Defining cosQ, the site required for termination of bacteriophage lambda DNA packaging

Bacteriophage lambda is a double-stranded DNA virus that processes concatemeric DNA into virion chromosomes by cutting at specific recognition sites termed cos. A cos is composed of three subsites: cosN, the nicking site; cosB, required for packaging initiation; and cosQ, required for termination of chromosome packaging. During packaging termination, nicking of the bottom strand of cosN depends on cosQ, suggesting that cosQ is needed to deliver terminase to the bottom strand of cosN to carry out nicking. In the present work, saturation mutagenesis showed that a 7-bp segment comprises cosQ. A proposal that cosQ function requires an optimal sequence match between cosQ and cosNR, the right cosN half-site, was tested by constructing double cosQ mutants; the behavior of the double mutants was inconsistent with the proposal. Substitutions in the 17-bp region between cosQ and cosN resulted in no major defects in chromosome packaging. Insertional mutagenesis indicated that proper spacing between cosQ and cosN is required. The lethality of integral helical insertions eliminated a model in which DNA looping enables cosQ to deliver a gpA protomer for nicking at cosN. The 7 bp of cosQ coincide exactly with the recognition sequence for the Escherichia coli restriction endonuclease, EcoO109I.     

Alterations of the portal protein,gpB, of bacteriophage lambda suppress mutations in cosQ,the site required for termination of DNA packaging

The cosQ site of bacteriophage lambda is required for DNA packaging termination. Previous studies have shown that cosQ mutations can be suppressed in three ways: by a local suppressor within cosQ, an increase in the length of the lambda chromosome, and missense mutations affecting the prohead's portal protein, gpB. In the present work, revertants of a set of lethal cosQ mutants were screened for suppressors. Seven new cosQ suppressors affected gene B, which encodes the portal protein of the prohead. All seven were allele-nonspecific suppressors of cosQ mutations. Experiments with several phages having two cosQ suppressors showed that the suppression effects were additive. Furthermore, these double suppressors had minimal effects on the growth of cosQ(+) phages. These trans-acting suppressors affecting the portal protein are proposed to allow the mutant cosQ site to be more efficiently recognized, due to the slowing of the rate of translocation.     

Genetic Evidence That Recognition of Cosq, the Signal for Termination of Phage λ DNA Packaging, Depends on the Extent of Head Filling

Packaging a phage λ chromosome involves cutting the chromosome from a concatemer and translocating the DNA into a prohead. The cutting site, cos, consists of three subsites: cosN, the nicking site; cosB, a site required for packaging initiation; and cosQ, a site required for termination of packaging. cosB contains three binding sites (R sequences) for gpNu1, the small subunit of terminase. Because cosQ has sequence identity to the R sequences, it has been proposed that cosQ is also recognized by gpNu1. Suppressors of cosB mutations were unable to suppress a cosQ point mutation. Suppressors of a cosQ mutation (cosQ1) were isolated and found to be of three sorts, the first affecting a base pair in cosQ. The second type of cosQ suppression involved increasing the length of the phage chromosome to a length near to the maximum capacity of the head shell. A third class of suppressors were missense mutations in gene B, which encodes the portal protein of the virion. It is speculated that increasing DNA length and altering the portal protein may reduce the rate of translocation, thereby increasing the efficiency of recognition of the mutant cosQ. None of the cosQ suppressors was able to suppress cosB mutations. Because cosQ and cosB mutations are suppressed by very different types of suppressors, it is concluded that cosQ and the R sequences of cosB are recognized by different DNA-binding determinants.     

Bacteriophage lambda DNA packaging: DNA site requirements for termination and processivity

Bacteriophage lambda chromosomes are processively packaged into preformed shells, using end-to-end multimers of intracellular viral DNA as the packaging substate. A 200 bp long DNA segment, cos, contains all the sequences needed for DNA packaging. The work reported here shows that efficient DNA packaging termination requires cos's I2 segment, in addition to the required termination subsite, cosQ, and the nicking site, cosN. Efficient processivity requires cosB, in addition to cosQ and cosN. An initiation-defective mutant form of cosB sponsored efficient processivity, indicating that the terminase-cosB interactions required for termination are less stringent than those required at initiation. The finding that an initiation-defective form of cosB is functional for processivity allows a re-interpretation of a similar finding, obtained previously, that the initiation-defective cosB of phage 21 is functional for processivity by the lambda packaging machinery. The cosBphi21 result can now be interpreted as indicating that interactions between cosBphi21 and lambda terminase, while insufficient for initiation, function for processivity.     

Evidence of Horizontal Transfer of the EcoO109I Restriction-Modification Gene to Escherichia coli Chromosomal DNA

A DNA fragment carrying the genes coding for EcoO109I endonuclease and EcoO109I methylase, which recognize the nucleotide sequence 5'-(A/G)GGNCC(C/T)-3', was cloned from the chromosomal DNA of Escherichia coli H709c. The EcoO109I restriction-modification (R-M) system was found to be inserted between the int and psu genes from satellite bacteriophage P4, which were lysogenized in the chromosome at the P4 phage attachment site of the corresponding leuX gene observed in E. coli K-12 chromosomal DNA. The sid gene of the prophage was inactivated by insertion of one copy of IS21. These findings may shed light on the horizontal transfer and stable maintenance of the R-M system.     

The Nul subunit of bacteriophage lambda terminase binds to specific sites in cos DNA.

The maturation and packaging of bacteriophage lambda DNA are under the control of the multifunctional viral terminase enzyme, which is composed of the protein products of Nu1 and A, the two most leftward genes of the phage chromosome. Terminase binds selectively to the cohesive end site (cos) of multimeric replicating lambda DNA and introduces staggered nicks to regenerate the 12-base single-stranded cohesive ends of the mature phage genome. The purified gpNu1 subunit of terminase forms specific complexes with cos lambda DNA. DNase I footprinting experiments showed that gpNu1 bound to three distinct regions near the extreme left end of the lambda chromosome. These regions coincided with two 16-base-pair sequences (CTGTCGTTTCCTTTCT) that were in inverted orientation, as well as a truncated version of this sequence. Bear et al. (J. Virol. 52:966-972,1984) isolated a mutant phage which contained a CG to TA transition at the 10th position of the rightmost 16-base-pair sequence, and this phage (termed lambda cos 154) exhibits a defect in DNA maturation when it replicates in Escherichia coli which is deficient in integration host factor. Footprinting experiments with cos 154 DNA showed that gpNu1 could not bind to the site which contained the mutation but could protect the other two sites. Since the DNA-packaging specificity of terminase resides in the gpNu1 subunit, these studies suggest that terminase uses these three sites as recognition sequences for specific binding to cos lambda.     

Characterization and overproduction of EcoO109I methyltransferase.

In order to characterize EcoO109I methyltransferase, a recombinant Escherichia coli clone that overproduces the enzyme was constructed. The coding region of M.EcoO109I was joined to the lac promoter of an expression vector, pUC118, and the resulting plasmid was introduced into E. coli HB101. M.EcoO109I was purified homogeneously from IPTG-induced cells, and was found to consist of a monomer subunit. M.EcoO109I uniquely methylates the inner deoxycytidylate residue in the sequence 5'-(A/G)GGNCC(C/T)-3' to produce 5-methylcytosine. The enzyme was most active at pH 8.0-8.5 and 50 degrees C. The enzyme activity was not affected by the addition of Mg2+ or EDTA.     

The interaction of Escherichia coli integration host factor with the cohesive end sites of phages lambda and 21

The interaction of E. coli integration host factor (IHF) with the cohesive end sites (cos's) of phages lambda and 21 has been studied by the DNAase I footprinting technique. Six potential sites in cos lambda differ from the consensus IHF binding sequence by 1 to 3 base pairs. Of the six, one site, I1, binds IHF strongly. The I1 segment protected by IHF contains two sequences that closely match the IHF consensus binding sequence. Another site, I2, binds IHF moderately well, and three sites: 10', 13 and 14 bind IHF very weakly. The 10 site does not bind IHF under the conditions used here. In phage 21 the DNA segment extending to the right from the cohesive ends, which contains three potential IHF binding sites, was examined. Two sites bind IHF well; I1, the 21 analogue of one of the lambda I1 sites, and I0, a site not analogous to a lambda site. The third 21 site, I2, binds IHF moderately well, as does the analogous I2 site in lambda. The significance of the results for lambda DNA packaging is discussed.     

Bacteriophage lambda gpNu1 and Escherichia coli IHF proteins cooperatively bind and bend viral DNA: implications for the assembly of a genome-packaging motor

Terminase enzymes are common to both prokaryotic and eukaryotic double-stranded DNA viruses and are responsible for packaging viral DNA into the confines of an empty procapsid shell. In all known cases, the holoenzymes are heteroligomers composed of a large subunit that possesses the catalytic activities required for genome packaging and a small subunit that is responsible for specific recognition of viral DNA. In bacteriophage lambda, the DNA recognition protein is gpNu1. The gpNu1 subunit interacts with multiple recognition elements within cos, the packaging initiation site in viral DNA, to site-specifically assemble the packaging machinery. Motor assembly is modulated by the Escherichia coli integration host factor protein (IHF), which binds to a consensus sequence also located within cos. On the basis of a variety of biochemical data and the recently solved NMR structure of the DNA binding domain of gpNu1, we proposed a novel DNA binding mode that predicts significant bending of duplex DNA by gpNu1 (de Beer et al. (2002) Mol. Cell 9, 981-991). We further proposed that gpNu1 and IHF cooperatively bind and bend viral DNA to regulate the assembly of the packaging motor. Here, we characterize cooperative gpNu1 and IHF binding to the cos site in lambda DNA using a quantitative electrophoretic mobility shift (EMS) assay. These studies provide direct experimental support for the long presumed cooperative assembly of gpNu1 and IHF at the cos sequence of lambda DNA. Further, circular permutation experiments demonstrate that the viral and host proteins each introduce a strong bend in cos-containing DNA, but not nonspecific DNA substrates. Thus, specific recognition of viral DNA by the packaging apparatus is mediated by both DNA sequence information and by structural alteration of the duplex. The relevance of these results with respect to the assembly of a viral DNA-packaging motor is discussed.     

tau Exon 10 expression involves a bipartite intron 10 regulatory sequence and weak 5' and 3' splice sites

tau mutations that deregulate alternative exon 10 (E10) splicing cause frontotemporal dementia with parkinsonism chromosome 17-type by several mechanisms. Previously we showed that E10 splicing involved exon splicing enhancer sequences at the 5' and 3' ends of E10, an exon splicing silencer, a weak 5' splice site, and an intron splicing silencer (ISS) within intron 10 (I10). Here, we identify additional regulatory sequences in I10 using both non-neuronal and neuronal cells. The ISS sequence extends from I10 nucleotides 11-18, which is sufficient to inhibit use of a weakened 5' splice site of a heterologous exon. Furthermore, ISS function is location-independent but requires proximity to a weak 5' splice site. Thus, the ISS functions as a linear sequence. A new cis-acting element, the intron splicing modulator (ISM), was identified immediately downstream of the ISS at I10 positions 19-26. The ISM and ISS form a bipartite regulatory element, within which the ISM functions when the ISS is present, mitigating E10 repression by the ISS. Additionally, the 3' splice site of E10 is weak and requires exon splicing enhancer elements for efficient E10 inclusion. Thus far, tau FTDP-17 splicing mutations affect six predicted cis-regulatory sequences.     

A base-paired structure in the avian sarcoma virus 5' leader is required for efficient encapsidation of RNA.

Selective encapsidation of avian sarcoma-leukosis virus genomic RNA within virions requires recognition of a cis-acting signal (termed psi) located in the 5' leader of the RNA between the primer binding site and the splice donor site. Computer analyses indicate the potential for numerous secondary structure interactions within this region, including alternative conformations with similar free energy levels. We have constructed mutations designed to disrupt and restore potential secondary structure interactions within psi to investigate the role of these structures in RNA packaging. To test for the ability of psi mutants to package a heterologous reporter gene into virions, chimeric constructs bearing avian sarcoma virus 5' sequences fused to lacZ were transiently cotransfected with a nonpackageable helper construct into chicken embryo fibroblasts. lacZ virions produced from cotransfected cells were used to infect new cultures of chicken embryo fibroblasts, and then an in situ assay for individual cells expressing lacZ was done. Results obtained with this assay were confirmed in direct analyses of isolated virion RNA by RNase protection assays. Two mutations, predicted to disrupt a potential stem structure forming between elements located at nucleotides 160 to 167 and 227 to 234, severely inhibited packaging when either element was mutated. A construct in which these mutations were combined to restore potential base pairing between the two elements displayed a partially restored packaging phenotype. These results strongly suggest that the structure, referred to as the O3 stem, is required for efficient encapsidation of avian sarcoma virus RNA. Site-directed mutagenesis of additional sequence elements located in the O3 loop reduced packaging as measured by the indirect assay, suggesting that these sequences may also be components of the encapsidation signal. The possible implications of the O3 stem structure with regard to translation of avian sarcoma-leukosis virus short upstream open reading frames are discussed.     

Frameshift suppressor mutations outside the anticodon in yeast proline tRNAs containing an intervening sequence.

Extragenic suppressors of +1 frameshift mutations in proline codons map in genes encoding two major proline tRNA isoacceptors. We have shown previously that one isoacceptor encoded by the SUF2 gene (chromosome 3) contains no intervening sequence. SUF2 suppressor mutations result from the base insertion of a G within a 3'-GGA-5' anticodon, allowing the tRNA to read a 4-base code word. In this communication we describe suppressor mutations in genes encoding a second proline tRNA isoacceptor (wild-type anticodon 3'-GGU-5') that result in a novel mechanism for translation of a 4-base genetic code word. The genes that encode this isoacceptor include SUF7 (chromosome 13), SUF8 (chromosome 8), trn1 (chromosome 1), and at least two additional unmapped genes, all of which contain an intervening sequence. We show that suppressor mutations in the SUF7 and SUF8 genes result in G-to-U base substitutions at position 39 that disrupted the normal G . C base pairing in the last base pair of the anticodon stem adjacent to the anticodon loop. These anticodon stem mutations might alter the size of the anticodon loop and permit the use of a 3'-GGGU-5' sequence within the loop to read 4-base proline codons. Uncertainty regarding the exact structure of the mature suppressor tRNAs results from the possibility that anticodon stem mutations might affect sites of intervening sequence removal. The possible role of the intervening sequence in the generation of mature suppressor tRNA is discussed. Besides an analysis of suppressor tRNA genes, we have extended previous observations of the apparent relationship between tRNA genes and repetitive delta sequences found as solo elements or in association with the transposable element TY1. Hybridization studies and a computer analysis of the DNA sequence surrounding the SUF7 gene revealed two incomplete, inverted delta sequences that form a stem and loop structure located 165 base pairs from the 5' end of the tRNA gene. In addition, sequences beginning 164 base pairs from the 5' end of the trn1 gene also exhibit partial homology to delta. These observations provide further evidence for a nonrandom association between tRNA genes and delta sequences.     

The interaction of E. coli integration host factor and lambda cos DNA: multiple complex formation and protein-induced bending.

The interaction of E. coli's integration Host Factor (IHF) with fragments of lambda DNA containing the cos site has been studied by gel-mobility retardation and electron microscopy. The cos fragment used in the mobility assays is 398 bp and spans a region from 48,298 to 194 on the lambda chromosome. Several different complexes of IHF with this fragment can be distinguished by their differential mobility on polyacrylamide gels. Relative band intensities indicate that the formation of a complex between IHF and this DNA fragment has an equilibrium binding constant of the same magnitude as DNA fragments containing lambda's attP site. Gel-mobility retardation and electron microscopy have been employed to show that IHF sharply bends DNA near cos and to map the bending site. The protein-induced bend is near an intrinsic bend due to DNA sequence. The position of the bend suggests that IHF's role in lambda DNA packaging may be the enhancement of terminase binding/cos cutting by manipulating DNA structure.     

Crystal structures of type II restriction endonuclease EcoO109I and its complex with cognate DNA

EcoO109I is a type II restriction endonuclease that recognizes the DNA sequence of RGGNCCY. Here we describe the crystal structures of EcoO109I and its complex with DNA. A comparison of the two structures shows that the catalytic domain moves drastically to capture the DNA. One metal ion and two water molecules are observed near the active site of the DNA complex. The metal ion is a Lewis acid that stabilizes the pentavalent phosphorus atom in the transition state. One water molecule, activated by Lys-126, attacks the phosphorus atom in an S(N)2 mechanism, whereas the other water interacts with the 3'-leaving oxygen to donate a proton to the oxygen. EcoO109I is similar to EcoRI family enzymes in terms of its DNA cleavage pattern and folding topology of the common motif in the catalytic domain, but it differs in the manner of DNA recognition. Our findings propose a novel classification of the type II restriction endonucleases and lead to the suggestion that EcoO109I represents a new subclass of the EcoRI family.     

Processive action of terminase during sequential packaging of bacteriophage lambda chromosomes

Bacteriophage lambda chromosomes are packaged in a polarized, sequential fashion from a multimeric DNA substrate. Mature chromosomes are generated when terminase introduces staggered nicks in the cohesive end sites (cos sites) bounding a chromosome. Packaging is polarized, to the initial and terminal cos sites for packaging a chromosome can be defined. To initiate packaging, terminase binds to cos at cosB, and subsequently cuts at cosN. To terminate packaging of a chromosome, a functional cosB is not required at the terminal cos. To explain this finding, it was proposed earlier that terminase scans for the terminal cosN, rather than any subsequent cosB, during packaging. In the work described here we performed helper packaging experiments to see whether processive action of terminase occurs during sequential packaging of lambda chromosomes. The helper packaging experiments involve trilysogens; strains carrying three prophages in tandem. Infection by a hetero-immune helper phage results in packaging of the repressed prophage chromosomes, since the prophage structure is analogous to the normal DNA substrate. Two chromosomes can be packaged from between the three cos sites of the prophages of a trilysogen. Both chromosomes are packaged even when the central cos is cosB-. Our interpretation of these data is that terminase is brought to the central cos by packaging; following cleavage of the central cos, the terminase remains bound to the distal chromosome; and terminase acts to begin packaging of the distal chromosome. The frequency at which terminase reads across the central cos to initiate packaging of the distal chromosome is in the range from 0.3 to 0.5 in our experiments. Reading across cos was found not to be greatly dependent on the state of cosB, indicating that cosB binding is only needed for packaging the first chromosome in a packaging series. A multilysogen was constructed in which the initial cos was cos+ and the distal cos sites were all cosB-. The initial and downstream chromosomes were found to be packaged. This result indicates that terminase that is brought to the central cos by packaging is not only able to initiate packaging of a downstream chromosome, but can also scan and terminate packaging of the downstream chromosome. A model is presented in which processive action of terminase is the basis for sequential packaging of lambda chromosomes.     

Identification of sequences necessary for packaging DNA into lambda phage heads

Several species of DNA molecules are packaged into lambda phage heads if they carry the region around the cohesive end site of lambda phage (cos lambda). The minimal functional sequence around cos lambda needed for packaging was examined by cloning in pBR322. The results showed that the minimal region contained 85 bp around cos lambda; 45 bp of the left arm of lambda phage and 40 bp of the right arm. A 75-bp region located to the right of the minimal region seems to enhance packaging. A 223-bp fragment containing these regions can be used as a portable element for plasmid DNA packaging into lambda phage heads. Plasmid ppBest 322, a derivative of pBR322 carrying this portable packager and both amp and tet genes, was constructed. This plasmid is useful for cloning of large DNA fragments.     

Genetic analysis of cosB, the binding site for terminase, the DNA packaging enzyme of bacteriophage lambda.

cosB, the binding site for terminase, the DNA packaging enzyme of bacteriophage lambda, consists of three binding sites (called R3, R2 and R1) for gpNu1, the small subunit of terminase; and I1, a binding site for integration host factor (IHF), the DNA bending protein of Escherichia coli. cosB is located between cosN, the site where terminase introduces staggered nicks to generate cohesive ends, and the Nu1 gene; the order of sites is: cosN-R3-I1-R2-R1-Nu1. A series of lambda mutants have been constructed that have single base-pair C-to-T transition mutations in R3, R2 and R1. A single base-pair transition mutation within any one of the gpNul binding sites renders lambda dependent upon IHF for plaque formation. lambda phage with mutations in both R2 and R3 are incapable of plaque formation even in the presence of IHF. Phages that carry DNA insertions between R1 and R2, from 7 to 20 base-pairs long, are also IHF-dependent, demonstrating the requirement for a precise spacing of gpNu1 binding sites within cosB. The IHF-dependent phenotype of a lambda mutant carrying a deletion of the R1 sequence indicates that IHF obviates the need for terminase binding to the R1 site. In contrast, a lambda mutant deleted for R2 and R1 fails to form plaques on either IHF+ or IHF- cells, indicating terminase binding of R2 is involved in suppression of R mutants by IHF. A fourth R sequence, R4, is situated on the left side of cosN; a phage with a mutant R4 sequence shows a reduced burst size on both an IHF+ and an IHF- host. The inability of the R4- mutant to be suppressed by IHF, plus the fact that R4 does not bind gpNu1, suggests R4 is not part of cosB and may play a role in DNA packaging that is distinct from that of cosB.     

Structure and inherent properties of the bacteriophage lambda head shell. VI. DNA-packaging-defective mutants in the major capsid protein

Some amino acid substitutions in the major capsid protein (gene E product) of lambda phage are found to cause a defect in DNA packaging. These substitutions permit initiation of DNA packaging and expansion of the prohead. However, cleavage of the concatemer DNA at the cos site takes place only to a very small extent, and the capsid eventually becomes empty. Interestingly, the mutations are suppressed by a decrease of the DNA length between the cos sites by 8000 to 10,000 bases. These properties are similar to those of amber mutants in gene D, which codes for the capsid outer-surface protein. Studies on the E missense.D amber double mutant show that the E protein and the D protein contribute additively to the stabilization of the condensed form of the DNA molecule in phage heads.     

Heteroduplex Chain Polarity in Recombination of Phage λ by the Red, Recbcd, Recbc(d(-)) and Recf Pathways

We have examined the chain polarity of heteroduplex DNA in unreplicated, bacteriophage lambda splice recombinants when recombination was by the RecBCD, RecBC(D-), or RecF pathway of Escherichia coli or the Red pathway of lambda. For each of these pathways, recombination is activated by the cutting of cos that accompanies chromosome packaging, and is effected by recombination enzymes acting at the right end created by that cutting. For exchanges occurring near cos, one parent makes a lesser physical and genetic contribution than does the other. For each pathway, when the phage carried standard cos, this minority contribution was predominantly on the r chain, ending 5' at the right end of lambda. When standard cos was replaced by a cloned inverted cos located centrally on the standard lambda genetic map, minority contribution was predominantly on the l chain. In each case, the polarity of the overlap was usually that formed by 3' overhangs of parental information and material. These results are discussed in the context of current models of recombination for the different pathways.