Probing the role of glutamic acid 144 in the EcoRI endonuclease using aspartic acid and glutamine replacements.

The x-ray structure of the EcoRI endonuclease-DNA complex (3) suggests that hydrogen bonds between amino acids, glutamic acid 144, arginine 145, and arginine 200, and major groove base moieties are the molecular determinants of specificity. We have investigated residue 144 using aspartate and glutamine substitutions introduced by site-directed mutagenesis. Substitution with glutamine results in a null phenotype (at least a 2000-fold reduction in activity). On the other hand, the aspartic acid mutant (ED144) retained in vivo activity. Substrate binding and catalytic studies were done with purified ED144 enzyme. The affinity of the ED144 enzyme for the canonical sequence 5'-GAATTC-3' is about 340-fold less than the wild-type (WT) enzyme, while its affinity for nonspecific DNA is about 50 times greater. The ED144 enzyme cleaves one strand in the EcoRI site in plasmid pBR322 with a kcat/Km similar to WT. In contrast to the WT enzyme, the ED144 enzyme dissociates after the first strand cleavage. Partitioning between cleavage and dissociation at the first and second cleavage steps for the ED144 enzyme is extremely salt-sensitive. The altered partitioning results largely from a destabilization of the enzyme-DNA complex, particularly the enzyme-nicked DNA complex, with only small changes in the respective cleavage rates. The hydrogen bonds of Glu-144 are critical, they appear to act cooperatively with other specificity contacts to stabilize the enzyme-DNA complex.

Reiterative copying by E.coli RNA polymerase during transcription initiation of mutant pBR322 tet promoters.

The major in vitro transcripts from the tet promoter of pBR322 derivatives pTA22 and pTA33 have heterogeneous 5' ends consisting of variable lengths of oligo(A). Their structure is 5'pppAnU..., where n ranges from 1 to greater than 12, but the template strand can encode at most four A residues at the site of transcription initiation. The abundance of additional A residues at the 5' end of the pTA22 and pTA33 tet transcripts could be reduced by elevating the concentration of UTP, but even at high concentrations (greater than 1 mM) non-cognate A residues were still observed. Aberrant initiation was not artifactual since the major and minor transcripts of the pBR322 tet promoter region, and other transcripts arising from minor promoters on pTA22 or pTA33 DNA all had unique 5' termini. Mixing experiments showed that RNA polymerase did not utilize pppA2-4-OH produced by abortive initiation as primers. The data suggest that the initial nascent RNA chain 'slips' in the 5' direction during elongation opposite T4 on the template strand causing RNA polymerase to reiteratively add A residues to the 5' end of the transcript. The generality and possible significance of this mechanism is discussed.

Comparison of the nucleotide and amino acid sequences of the RsrI and EcoRI restriction endonucleases.

The RsrI endonuclease, a type-II restriction endonuclease (ENase) found in Rhodobacter sphaeroides, is an isoschizomer of the EcoRI ENase. A clone containing an 11-kb BamHI fragment was isolated from an R. sphaeroides genomic DNA library by hybridization with synthetic oligodeoxyribonucleotide probes based on the N-terminal amino acid (aa) sequence of RsrI. Extracts of E. coli containing a subclone of the 11-kb fragment display RsrI activity. Nucleotide sequence analysis reveals an 831-bp open reading frame encoding a polypeptide of 277 aa. A 50% identity exists within a 266-aa overlap between the deduced aa sequences of RsrI and EcoRI. Regions of 75-100% aa sequence identity correspond to key structural and functional regions of EcoRI. The type-II ENases have many common properties, and a common origin might have been expected. Nevertheless, this is the first demonstration of aa sequence similarity between ENases produced by different organisms.

Determinants of EcoRI endonuclease sequence discrimination.

The arginine at position 200 of EcoRI endonuclease is thought to make two hydrogen bonds to the guanine of the sequence GAATTC and thus be an important determinant of sequence discrimination. Arg-200 was replaced by each of the other 19 naturally occurring amino acids, and the mutant endonucleases were assessed for activities in vivo and in vitro. The mutant endonuclease with lysine at position 200 exhibits the most in vivo activity of all the position 200 mutants, although the in vitro activity is less than 1/100th of wild-type activity. Five other mutants show more drastically reduced levels of in vivo activity (Cys, Pro, Val, Ser, and Trp). The Cys, Val, and Ser mutant enzymes appear to have in vivo activity which is specific for the wild-type canonical site despite the loss of hydrogen bonding potential at position 200. The Pro and Trp mutants retain in vivo activity which is independent of the presence of the EcoRI methylase. In crude cell lysates, only the Cys mutant shows a very low level of in vitro activity. None of the mutant enzymes show a preference for alternative sites in assays in vitro. The implications of these results are discussed.

Transcription initiation at the tet promoter and effect of mutations.

We have identified the startpoint for transcription in vitro of the tetracycline resistance gene (tet) of pBR322 and several deletion and insertion mutations which alter tet promoter structure. Tetracycline resistance in host bacteria correlates qualitatively with the efficiency of DNA fragments from these plasmids to promote tet transcription in vitro. Only in active promoters could we find by computer analysis promoter structures in which the -10 and -35 sequences and the relative spacing of the two regions agree with consensus sequence determinants. These data support the current model of the E. coli promoter sequence. Two promoter mutants gave heterogeneous 5' termini with additional A residues not encoded by the DNA sequence.

Purification and characterization of the restriction endonuclease RsrI, an isoschizomer of EcoRI.

Rhodobacter sphaeroides strain 630 produces restriction enzyme RsrI which is an isoschizomer of EcoRI. We have purified this enzyme and initiated a comparison with the EcoRI endonuclease. The properties of RsrI are consistent with a reaction mechanism similar to that of EcoRI: the position of cleavage within the -GAATTC-site is identical, the MgCl2 optimum for the cleavage is identical, and the pH profile is similar. Methylation of the substrate sequence by the EcoRI methylase protects the site from cleavage by the RsrI endonuclease. RsrI cross-reacts strongly with anti-EcoRI serum indicating three-dimensional structural similarities. We have determined the sequence of 34 N terminal amino acids for RsrI and this sequence possesses significant similarity to the EcoRI N terminus.

Clustering of null mutations in the EcoRI endonuclease.

EcoRI endonuclease mutants were isolated in a methylase-deficient background following in vitro hydroxylamine mutagenesis of plasmid pKG2 (Kuhn et al.: Gene 44:253-263, 1986). Mutants which survived high-level endonuclease expression (IPTG induction) were termed null mutants. Sixty-two of 121 null mutants tested by Western blot contained normal levels of endonuclease cross-reacting protein. The complete endonuclease gene was sequenced for 27 null mutants. This group was found to consist of 20 single base-change missense mutations, 6 double mutations, and 1 triple mutation. Ten of the 20 single mutations were clustered between residues 139 and 144. When examined with respect to the structure of the EcoRI-DNA complex (McClarin et al.: Science 234:1526-1541, 1986), these alterations were found to fall predominantly into two classes: substitutions at the protein-DNA interface or substitutions at the protein-protein (dimer) interface. Protein from several of the mutants was purified and sized by using HPLC. Wild-type EcoRI endonuclease and protein from three of the DNA interface mutations (Ala139----Thr, Gly140----Ser, Arg203----Gln) appeared to be dimeric, while protein from subunit interface mutations (Glu144----Lys, Glu152----Lys, Gly210----Arg) migrated as monomers.

Structure of the DNA-Eco RI endonuclease recognition complex at 3 A resolution.

The crystal structure of the complex between Eco RI endonuclease and the cognate oligonucleotide TCGCGAATTCGCG provides a detailed example of the structural basis of sequence-specific DNA-protein interactions. The structure was determined, to 3 A resolution, by the ISIR (iterative single isomorphous replacement) method with a platinum isomorphous derivative. The complex has twofold symmetry. Each subunit of the endonuclease is organized into an alpha/beta domain consisting a five-stranded beta sheet, alpha helices, and an extension, called the "arm," which wraps around the DNA. The large beta sheet consists of antiparallel and parallel motifs that form the foundations for the loops and alpha helices responsible for DNA strand scission and sequence-specific recognition, respectively. The DNA cleavage site is located in a cleft that binds the DNA backbone in the vicinity of the scissile bond. Sequence specificity is mediated by 12 hydrogen bonds originating from alpha helical recognition modules. Arg200 forms two hydrogen bonds with guanine while Glu144 and Arg145 form four hydrogen bonds to adjacent adenine residues. These interactions discriminate the Eco RI hexanucleotide GAATTC from all other hexanucleotides because any base substitution would require rupture of at least one of these hydrogen bonds.

Positive-selection vectors utilizing lethality of the EcoRI endonuclease.

The construction and use of a series of positive-selection vectors are described. These plasmids encode EcoRI endonuclease, the synthesis of which is under the control of the lacUV5 promoter. The pKG2 plasmid encodes a wild-type EcoRI endonuclease. In the absence of EcoRI methylase, the endonuclease is lethal. Cloning into any of the unique restriction sites within the endonuclease-coding gene allows survival of the transformed EcoRI-methylase-less host. The pKGW and pKGS plasmids encode an altered EcoRI endonuclease which, when repressed in a lacIQ host, allows survival in the absence of the methylase. Induction with IPTG, however, results in cell death as a result of high-level EcoRI synthesis. Cloning into any of the unique restriction sites within the EcoRI gene of pKGW or pKGS allows survival of derepressed transformed cells. These vectors strongly select for cloning events which inactivate the endonuclease gene.

Restoration of bacterioopsin gene expression in a revertant of Halobacterium halobium.

Restoration of bacterioopsin (bop) gene expression in a revertant of Halobacterium halobium was investigated. The phenotype of the revertant is the result of a translocation of the 588-base-pair (bp) sequence "ISH25", adjacent to an ISH24 insertion found in the parental mutant IV-4. These insertions are located about 1,400 bp upstream of the bop gene within the coding region of the putative brp (bacterioopsin-related protein) gene. The level at which the brp gene affects bop gene expression is unknown. Analysis of bop and brp gene transcription in the wild type, mutant IV-4, and the revertant supports the hypothesis that transcription of the putative brp gene is necessary for bop gene expression in the revertant. Eight insertion mutants of the Bop revertant were analyzed to further elucidate restoration of bop gene expression in the revertant. Bop mutants of the revertant were recovered with a frequency of about 10(-4) and were found to contain insertion elements in addition to ISH24 and "ISH25". Six-eighths of these mutants have the insertion element ISH2, and two mutants have previously uncharacterized insertion elements (ISH27 [1,400 bp] and ISH28 [1,000 bp]). ISH27 and ISH28 are confined to the more A + T-rich fraction of the H. halobium genome, as are most copies of other halobacterial insertion elements. The insertion sites in the Bop mutants of the revertant mapped within the coding region of the bop gene (three mutants), immediately upstream of the bop gene presumably in the bop promoter region (two mutants), or within a region from 241 to 449 bp upstream of the bop gene (three mutants). This distribution of insertion sites suggests that the integrity of the 526-bp region between the bop and the brp genes is important for bop gene expression in the revertant.

Characterization of a halobacterial gene affecting bacterio-opsin gene expression.

A substantial number of spontaneous bacterio-opsin mutants of Halobacterium halobium are the result of insertion elements up to 1400 bp upstream of the bacterio-opsin (bop) gene. The nucleotide sequence of 1800 bp upstream of the bop gene has been determined. There is a 1118 bp open reading frame (ORF) located within this region which is transcribed and which coincides with the distribution of insertion elements upstream of the bop gene in Bop mutants. Therefore, we propose that there is a gene (brp gene) 526 bp upstream of the bop gene. This putative gene is transcribed in the opposite direction as the bop gene and could encode a protein of 37,500 D (359 amino acids) with a codon usage similar to bacterio-opsin. The 5' terminus of the brp transcript has been determined. The brp transcript and the bop mRNA are complementary for 13 residues near their 5' termini and both transcripts start at or near the initiating codon of the gene. Both transcripts could form similar hairpin loop structures at their 5' termini which contain possible ribosomal binding sites. The DNA sequences immediately upstream of the bop and the brp genes have significant homologies and there is a short complementary sequence. The role of the brp gene in bacterio-opsin gene expression is unclear.

Kinked DNA in crystalline complex with EcoRI endonuclease.

The 3 A electron density map of a co-crystalline recognition complex between EcoRI endonuclease and the oligonucleotide TCGCGAATTCGCG reveals that a tight, complementary interface between the enzyme and the major groove of the DNA is the major determinant of sequence specificity. The DNA contains a torsional kink and other departures from the B conformation which unwind the DNA and thereby widen the major groove in the recognition site.

Characterization of insertions affecting the expression of the bacterio-opsin gene in Halobacterium halobium.

We have determined the sequence of the inverted repeats and duplicated target DNA of the halobacterial insertion elements ISH2 (520 bp), ISH23 (900 bp) and ISH24 (3000 bp) associated with bacterio-opsin (bop) mutants. ISH2 has a perfect 19 bp inverted repeat (3,5), while both ISH23 and ISH24 have imperfect inverted repeats of 29 bp and 14 bp respectively. ISH23 was shown to be highly homologous to ISH50 (6). Variable lengths of duplicated target DNA are found when ISH2 and ISH23 (ISH50) transpose into different sites. A 550 bp DNA insert ("ISH25") reverts the Bop mutation caused by ISH24. "ISH25" lacks typical structural features of a transposable element. "ISH25" and ISH24 are found adjacent to each other upstream of the bop gene. An identical arrangement of "ISH25" and ISH24 is found in the cccDNA of H. halobium NRC817. Comparative sequence analysis of both areas suggests that the translocation of "ISH25" to the bop gene region occurred by a recombination event.

Two-fold symmetry of crystalline DNA-EcoRI endonuclease recognition complexes.

Recognition complexes between EcoRI endonuclease and either of two synthetic oligonucleotides (sequences CGCGAATTCGCG and TCGCGAATTCGCG) crystallize in Space Group P321 with unit cell parameters a = 128 and c = 47 A and a = 118.4 and c = 49.7 A, respectively. Native diffraction data to 3 A resolution have been collected from the form containing the tridecameric sequence. Electrophoretic analyses of dissolved crystals demonstrate that this form contains DNA and protein in a ratio of one double helix per enzyme dimer. The most likely asymmetric unit contents are one 31,000 dalton enzyme subunit and one strand of DNA, yielding VM values of 3.1 A3/dal and 2.8 A3/dal for the forms containing dodecameric and tridecameric DNA, respectively. This implies that the DNA-protein complex possesses two-fold rotational symmetry, which has been incorporated in the crystalline lattice.