Mutants of Escherichia coli integration host factor: DNA-binding and recombination properties

Integration host factor (IHF) is a protein encoded by Escherichia coli, which was first discovered as a requirement for bacteriophage lambda site-specific recombination. In this study, we characterized mutants of IHF for their ability to bind to various IHF binding sites in vivo and to promote recombination of lambda in vitro. DNA-binding in vivo was monitored using the challenge-phage system. If IHF binds to its DNA-binding site that has been placed into the P(ant) region of bacteriophage P22, it acts as a repressor of the ant (antirepressor) gene, leading to the formation of lysogens of Salmonella typhimurium. If IHF cannot bind to its site, antirepressor is made leading to cell lysis. Challenge phages containing chimeras of different lambda IHF binding sites were constructed to test the contribution to the binding of a dA+dT-rich region, found in the sequence of the H' site but not in the H' site. In one case, the binding of mutant IHF proteins was enhanced by the presence of the dA+dT-rich region, indicating that IHF may be affected by neighboring bases and local DNA structure when it binds to its site. A subset of the mutant proteins retained the ability to form a looped attL complex in vivo, representing part of a higher-order protein-DNA complex (the 'intasome'). Additionally, this same subset of proteins also promoted the integration and excision of bacteriophage lambda in vitro. Thus, these mutant proteins not only retain their DNA-bending ability but make any protein-protein contacts necessary to form a recombination-proficient intasome.

Complementation of bacteriophage lambda integrase mutants: evidence for an intersubunit active site

Site-specific recombination of bacteriophage lambda starts with the formation of higher-order protein--DNA complexes, called 'intasomes', and is followed by a series of steps, including the initial DNA cleavage, top-strand exchange, branch migration and bottom-strand exchange, to produce recombinant products. One of the intasomes formed during excisive recombination (the attL complex) is composed of the phage-encoded integrase (Int), integration host factor (IHF) and one of the recombination substrates, attL DNA. Int is the catalytic recombinase and has two different DNA binding domains. When IHF is present, Int binds to two types of sites in attL DNA, the three arm-type sites (P'123) and the core-type sites (B and C') where the reciprocal strand exchange takes place. The Tyr342 residue of Int serves as a nucleophile during strand cleavage and covalently attaches to the DNA through a phosphotyrosyl bond. In vitro complementation assays have been performed for strand cleavage using attL suicide substrates and mutant proteins containing amino acid substitutions at residues conserved in the integrase family of recombinases. We demonstrate that at least two Int monomers are required to form the catalytically-competent species that performs cleavage at the B site. It is likely that the active site is formed by two Int monomers.

Characterization of the bacteriophage lambda excisionase (Xis) protein: the C-terminus is required for Xis-integrase cooperativity but not for DNA binding

We have performed a mutational analysis of the xis gene of bacteriophage lambda. The Xis protein is 72 amino acids in length and required for excisive recombination. Twenty-six mutants of Xis were isolated that were impaired or deficient in lambda excision. Mutant proteins that contained amino acid substitutions in the N-terminal 49 amino acids of Xis were defective in excisive recombination and were unable to bind DNA. In contrast, one mutant protein containing a leucine to proline substitution at position 60 and two truncated proteins containing either the N-terminal 53 or 64 amino acids continued to bind lambda DNA, interact cooperatively with FIS and promote excision. However, these three mutants were unable to bind DNA cooperatively with Int. Cooperativity between wild-type Xis and Int required the presence of FIS, but not the Int core-type binding sites. This study shows that Xis has at least two functional domains and also demonstrates the importance of the cooperativity in DNA binding of FIS, Xis and Int in lambda excision.

Transcription termination in vitro by bacteriophage T7 RNA polymerase. The role of sequence elements within and surrounding a rho-independent transcription terminator

rho-Independent transcription terminators in Escherichia coli contain a dG+dC-rich dyad-symmetrical structure that encodes an RNA hairpin structure and an adjacent, downstream dA+dT-rich region which encodes uridines at the 3'-end of the transcript. In the threonine (thr) attenuator, there are at least six sequence segments in the DNA that might affect termination: the sequence upstream of the attenuator, the deoxythymidine-rich stretch immediately preceding the G+C-rich region, the G+C-rich region itself and its hairpin loop-encoding region, the deoxyadenosine tract following the G+C-rich region, and the following downstream sequence. Our previous studies (Jeng, S.-T., Gardner, J.F., and Gumport, R.I. (1990) J. Biol. Chem. 265, 3823-3830) indicate that both the stability and sequence of the RNA hairpin formed by the G+C-rich region and the length of the uridine tract encoded by the deoxyadenosine stretch influence the termination of T7 RNA polymerase in vitro. In this report, we demonstrate that the template deoxythymidine run upstream of the G+C-rich region, the loop-encoding segment, and the sequences upstream and downstream of the thr attenuator also affect termination. These results indicate that: 1) a deoxythymidine tract is not absolutely required for termination, but increasing the number of deoxythymidines from one to nine base pairs causes T7 RNA polymerase to terminate more efficiently; 2) a template with the natural loop sequence reversed results in a higher termination efficiency than one encoded by the the wild-type attenuator; 3) the termination of T7 RNA polymerase is affected by sequences both proximal and distal to the thr attenuator.

Purification and characterization of the M.RsrI DNA methyltransferase from Escherichia coli

The gene (rsrIM) encoding the RsrI DNA methyltransferase (M.RsrI) from Rhodobacter sphaeroides was cloned and expressed in Escherichia coli. Under the control of a bacteriophage T7 promoter, 2% of the total protein in a crude extract was M.RsrI. This level of expression represents an approximately 50-fold increase over that present in the natural host. Chromatography using DNA cellulose and the S-adenosylmethionine analogue, sinefungin, was useful in purifying the enzyme to homogeneity. The purification yielded 100 times more enzyme than was obtained from the same quantity of R. sphaeroides cell paste. M.RsrI deposits one methyl group per productive DNA-binding event, as does its functional but sequence-nonhomologous analogue, M.EcoRI. Unlike M.EcoRI, the R. sphaeroides enzyme is a dimer at micromolar concentrations.

A new affinity reagent for the site-specific, covalent attachment of DNA to active-site nucleophiles: application to the EcoRI and RsrI restriction and modification enzymes

A modified oligodeoxyribonucleotide duplex containing an unnatural internucleotide trisubstituted 3' to 5' pyrophosphate bond in one strand [5'(oligo1)3'-P(OCH3)P-5'(oligo2) 3'] reacts with nucleophiles in aqueous media by acting as a phosphorylating affinity reagent. When interacted with a protein, a portion of the oligonucleotide [--P-5'(oligo2)3'] becomes attached to an amino acid nucleophilic group through a phosphate of the O-methyl-modified pyrophosphate linkage. We demonstrate the affinity labeling of nucleophilic groups at the active sites of the EcoRI and RsrI restriction and modification enzymes with an oligodeoxyribonucleotide duplex containing a modified scissile bond in the EcoRI recognition site. With the EcoRI and RsrI endonucleases in molar excess approximately 1% of the oligonucleotide becomes attached to the protein, and with the companion methyltransferases the yield approaches 40% for the EcoRI enzyme and 30% for the RsrI methyltransferase. Crosslinking proceeds only upon formation of a sequence-specific enzyme-DNA complex, and generates a covalent bond between the 3'-phosphate of the modified pyrophosphate in the substrate and a nucleophilic group at the active site of the enzyme. The reaction results in the elimination of an oligodeoxyribonucleotide remnant that contains the 3'-O-methylphosphate [5'(oligo1)3'-P(OCH3)] derived from the modified phosphate of the pyrophosphate linkage. Hydrolysis properties of the covalent protein-DNA adducts indicate that phosphoamide (P-N) bonds are formed with the EcoRI endonuclease and methyltransferase.

Influence of enzyme-substrate contacts located outside the EcoRI recognition site on cleavage of duplex oligodeoxyribonucleotide substrates by EcoRI endonuclease

A complete understanding of the sequence-specific interaction between the EcoRI restriction endonuclease and its DNA substrate requires identification of all contacts between the enzyme and substrate, and evaluation of their significance. We have searched for possible contacts adjacent to the recognition site, GAATTC, by using a series of substrates with differing lengths of flanking sequence. Each substrate is a duplex of non-self-complementary oligodeoxyribonucleotides in which the recognition site is flanked by six base pairs on one side and from zero to three base pairs on the other. Steady-state kinetic values were determined for the cleavage of each strand of these duplexes. A series of substrates in which the length of flanking sequence was varied on both sides of the hexamer was also examined. The enzyme cleaved both strands of each of the substrates. Decreasing the flanking sequence to fewer than three base pairs on one side of the recognition site induced an asymmetry in the rates of cleavage of the two strands. The scissile bond nearest the shortening sequence was hydrolyzed with increasing rapidity as base pairs were successively removed. Taken together, the KM and kcat values obtained may be interpreted to indicate the relative importance of several likely enzyme-substrate contacts located outside the canonical hexameric recognition site.

The isolation and characterization of mutants of the integration host factor (IHF) of Escherichia coli with altered, expanded DNA-binding specificities

The integration host factor (IHF) of Escherichia coli is a small, basic protein that is required for lambda site-specific recombination and a variety of cellular processes. It is composed of two subunits, alpha and beta, that are encoded by the himA and hip (himD) genes, respectively. IHF is a sequence-specific DNA-binding protein and bends the DNA when it binds. We have used the bacteriophage P22-based challenge phage selection to isolate suppressor mutants with altered, expanded DNA binding specificities. The suppressors were isolated by selecting mutants that recognize variants of the phage lambda H'IHF recognition site. Two of the mutants recognize both the wild-type and a single variant site and contain amino acid substitutions at positions 64 (Pro to Leu) or 65 (Lys to Ser) of the alpha subunit. These substitutions are in a region of the protein that is predicted to contain a flexible arm that interacts with DNA. Three other mutants, which recognize the wild-type and a different variant site, contain amino acid substitutions at position 44 (Glu to Lys, Val or Gly) of the beta subunit. These substitutions are in the middle of a predicted beta-strand of the subunit. We discuss the possible mechanisms of suppression by the mutants in terms of a model of the IHF-DNA complex proposed by Yang and Nash [Cell, 57, 869-880 (1989)].

The highly homologous isoschizomers RsrI endonuclease and EcoRI endonuclease do not recognize their target sequence identically

Using a series of decadeoxyribonucleotides containing base analogues as substrates we measured the steady-state kinetic parameters for the reaction catalyzed by RsrI endonuclease and compared the results to those with its isoschizomer EcoRI. The kinetics of RsrI cleavage are affected by each substitution, with the effects being generally more deleterious than with EcoRI, as shown by the greater reduction in the specificity constant kcat/KM. The magnitudes of the effects of several substitutions are consistent with the formation of direct enzyme-nucleobase contacts at the indicated positions. With substrates containing 2-amino-purine or 2,6-diaminopurine at the central adenine or uracil at the outermost thymine in the recognition sequence, cleavage by RsrI was very slow, less than one-tenth the rate of the corresponding EcoRI-catalyzed reaction. The lower tolerance of RsrI endonuclease for functional group changes in its recognition site may reflect differences in the mechanisms of DNA recognition by the two enzymes. Although RsrI and EcoRI endonucleases bind with similar affinities to specific and nonspecific DNA sequences and appear to introduce similar structural distortions in DNA upon binding, the use of substrate analogues reveals significant differences at the level of catalysis in the mechanisms by which these two endonucleases recognize the duplex sequence GAATTC.

The specific binding, bending, and unwinding of DNA by RsrI endonuclease, an isoschizomer of EcoRI endonuclease

To determine whether RsrI endonuclease recognizes and cleaves the sequence GAATTC in duplex DNA similarly to its isoschizomer EcoRI we initiated a functional comparison of the two enzymes. Equilibrium binding experiments showed that at 20 degrees C RsrI endonuclease binds to specific and nonspecific sequences in DNA with affinities similar to those of EcoRI. At 0 degrees C the affinity of RsrI for its specific recognition sequence is reduced 7-fold whereas the affinity for noncanonical sequences remains relatively unchanged. Unlike EcoRI, incubation of RsrI endonuclease with N-ethylmaleimide inactivates the enzyme; however, preincubation with DNA prevents the inactivation. The N-ethylmaleimide-treated enzyme fails to bind DNA as assayed by gel mobility shift assays. Comparison of the deduced amino acid sequences of RsrI and EcoRI endonucleases suggests that modification of Cys245 is responsible for the inactivation. Fe(II). EDTA and methidiumpropyl-EDTA.Fe(II) footprinting results indicate that RsrI, like EcoRI, protects 12 base pairs from cleavage when bound to its specific recognition sequence in the absence of Mg2+. RsrI bends DNA by approximately 50 degrees, as determined by measuring the relative electrophoretic mobilities of specific RsrI-DNA complexes with the binding site in the center or near the end of the DNA fragment. This value is similar to that reported for EcoRI. RsrI also unwinds the DNA helix by 25 degrees +/- 5 degrees, a value close to that reported for EcoRI endonuclease. Collectively, these results indicate that the overall structural changes induced in the DNA by the binding of RsrI and EcoRI endonucleases to DNA in the absence of Mg2+ are similar. In the accompanying paper (Aiken, C. R., McLaughlin, L. W., and Gumport, R. I. (1991) J. Biol. Chem. 266, 19070-19078) we present results of studies of RsrI endonuclease using oligonucleotide substrates containing base analogues which suggest differences in the ways the two enzymes cleave DNA.

A genetic analysis of Xis and FIS interactions with their binding sites in bacteriophage lambda

The bacteriophage P22-based challenge-phage system was used to study the binding of Xis and FIS to their sites in attP of bacteriophage lambda. Challenge phages were constructed that contained the X1, X2, and F sites within the P22 Pant promoter, which is required for expression of antirepressor. If Xis and FIS bind to these sites in vivo, they repress transcription from Pant, allowing lysogenization to occur. Challenge phages carrying the XIX2F region in either orientation exhibited lysogenization dependent on both Xis and FIS. Neither Xis nor FIS was capable of functioning by itself as an efficient repressor in this system. This was the first time challenge phages have been constructed that require two different proteins bound simultaneously to act as a repressor. Mutations in the X1, X2, and F sites that inhibit Xis and FIS from binding were isolated by selecting mutant phages that still expressed antirepressor synthesis in the presence of Xis and FIS. DNA sequence analysis of the mutants revealed 38 unique mutations, including single-base-pair substitutions, multiple-base-pair changes, deletions, and insertions throughout the entire X1, X2, and F regions. Some of the mutations verified the importance of certain bases within the proposed consensus sequences for Xis and FIS, while others provided evidence that the DNA sequence outside of the proposed binding sites may affect the binding of the individual proteins or the cooperativity between them.

Ligation with T4 RNA ligase of an oligodeoxyribonucleotide to covalently-linked cross-sectional base-pair analogues of short, normal, and long dimensions

Compounds that are covalent analogues of nucleic acid base pairs of normal, long, and short C1' to C1' dimensions [B. Devadas and N.J. Leonard (1990) J. Am. Chem. Soc., 112, 3125-3135.] have been added to the oligodeoxyribonucleotide d(A)6 with bacteriophage T4 RNA ligase as a prelude to placing them at defined loci within nucleic acid duplexes. Analogue cross sections that represent a normal Watson-Crick base pair as well as a pyrimidine-pyrimidine and a purine-purine apposition were ligated in modest yields (approximately 20%) to the oligonucleotide. Ligation conditions were optimized for each analogue, and the cross section was joined to only a single oligonucleotide in each case. The structures of the ligated products were proved by HPLC, enzymatic degradation, and spectroscopic analyses.

Genetic analysis of Escherichia coli integration host factor interactions with its bacteriophage lambda H' recognition site

The bacteriophage P22-based challenge phage system was used to study the binding of integration host factor (IHF) to its H' recognition site in the attP region of bacteriophage lambda. We constructed challenge phages that carried H' inserts in both orientations within the P22 Pant promoter, which is required for antirepressor synthesis. We found that IHF repressed expression of Pant from either challenge phage when expressed from an inducible Ptac promoter on a plasmid vector. Mutants containing changes in the H' inserts that decrease or eliminate IHF binding were isolated by selecting challenge phages that could synthesize antirepressor in the presence of IHF. Sequence analysis of 31 mutants showed that most changes were base pair substitutions within the H' insert. Approximately one-half of the mutants contained substitutions that changed base pairs that are part of the IHF consensus binding site; mutants were isolated that contained substitutions at six of the nine base pairs of the consensus site. Other mutants contained changes at base pairs between the two subdeterminants of the H' site, at positions that are not specified in the consensus sequence, and in the dA + dT-rich region that flanks the consensus region of the site. Taken together, these results show that single-base-pair changes at positions outside of the proposed consensus bases can weaken or drastically disrupt IHF binding to the mutated site.

A comparison of the effects of single-base and triple-base changes in the integrase arm-type binding sites on the site-specific recombination of bacteriophage lambda

Triple-base changes were made in each of the five Integrase (Int) arm-type binding sites of bacteriophage lambda. These triple changes, called ten mutants, were compared with single-base changes (hen mutants) for their effects on integrative and excisive recombination. The presence of ten or hen mutations in the P1, P'2, or P'3 sites inhibited integration, but the ten P'3 mutant was 10-fold more defective than the analogous hen mutant. The results with these mutants suggest that the P1, P'2, P'3, and possibly the P'1 sites are required for integration. In wild-type E. coli, the ten P'1 mutant reduced the frequency of excision 5-fold, whereas the hen P'1 mutant had no effect. The presence of ten mutations in the P2, P'1, or P'2 sites inhibited lambda excision in an E. coli strain deficient in the production of FIS, while hen mutations in the P2 and P'2 sites had little or no effect. The results with the ten mutants suggest that the P2, P'1, and P'2 sites are required for excision. The differences in the severity of the effects between the ten and hen mutations may be due to the inability of cooperative interactions among Int, IHF, Xis, and FIS to overcome the disruption of Int binding to sites with triple-base changes compared to sites with single-base changes.

Transcription termination by bacteriophage T7 RNA polymerase at rho-independent terminators

We have investigated the mechanism of transcription termination by T7 RNA polymerase using templates encoding variants of the transcription-termination structure (attenuator) of the regulatory region of the threonine (thr) operon of Escherichia coli. The thr attenuator comprises the following two distinct structural elements: a G + C-rich inverted repeat, which encodes an RNA hairpin structure, and A + T-rich regions, one of which contains a continuous sequence of template deoxyadenosine residues within which the transcription terminates. Fourteen attenuator variants were analyzed and we find that not only the hairpin structure itself but also its sequence influences termination. Furthermore, the formation of a hairpin in the RNA encoded by the A + T-rich regions of the attenuator is not mandatory for termination. A series of seven deletion variants that successively shorten the deoxyadenosine tract in the attenuator template were also analyzed. Results from these experiments indicate that complete readthrough occurs when there are four or fewer deoxyadenosine residues. With 5 template deoxyadenosine residues there is 5% termination increasing to 32% with 8 deoxyadenosines, the value produced by the wild-type attenuator. In addition, a comparison with E. coli RNA polymerase shows that T7 RNA polymerase requires a more perfect region of dyad symmetry and a longer deoxyadenosine tract than does the bacterial enzyme to terminate with maximum efficiency.

Genetic analysis of bacteriophage lambda integrase interactions with arm-type attachment site sequences

The bacteriophage P22-based challenge phage system was used to study lambda integrase (Int) protein binding to its arm-type recognition sequences in the bacteriophage lambda attachment site. Challenge phages were constructed that carried inserts containing either the contiguous P'123 arm-type sites or the single P'1 site within the P22 phage promoter, Pant, which is required for expression of antirepressor. If Int protein binds to these sequences in vivo, it represses transcription from Pant. We found that Int repressed Pant in phages carrying the P'123 sites more efficiently than those carrying only the P'1 site, suggesting that the protein binds cooperatively at the three adjacent sites. The Int protein from a related lambdoid phage, HK022, also repressed transcription by binding to the same arm-type sites. Mutations in the P'123 or P'1 sites that impair Int binding were isolated by selecting mutant phages that express antirepressor in the presence of Int. DNA sequence analyses showed that most of the mutants in the challenge phages carrying the P'123 sites contained multiple changes and that two mutants contained only single-base-pair changes at positions that are completely conserved among all arm-type sites. Thirty-five mutants were isolated and analyzed from phages containing only the P'1 site. Most mutants contained single-nucleotide changes, and mutations were isolated at 8 of the 10 positions of the site, suggesting that most if not all base pairs in the conserved recognition sequence are involved in Int binding.

Purification, cloning and sequence analysis of RsrI DNA methyltransferase: lack of homology between two enzymes, RsrI and EcoRI, that methylate the same nucleotide in identical recognition sequences

RsrI DNA methyltransferase (M-RsrI) from Rhodobacter sphaeroides has been purified to homogeneity, and its gene cloned and sequenced. This enzyme catalyzes methylation of the same central adenine residue in the duplex recognition sequence d(GAATTC) as does M-EcoRI. The reduced and denatured molecular weight of the RsrI methyltransferase (MTase) is 33,600 Da. A fragment of R. sphaeroides chromosomal DNA exhibited M.RsrI activity in E. coli and was used to sequence the rsrIM gene. The deduced amino acid sequence of M.RsrI shows partial homology to those of the type II adenine MTases HinfI and DpnA and N4-cytosine MTases BamHI and PvuII, and to the type III adenine MTases EcoP1 and EcoP15. In contrast to their corresponding isoschizomeric endonucleases, the deduced amino acid sequences of the RsrI and EcoRI MTases show very little homology. Either the EcoRI and RsrI restriction-modification systems assembled independently from closely related endonuclease and more distantly related MTase genes, or the MTase genes diverged more than their partner endonuclease genes. The rsrIM gene sequence has also been determined by Stephenson and Greene (Nucl. Acids Res. (1989) 17, this issue).

Transcriptional analysis of puf operon expression in Rhodobacter sphaeroides 2.4.1 and an intercistronic transcription terminator mutant

DNA sequence analysis of the pufX region, the most distal gene of the pufBALMX operon of Rhodobacter sphaeroides, revealed a sequence encoding a putative polypeptide of 82 amino acids with a molecular mass of 9052 Da followed by a puf operon-specific transcription terminator. Analysis of the 5' and 3' termini of the transcripts produced in vivo from the puf operon of R. sphaeroides PUF delta 348-420 (three transcripts; 0.59, 0.64, and 2.63 kilobases) lacking the puf-intercistronic terminator structure were identical to those of the corresponding puf transcripts derived from wild-type R. sphaeroides 2.4.1 (four transcripts; 0.50, 0.66, 0.71, and 2.7 kilobases) showing that the transcripts begin and end at the same sites. However, the absence of the puf intercistronic terminator resulted in both the loss of the smallest transcript found in wild type and increased transcriptional read-through of the mutated region to the more distal pufL gene, supporting our previous contention that the proximal intercistronic stem-loop functions as a transcription terminator. The 5' terminus of the medium sized puf transcript has been localized to the same site as that of the small puf transcript. These analyses also showed conclusively that the puf operon-specific transcripts are not extended transcripts derived from the upstream open reading frame Q. In addition, a 120-nucleotide RNA was detected which encompassed the terminator region downstream of pufX and extended into the next downstream open reading frame. The 120-nucleotide RNA of unknown function was regulated by O2 and is unique in its abundance and stability. By comparison with strain 2.4.1, the mutant PUF delta 348-420 showed an increased amount (1.9-fold) of the 120-nucleotide RNA, suggesting that its synthesis is under the control of the puf operon despite the fact that its sequence appears to overlap the next downstream operon.

The effect of attachment site mutations on strand exchange in bacteriophage lambda site-specific recombination

Recombination of phage lambda attachment sites occurs by sequential exchange of the DNA strands at two specific locations. The first exchange produces a Holliday structure, and the second resolves it to recombinant products. Heterology for base substitution mutations in the region between the two strand exchange points (the overlap region) reduces recombination; some mutations inhibit the accumulation of Holliday structures, others inhibit their resolution to recombinant products. To see if heterology also alters the location of the strand exchange points, we determined the segregation pattern of three single and one multiple base pair substitution mutations of the overlap region in crosses with wild type sites. The mutations are known to differ in the severity of their recombination defect and in the stage of strand exchange they affect. The three single mutations behaved similarly: each segregated into both products of recombination, and the two products of a single crossover were frequently nonreciprocal in the overlap region. In contrast, the multiple mutation preferentially segregated into one of the two recombinant products, and the two products of a single crossover appeared to be fully reciprocal. The simplest explanation of the segregation pattern of the single mutations is that strand exchanges occur at the normal locations to produce recombinants with mismatched base pairs that are frequently repaired. The segregation pattern of the multiple mutation is consistent with the view that both strand exchanges usually occur to one side of the mutant site. We suggest that the segregation pattern of a particular mutation is determined by which stage of strand exchange it inhibits and by the severity of the inhibition.

In vivo analysis of puf operon expression in Rhodobacter sphaeroides after deletion of a putative intercistronic transcription terminator

The intercistronic region of the mRNA derived from the puf operon of Rhodobacter sphaeroides is capable of forming two stable stem-loop structures, the first of which resembles a factor-independent transcription terminator. A puf operon construction lacking the putative transcription terminator was made in vitro and crossed into the chromosome of R. sphaeroides PUFB1 to yield a single chromosomal copy in the terminator-deleted strain. The mutant strain, designated PUF delta 348-420 which was otherwise isogenic with the wild-type strain 2.4.1, showed a normal growth rate at high light intensity compared with the wild type, with the levels of the B875 and reaction center spectral complexes being approximately 7% and 25%, respectively, of those found in the wild type. The deletion mutation correlated with a reduction in the size of the fixed photosynthetic unit from 15:1 in the wild type to 4:1 in the mutant. The level of the B800-850 complex was increased approximately twofold in the mutant strain. However, substantial amounts of the B875 and reaction center polypeptides were not incorporated into spectrally active complexes, suggesting the importance of other factors in the assembly of these complexes. Removal of the intercistronic stem-loops resulted in increased readthrough of the puf operon terminator to regions downstream, as well as altering the stability of the resulting puf operon-specific transcripts. A model is proposed which links ribosome stalling within the open reading frame K leader region of the puf operon transcript with chain termination.

Restriction endonuclease RsrI from Rhodobacter sphaeroides, an isoschizomer of EcoRI: purification and properties

We have purified RsrI endonuclease (R.RsrI), an isoschizomer of EcoRI, from Rhodobacter sphaeroides strain 630. The enzyme is homogeneous as judged by polyacrylamide gel electrophoresis and size-exclusion high-performance liquid chromatography. RsrI endonuclease is a dimer over the concentration range of 0.05 to 1.4 mg/ml. The reduced and denatured molecular weight of the enzyme is 30,000 Da. R.RsrI, like R.EcoRI, catalyzes the cleavage of duplex DNA and oligodeoxyribonucleotides between the first two residues of the sequence GAATTC. R.RsrI exhibits a KM of 14 nM and a kcat of 6.5 min-1 when reacting with pBR322 DNA at 25 degrees C. R.RsrI differs from R.EcoRI in its N-terminal amino acid sequence, susceptibility to inhibition by antibodies, sensitivity to N-ethylmaleimide, isoelectric point, state of aggregation at high concentrations, temperature lability, and conditions for optimal reaction. R.RsrI displays a reduction of specificity ("star activity") under conditions that also relax the specificity of R.EcoRI.