there are at least two functionally distinct domains in Fis: a C-terminal DNA binding region that is required for promoting both DNA recombination reactions and an N-terminal region that is uniquely required for Hin-mediated inversion.     

The rolling-circle plasmid pTN1 from the hyperthermophilic archaeon Thermococcus nautilus

The hyperthermophilic archaeon Thermococcus nautilus carries a plasmid, pTN1, which encodes a rolling-circle (RC) replication initiator protein of 74 kDa (Rep74) and an orphan protein of 24 kDa (p24). The Rep74 protein is homologous to the Rep75 protein encoded by the RC plasmid pGT5 from Pyrococcus abyssi. Comparative analysis of Rep74 and Rep75 sequences shows that these proteins correspond to a new family of RC initiators formed by the fusion of a Rep domain with an N-terminal domain of unknown function. Surprisingly, the Rep domain of Rep74/75 is more closely related to transposases encoded by IS elements than to Rep proteins of other RC plasmids. The p24 protein contains a hydrophobic segment, a highly charged region and a zinc finger motif. A recombinant p24 protein lacking the hydrophobic segment binds and condenses both single- and double-stranded DNA, and forms DNA aggregates with extreme compaction at high protein to DNA ratio. In addition to encoding proteins of significant interest, pTN1 is remarkable by being the only characterized plasmid isolated from a Thermococcus strain, thus being useful to develop genetic tools in Thermococcus kodakaraensis for which gene disruption methods became recently available.     

Carboxy-terminal cleavage of the human foamy virus Gag precursor molecule is an essential step in the viral life cycle.

Foamy viruses (FVs) express the Gag protein as a precursor with a molecular mass of 74 kDa (pr74) from which a 70-kDa protein (p70) is cleaved by the viral protease. To gain a better understanding of FV Gag protein processing and function, we have generated and analyzed mutants in the C-terminal gag region of an infectious molecular clone. Our results show that p70 is an N-terminal cleavage product of pr74. However, we were unable to identify a p4 molecule. A virus mutant expressing p70 only was found to be replication competent, albeit at very low titers compared to those of wild-type virus. A strong tendency to synthesize and cleave a pr74 molecule was deduced from the occurrence of revertants upon transfection of this mutant. Substitution of the p6gag domain of human immunodeficiency virus type 1 for the p4 domain of FV resulted in a stable chimeric virus which replicated to titers 10 times lower than those of wild-type virus. FV Gag protein was found to be phosphorylated at serine residues. Mutagenesis of serines conserved in the p4 domain had no influence on viral replication in cell culture. The p70/p74 Gag cleavage was found to be required for viral infectivity, since mutagenesis of the putative cleavage site led to replication-incompetent virus. Interestingly, the cleavage site mutants were defective in the intracellular cDNA synthesis of virion DNA, which indicates that correct FV particle formation and the generation of virion DNA are functionally linked.     

Electrospray ionization mass spectrometric characterization of photocrosslinked DNA-EcoRI DNA methyltransferase complexes.

We describe a novel strategy combining photocrosslinking and HPLC-based electrospray ionization mass spectrometry to identify UV crosslinked DNA-protein complexes. Eco RI DNA methyltransferase modifies the second adenine within the recognition sequence GAATTC. Substitution of 5-iodouracil for the thymine adjacent to the target base (GAATTC) does not detectably alter the DNA-protein complex. Irradiation of the 5-iodouracil-substituted DNA-protein complex at various wavelengths was optimized, with a crosslinking yield >60% at 313 nm after 1 min. No protein degradation was observed under these conditions. The crosslinked DNA-protein complex was further analyzed by electrospray ionization mass spectrometry. The total mass is consistent with irradiation-dependent covalent bond formation between one strand of DNA and the protein. These preliminary results support the possibility of identifying picomole quantities of crosslinked peptides by similar strategies.     

Laser crosslinking of E. coli RNA polymerase and T7 DNA.

The first photochemical crosslinking of a protein to a nucleic acid using laser excitation is reported. A single, 120 mJ, 20 ns pulse at 248 nm crosslinks about 10% of bound E. coli RNA polymerase to T7 DNA under the conditions studied. The crosslinking yield depends on mercaptoethanol concentration, and is a linear function of laser intensity. The protein subunits crosslinked to DNA are beta, beta' and sigma.     

A Stoichiometry Driven Universal Spatial Organization of Backbones of Folded Proteins: Are there Chargaff's Rules for Protein Folding?

Abstract

Protein folding is at least a six decade old problem, since the times of Pauling and Anfinsen. However, rules of protein folding remain elusive till date. In this work, rigorous analyses of several thousand crystal structures of folded proteins reveal a surprisingly simple unifying principle of backbone organization in protein folding. We find that protein folding is a direct consequence of a narrow band of stoichiometric occurrences of amino-acids in primary sequences, regardless of the size and the fold of a protein. We observe that “preferential interactions” between amino-acids do not drive protein folding, contrary to all prevalent views. We dedicate our discovery to the seminal contribution of Chargaff which was one of the major keys to elucidation of the stoichiometry-driven spatially organized double helical structure of DNA.     

The Middle Region of an HP1-binding Protein, HP1-BP74, Associates with Linker DNA at the Entry/Exit Site of Nucleosomal DNA

In higher eukaryotic cells, DNA molecules are present as chromatin fibers, complexes of DNA with various types of proteins; chromatin fibers are highly condensed in metaphase chromosomes during mitosis. Although the formation of the metaphase chromosome structure is essential for the equal segregation of replicated chromosomal DNA into the daughter cells, the mechanism involved in the organization of metaphase chromosomes is poorly understood. To identify proteins involved in the formation and/or maintenance of metaphase chromosomes, we examined proteins that dissociated from isolated human metaphase chromosomes by 0.4 m NaCl treatment; this treatment led to significant chromosome decondensation, but the structure retained the core histones. One of the proteins identified, HP1-BP74 (heterochromatin protein 1-binding protein 74), composed of 553 amino acid residues, was further characterized. HP1-BP74 middle region (BP74Md), composed of 178 amino acid residues (Lys⁹⁷–Lys²⁷⁴), formed a chromatosome-like structure with reconstituted mononucleosomes and protected the linker DNA from micrococcal nuclease digestion by ∼25 bp. The solution structure determined by NMR revealed that the globular domain (Met¹⁵³–Thr²³⁷) located within BP74Md possesses a structure similar to that of the globular domain of linker histones, which underlies its nucleosome binding properties. Moreover, we confirmed that BP74Md and full-length HP1-BP74 directly binds to HP1 (heterochromatin protein 1) and identified the exact sites responsible for this interaction. Thus, we discovered that HP1-BP74 directly binds to HP1, and its middle region associates with linker DNA at the entry/exit site of nucleosomal DNA in vitro.     

Role of Aromatic Amino-acid Residues in the Binding of Enzymes and Proteins to Nucleic Acids

MANY studies have been made of the specificity of interaction between nucleic acids and polypeptides, proteins and enzymes^1,2. Electrostatic forces between basic amino-acids and phosphate groups contribute to the stability of the complexes, but selective recognition requires more specific interactions which are not yet understood. The recognition of a specific region of a nucleic acid could be explained if this region has some particular conformation or if there are specific interactions between a few amino-acid residues and the bases of this region. We wish to report results which show that the aromatic amino-acids tryptophan and tyrosine can interact with nucleic acid bases in double stranded nucleic acids. They suggest that aromatic amino-acid residues of enzymes and proteins could participate in the binding to nucleic acids by intercalating between the bases and thus constraining the nucleic acid molecule to adopt a definite position with respect to the protein molecule.     

Comparison of the interactions of the adenovirus type 2 major core protein and its precursor with DNA.

The interactions of the major core protein of adenovirus type 2 (Ad2) protein VII, and its precursor, protein pre-VII, with viral DNA, were studied using UV light induced crosslinking of 32P-labelled oligonucleotides to the proteins. Proteolytic fragments of these two proteins that contain DNA-binding domains were identified by virtue of their covalently attached, alkali-resistant 32P-radioactivity. The overall efficiency of crosslinking of protein pre-VII to DNA, in H2ts1 virions assembled at 39 degrees C, was comparable to that of the crosslinking of protein VII to DNA in Ad2 virions. However, a protease V8 fragment comprising the N-terminal half of protein pre-VII crosslinked to DNA at least ten times more efficiently than the corresponding N-terminal fragment of protein VII, which is truncated by the removal of 23 amino acids from the N-terminus of protein pre-VII during virion maturation.     

DNA sequence of the US component of the varicella-zoster virus genome

The linear duplex DNA molecule of varicella-zoster virus is 120 000 bp in size and has the sequence arrangement UL-IRS-US-TRS, where UL and US are unique sequences and IRS and TRS are inverted repeats flanking US. The primary structure of the cloned SstI g DNA fragment containing US (5232 bp) and adjacent portions of IRS and TRS (426 bp of each) was determined, and the following model for genetic expression was derived from an analysis of the sequence. The region specifies four mRNAs encoding primary translation products with mol. wts. of 11, 44, 39 and either 74 or 70 kd. The 39-and 70-kd proteins have primary structures characteristic of membrane proteins. The mRNAs encoding the 11- and 74/70-kd proteins extend from opposite sides of US into IRS/TRS, thus sharing a common 3' terminus. These proteins do not share a common carboxy terminus because the coding region for the 11-kd protein terminates at the junction between US and IRS, whereas that for the 74/70-kd protein extends into TRS. The analysis affirms the hypothesis that the extent of inverted repeats in herpesvirus genomes is primarily a result of constraints imposed by adjacent protein coding sequences.