Dissection and comparative anatomy of the origins of replication of lambdoid phages

Complementation Studies of Bacteriophage λ O Amber Mutants by Allelic Forms of O Expressed from Plasmid, and O-P Interaction Phenotypes

λ genes O and P are required for replication initiation from the bacteriophage λ origin site, oriλ, located within gene O. Questions have persisted for years about whether O-defects can indeed be complemented in trans. We show the effect of original null mutations in O and the influence of four origin mutations (three are in-frame deletions and one is a point mutation) on complementation. This is the first demonstration that O proteins with internal deletions can complement for O activity, and that expression of the N-terminal portion of gene P can completely prevent O complementation. We show that O-P co-expression can limit the lethal effect of P on cell growth. We explore the influence of the contiguous small RNA OOP on O complementation and P-lethality.

Opening the Strands of Replication Origins-Still an Open Question

The local separation of duplex DNA strands (strand opening) is necessary for initiating basic transactions on DNA such as transcription, replication, and homologous recombination. Strand opening is commonly a stage at which these processes are regulated. Many different mechanisms are used to open the DNA duplex, the details of which are of great current interest. In this review, we focus on a few well-studied cases of DNA replication origin opening in bacteria. In particular, we discuss the opening of origins that support the theta (θ) mode of replication, which is used by all chromosomal origins and many extra-chromosomal elements such as plasmids and phages. Although the details of opening can vary among different origins, a common theme is binding of the initiator to multiple sites at the origin, causing stress that opens an adjacent and intrinsically unstable A+T rich region. The initiator stabilizes the opening by capturing one of the open strands. How the initiator binding energy is harnessed for strand opening remains to be understood.

Plasmid R6K replication control

The focus of this minireview is the replication control of the 39.9-kb plasmid R6K and its derivatives. Historically, this plasmid was thought to have a narrow host range but more recent findings indicate that its derivatives can replicate in a variety of enteric and non-enteric bacterial species (Wild et al., 2004). In the four-plus decades since it was first described, R6K has proven to be an excellent model for studies of plasmid DNA replication. In part this is because of its similarities to other systems in which replication is activated and regulated by Rep protein and iteron-containing DNA. However its apparent idiosynchracies have also added to its significance (e.g., independent and co-dependent replication origins, and Rep dimers that stably bind iterons). Here, we survey the current state of knowledge regarding R6K replication and place individual regulatory elements into a proposed homeostatic model with implications for the biological significance of R6K and its multiple origins of replication.

A CI-independent form of replicative inhibition: turn off of early replication of bacteriophage lambda

Several earlier studies have described an unusual exclusion phenotype exhibited by cells with plasmids carrying a portion of the replication region of phage lambda. Cells exhibiting this inhibition phenotype (IP) prevent the plating of homo-immune and hybrid hetero-immune lambdoid phages. We have attempted to define aspects of IP, and show that it is directed to repλ phages. IP was observed in cells with plasmids containing a λ DNA fragment including oop, encoding a short OOP micro RNA, and part of the lambda origin of replication, oriλ, defined by iteron sequences ITN1-4 and an adjacent high AT-rich sequence. Transcription of the intact oop sequence from its promoter, p(O) is required for IP, as are iterons ITN3-4, but not the high AT-rich portion of oriλ. The results suggest that IP silencing is directed to theta mode replication initiation from an infecting repλ genome, or an induced repλ prophage. Phage mutations suppressing IP, i.e., Sip, map within, or adjacent to cro or in O, or both. Our results for plasmid based IP suggest the hypothesis that there is a natural mechanism for silencing early theta-mode replication initiation, i.e. the buildup of λ genomes with oop(+)oriλ(+) sequence.

Nucleotide sequence of the S-2 mitochondrial DNA from the S cytoplasm of maize

Mitochondria from the S male-sterile cytoplasm (cms-S) of maize contain two plasmid-like DNAs, S-1 and S-2, that appear to be prominently involved with the cytoplasmic male sterility trait. The complete nucleotide sequence of the S-2 DNA molecule was determined by the chain termination method. The linear S-2 DNA molecule contains 5,452 base pairs and is terminated by exact 208-base-pair inverted repetitions. Two large open reading frames were identified in the S-2 DNA, suggesting the possibility of protein-encoding genes. The nucleotide sequence of the S-2 termini are discussed with regard to models proposed for the replication of linear DNA molecules.

Sequence analysis of the cryptic plasmid pMG101 from Rhodopseudomonas palustris and construction of stable cloning vectors

A 15-kb cryptic plasmid was obtained from a natural isolate of Rhodopseudomonas palustris. The plasmid, designated pMG101, was able to replicate in R. palustris and in closely related strains of Bradyrhizobium japonicum and phototrophic Bradyrhizobium species. However, it was unable to replicate in the purple nonsulfur bacterium Rhodobacter sphaeroides and in Rhizobium species. The replication region of pMG101 was localized to a 3.0-kb SalI-XhoI fragment, and this fragment was stably maintained in R. palustris for over 100 generations in the absence of selection. The complete nucleotide sequence of this fragment revealed two open reading frames (ORFs), ORF1 and ORF2. The deduced amino acid sequence of ORF1 is similar to sequences of Par proteins, which mediate plasmid stability from certain plasmids, while ORF2 was identified as a putative rep gene, coding for an initiator of plasmid replication, based on homology with the Rep proteins of several other plasmids. The function of these sequences was studied by deletion mapping and gene disruptions of ORF1 and ORF2. pMG101-based Escherichia coli-R. palustris shuttle cloning vectors pMG103 and pMG105 were constructed and were stably maintained in R. palustris growing under nonselective conditions. The ability of plasmid pMG101 to replicate in R. palustris and its close phylogenetic relatives should enable broad application of these vectors within this group of alpha-proteobacteria.

An essential iteron-binding protein required for plasmid R1162 replication induces localized melting within the origin at a specific site in AT-rich DNA

The R1162-encoded protein RepIB is essential for replication of the plasmid and binds specifically to iterons within the replicative origin. The protein causes the localized melting of DNA (determined by sensitivity to P1 nuclease) at a site within the AT-rich region of the origin, about 60 bp from the iteron binding sites and separated from them by a GC-rich tract. Point mutations have been isolated in the AT-rich DNA. These mutations interfere with origin activity and also prevent the protein-induced sensitivity to P1. A second-site suppressor of one of these mutations maps in the repIb gene and restores both origin function and sensitivity to P1. The results suggest a specific interaction between RepIB and origin DNA at a position distant from its primary binding site.

Overproduction of an antisense RNA containing the oop RNA sequence of bacteriophage lambda induces clear plaque formation

We have constructed an IPTG-inducible plasmid which overexpresses oop RNA sequences in Escherichia coli. Infection of these transformed E. coli cells (SB221/pOOP5) with lambda+ phage produced clear plaques, whereas lambda+ infection of cells transformed with the plasmid vector (SB221/pJDC406) or the plasmid expressing the oop RNA transcript in the other orientation (SB221/pOOP9) gave rise to turbid plaques characteristic of lambda+. Calculations of the percentage of infected cells forming lysogens show a 6-fold decrease in the absence of isopropyl beta-D-thiogalactoside (IPTG) and a 20-fold decrease in the presence of IPTG for SB221/pOOP5 as compared to both SB221/pJDC406 and SB221/pOOP9. We have thus shown that the overexpression of oop RNA favors the lytic mode of lambda development.

Characterization of a bacteriophage that carries the genes for production of Shiga-like toxin 1 in Escherichia coli

The Shiga-like toxin 1-converting bacteriophage H-19B was recently shown to carry the structural genes for the toxin and was shown to have DNA sequence homology with phage lambda. We present evidence that the linear genome of bacteriophage H-19B has cohesive termini which become covalently associated during prophage integration. Integration occurs through a site on a 4-kilobase-pair EcoRI fragment located near the center of the bacteriophage chromosome. The relationship between bacteriophages H-19B and lambda was examined by Southern hybridization. Homologous regions were mapped on the respective chromosomes which corresponded to the regions of the J gene, the int-xis area, and the O and P genes of phage lambda. The H-19B tox genes were mapped to the right of the O and P gene homology, which was far away from the phage attachment site. We concluded that H-19B is a lambdoid bacteriophage. Unlike other toxin-converting bacteriophages, the toxin genes were not located adjacent to the phage attachment site. It appeared that the Shiga-like toxin 1 genes were not picked up by a simple imprecise prophage excision. H-19B could, however, have acquired chromosomally located toxin genes by a series of events involving deletion and duplication followed by aberrant excision.

Direct evidence for DNA bending at the lambda replication origin

Replication initiation in bacteriophage lambda appears to require wrapping of origin DNA on an approximately 50 angstrom radius in or around the complex with the initiator protein O. Since short lengths of DNA are not that flexible, it may be that runs of coherently spaced deoxyadenylate residues constitute bend sites in the ori sequence that facilitate the process. Earlier data showed that ori DNA has electrophoretic anomalies characteristic of bend sites and that these are augmented by initiator protein binding. Here origin bending is examined by direct measurement of the ability of polymerized ori sequences to form small circles. The smallest circles observed (84 residues) are compatible with the required radius of curvature. Bend sites within the O protein binding sites, bend sites in the spacers between them, plus the inherent flexibility of non-bent DNA in the origin may all contribute to origin bending. The data also show that a bend site is required for O protein binding to DNA.

Multiple DNA-protein interactions governing high-precision DNA transactions

The precise association of DNA-binding proteins with localized regions of DNA is crucial for regulated replication and expression of the genome. For certain DNA transactions, the requirement for precision in localization and control is extremely high. High-precision events amenable to detailed biochemical analysis are the initiation of DNA replication and site-specific recombination by bacteriophage lambda and Escherichia coli. Recent experiments indicate that site-localization and control in these reactions involves the association of DNA-bound proteins to generate organized nucleoprotein structures in which the DNA is folded or wound. These specialized nucleoprotein structures are likely to provide the requisite accuracy for site localization and the necessary regulated reactivity to direct the DNA transaction. Multiple DNA-protein interactions are also required for controlled transcription of the eukaryotic genome. Distant upstream regulator and enhancer sequences may define protein-binding sites that form part of a reactive nucleoprotein structure capable of initiating transcription.

Sequence-induced DNA curvature at the bacteriophage lambda origin of replication

DNA replication in bacteriophage lambda begins at a unique origin between residues 39,000 and 39,200 of the lambda genome. This segment of DNA serves a dual function since it also lies within the coding sequence of the lambda replication initiator protein O which binds origin DNA. The lambda origin sequence contains four 19-base-pair (bp) segments (iterons) which have dyad symmetry, followed by a 40-bp A + T-rich zone of highly asymmetrical base composition. It was noted earlier that lambda origin DNA exhibits an anomalous electrophoretic mobility on gels; that is, the length of DNA as determined by DNA sequencing is approximately 20% less than is predicted from electrophoretic mobility. Recent studies of kinetoplast minicircle DNA (K-DNA) from the protozoan Leishmania tarentolae have led to the proposal that sequence-induced DNA curvature could account for such electrophoretic anomalies by alteration of the shape of the DNA molecule. We now present evidence that the lambda origin contains a static curve.

Curved DNA

A priori considerations and the concept of the sequence-dependent local curving of the DNA axis. Experimental evidence: electric dichroism (relaxation time measurements); anomalous electrophoretic mobility and gel-filtration of some restriction fragments of DNA; one-sided binding of the nucleosomal DNA to the mica surface. Theoretical predictions concerning the nucleotide sequences of the curved DNA. Discovery of the dinucleotide periodicity in the chromatin DNA. The sequence periodicity as a tool for mapping of the nucleosomes along the sequences. Preferential binding of the histone octamers to the curved pieces of DNA--sequence analysis predictions and comparison with experiments: Theoretical and experimental estimates of the tilt and roll angles for different combinations of the neighboring base-pairs. Inherent sequence-dependent curvature and apparent persistence length of DNA.

Identification of the minimal essential region for the replication origin of miniF plasmid

The minimal replication origin of miniF plasmid was found to lie within a region of 217 bp in length. This region contains an AT cluster and the four 19 bp direct repeats responsible for incompatibility, termed incB. Its location coincides with hat of ori2 of plasmid F, previously inferred to be the replication starting point by electron microscopic analysis (Eichenlaub et al. 1981).

Primary structure of the essential replicon of the plasmid pSC101

The replicon of the low copy number plasmid pSC101 has an obligatory requirement for the dnaA initiator protein of Escherichia coli as well as a plasmid-encoded initiator protein. We have identified the cistron of the plasmid-encoded initiator by DNA sequence analysis. Fusion of the initiator cistron with the lacZ gene of E. coli yielded a fusion protein of approximately equal to 150 kilodaltons, thus confirming that the open reading frame detected by DNA sequence analysis actually encoded a 37.5-kilodalton protein. Deletion of 26 amino acid residues from the COOH terminus of the plasmid initiator abolished autonomous replication from pSC101 origin. By in vitro deletion analysis we have shown that, although sequences downstream from the initiator cistron are dispensable, a maximum of 400 base pairs immediately upstream from the NH2-terminal region of the initiator is necessary for plasmid replication. These upstream sequences contain an A + T-rich region and three tandem repeats of a 21-base pair sequence; these features are characteristics of other replication origins.

Initiation of adenovirus DNA replication in vitro requires a specific DNA sequence

Initiation of adenovirus DNA replication in vitro occurs on a linearized plasmid DNA containing 3,327 base pairs of the adenovirus terminal sequence. Various deletions have been constructed in the plasmid DNA and their template activities examined. Deletions from an internal restriction enzyme cleavage site that retain only 20 base pairs or more of the adenovirus terminal sequence support initiation and limited chain elongation, whereas deletions that leave 14 base pairs or less of the terminal sequence do not. On the other hand, all deletions extending from the very terminus of the adenovirus DNA destroy the template activity. The terminal 20 base pairs of adenovirus DNA contain a sequence A-T-A-A-T-A-T-A-C-C, which is perfectly conserved in the DNAs from different serotypes of human adenovirus. Base changes within the conserved sequence greatly reduce the template activity. These results suggest that the terminal 20 base pairs constitute a functional origin for the initiation of adenovirus DNA replication in vitro.

The nucleotide sequence of replication and maintenance functions encoded by plasmid pSC101

The nucleotide sequence of 1100bp around the origin of replication of the pSC101 plasmid has been determined. This segment of DNA is capable of replication in the presence of a helper plasmid. The sequence data reveal similarities between pSC101 and several other replicons. The origin of replication contains three direct repeats of an 18bp sequence associated with a segment exceptionally rich in A-T base pairs. A promotor that probably directs transcription of a gene encoding an essential plasmid replication function is associated with a region of extensive potential secondary structure. The sequence presented here includes the sequence of the par region involved in partitioning of plasmids at cell division.

Separation of the minimal replication region of the F plasmid into a replication origin segment and a trans-acting segment

An analysis was carried out on the replication functions within a 2.3 kilobase (kb) segment of the F plasmid which contains an origin (ori s) of replication and is capable of autonomous replication in Escherichia coli. Two separable regions were delineated for this segment: an origin region of approximately 1,140 bp in length and a segment of approximately 1,140 bp that functions in trans to support replication of the origin region. The trans-acting segment is functional as part of an F replicon or when inserted into the E. coli chromosome. A prominent feature of the trans-acting segment is a coding sequence for a 29 K protein (Murotsu et al. 1981).

Replication of lambda dv DNA in vitro

Exogenous lambda dv DNA was replicated in extracts prepared from E. coli cells carrying plasmids with inducible lambda O and /or P genes. Extracts from cells carrying only one of the two lambda replication functions complement each other in this reaction. The reaction further requires ribonucleotide triphosphates, an ATP regenerating system, DNA gyrase and RNA polymerase functions. Density labelling of the superhelical reaction products results in hybrid density indicating that one complete round of replication has taken place in vitro.

Replication of linear mitochondrial DNA from Paramecium: sequence and structure of the initiation-end crosslink

Replication of the 14-micrometer linear Paramecium mitochondrial DNA is initiated by a crosslinking of the duplex strands at the initiation end of the molecule. As a consequence of the crosslink, a head-to-head dimer molecule, or palindrome, is a replicative intermediate. The central region of the dimer molecules of two species was cloned and sequenced, In the distal regions, the sequence is palindromic as expected; however, in the central region, there is a nonpalindromic sequence that is rich in A + T and contains direct tandem repeats. It is proposed that the nonpalindromic sequence constitutes the crosslink. Implications for the replication scheme are discussed. The model is unlike any other for a linear DNA.

Purified bacteriophage lambda O protein binds to four repeating sequences at the lambda replication origin

The bacteriophage lambda O protein is needed for initiation of lambda DNA replication. Several lines of evidence suggest that initiation requires that this protein interacts with a specific sequence called ori (for origin) in lambda DNA. We have purified this protein to near homogeneity and studied the protection against nuclease cleavage of the origin DNA sequences. Our data demonstrate that the O protein binds within an interval of about 95 base pairs (bp), which contains four tandemly arranged 19bp repeating sequences, ATCCCTCAAAACGA (G)GG GAT(A). At a low concentration of O protein, the inner two repeats are primarily covered, while binding to the outer two repeats requires a high concentration of O protein. From the molecular size of O protein (32,000 daltons), and the internal symmetry in each 19bp repeat, we inferred that the O protein may bind in dimeric form, and that the 95bp region may be filled only when four such dimers have bound. This interaction is discussed in connection with the "activation" of the ori by O protein leading to initiation of DNA synthesis.

Nucleotide sequence at the termini of the DNA of Bacillus subtilis phage phi 29

Phage phi 29 DNA cannot be phosphorylated with polynucleotide kinase and [gamma-32P]ATP because of the presence of a viral protein covalently linked to the 5' termini. The 5' ends can, however, be made susceptible to phosphorylation by treatment with alkali and alkaline phosphatase. Restriction fragments Hpa II C and Hpa II F, corresponding to the right and left ends of phi 29 DNA, respectively, were labeled at the 5' ends with polynucleotide kinase and [gamma-32P]ATP or at the 3' ends with terminal transferase and [alpha-32P]ATP or [alpha-32P]cordycepin 5'-triphosphate. After a secondary cleavage of the labeled fragments, the sequence of the first 150-180 nucleotides at the termini of phi 29 DNA was determined by the method of Maxam and Gilbert. The ends of phi 29 DNA are flush, and a six-nucleotides-long inverted terminal repetition was found. The functional implications of the sequences determined are discussed.

Interactions between phage lambda replication proteins, lambda DNA and minicell membrane

Gentle methods for minicell lysis and lysate fractionation have been elaborated: lysis by T4 lysozyme without detergents, and fractionation by equilibrium sedimentation in a metrizamide density gradient, both at low ionic strength. In the lysates of phage-lambda-infected minicells the lambda DNA, trapped at a prereplicative step [Witkiewicz, H. and Taylor, K. (1979) Biochim. Biophys. Acta 564, 31-36], appeared in two peaks of different buoyant densities: as a membrane-bound and a free lambda DNA. The covalently-closed-circular form of lambda DNA appeared exclusively in the membrane fraction. The lambda-coded proteins, synthesized in lambda-infected minicells, appeared in two major fractions: as membrane-bound and as free proteins, and in one minor fraction, bound with free lambda DNA. Neither lambda protein engaged in the initiation of DNA replication was present in the fraction of free proteins: the P-gene product was membrane-associated, and the O-gene product formed a complex with free lambda DNA. The effect of high ionic strength (KCl) and of detergents (Triton X-100 and sarcosyl) on the binding of replication proteins with lambda DNA and with the membrane was studied. The non-ionic detergent, Triton X-100 caused displacement of a part of lambda DNA from the membrane to the free lambda DNA peak; both lambda replication proteins were bound with free lambda DNA. The binding of the O protein with lambda DNA was relatively stable, but was destroyed by the ionic detergent, sarcosyl.

Genes and sites involved in replication and incompatibility of an R100 plasmid derivative based on nucleotide sequence analysis

The nucleotide sequence of the entire region required for autonomous replication and incompatibility of an R100 plasmid derivative, pSM1, has been determined. This region includes the replication region and all plasmid encoded information required for replication. Numerous reading frames for possible proteins can be found in this region. The existence of one of these proteins called RepA1 (285 amino acids; 33,000 daltons) which is encoded within the region known by cloning analysis to be required for replication is supported by several lines of evidence. These include an examination of the characteristic sequences on the proximal and distal ends of the coding region, a comparison of the sequence of the replication regions of pSM1 and the highly related R1 plasmid derivative Rsc13 as well as other biochemical and genetic evidence. The existence of two other proteins, RepA3 (64 amino acis; 7000 daltons) and RepA2 (103 amino acids; 11,400 daltons) is also consistent with most of the criteria mentioned above. However, the region encoding RepA3, which by cloning analysis is within the region responsible for both replication and incompatibility, has never been demonstrated to produce a 7,000 dalton polypeptide. Since a large secondary structure can be constructed in this region, it is possible that the region contains structure or other information that is responsible for incompatibility. RepA2, encoded entirely within the region identified by cloning analysis to be responsible for incompatibility but not for replication can be visualized in vivo and in vitro. However, the nucleotide sequence of the region encoding RepA2 is completely different in mutually incompatible plasmid derivatives of R1 and R100. It is therefore unlikely that RepA2 plays a major role in incompatibility. Thus, we predict that RepA2 is required to initiate DNA synthesis at the replication origin and that the region proximal to RepA2 either encodes a gene product or structure information that is responsible for incompatibility.

Eukaryotic DNA segments capable of autonomous replication in yeast

A selective scheme is presented for isolating sequences capable of replicating autonomously in the yeast Saccharomyces cerevisiae. YIp5, a vector that contains the yeast gene ura3, does not transform a ura3 deletion mutant to Ura+. Hybrid YIp5-Escherichia coli DNA molecules also fail to produce transformants. However, collections of molecular hybrids between YIp5 and DNA from any of six eukaryotes tested (S. cerevisiae, Neurospora crassa, Dictyostelium discoideum Ceanhorabditis elegans, Drosophila melanogaster, and Zea mays) do transform the deletion mutant. The Ura+ transformants grow slowly, are unstable under nonselective conditions, and carry the transforming DNA as autonomously replicating, supercoiled circular molecules. Such a phenotype is qualitatively identical to that of strains transformed by molecules containing a yeast chromosomal origin of replication. Thus, these DNA hybrid molecules may contain eukaryotic origins of replication. The isolated sequences may be useful in determiing the signals controlling DNA replication in yeast and in studying both DNA replication and transformation in other eukaryotic organisms.

Functional analysis of minichromosome replication: bidirectional and unidirectional replication from the Escherichia coli replication origin, oriC

Replicating molecules of minichromosomes pCM959 and pOC24 were analyzed by electron microscopy. Replication of pCM959 proceeded bidirectionally from the replication origin, oriC, in about 60% of the molecules; the rest of the molecules replicated unidirectionally in either direction. pOC24, in which deoxyribonucleic acid to the right (clockwise) of the oriC segment is deleted, seemed to replicate predominantly unidirectionally counterclockwise from oriC.

Nucleotide sequence of the primary origin of bacteriophage T7 DNA replication: relationship to adjacent genes and regulatory elements

The 682-base-pair nucleotide sequence between positions 14.45 and 16.15 on the bacteriophage T7 DNA molecule has been determined. We can identify not only the sequence of the primary origin of DNA replication but also the termination of gene 1, all of genes 1.1 and 1.2, the start of gene 1.3, and a number of regulatory sequences. The endpoints of four deletion mutations that extend into this region have been determined. These mutations are inferred to have arisen by recombination between short homologous sequences, three of which ar T7 RNA polymerase promoters. The base changes of four point mutations in gene 1.2 have been identified. The sequence essential for initiation at the primary origin is located between the left endpoints of the two deletions D2 and D303. Sequence analysis of these mutants assigns the primary origin to a 129-base-pair segment between positions 14.73 and 15.05. This intergenic segment is A+T-rich (75%) and contains a single T7 gene 4 protein recognition site; it is preceded by two tandem T7 RNA polymerase promoters. A model for initiation of T7 DNA replication is presented.

Physical mapping of primary and secondary origins of bacteriophage T7 DNA replication

Deletion mutants of bacteriophage T7 have been used to identify and to map, by electron microscopy, the origins of T7 DNA replication. The primary origin of phage T7 DNA replication lies within a 100-base-pair region located 14.75-15.0% of the distance from the genetic left end of the DNA molecule. T7 phage whose DNA contains a deletion of this region initiate replication at secondary origins, the predominant one of which is located at a distance approximately 4% from the left end of the molecule.

New map of bacteriophage lambda DNA

A map of bacteriophage lambda was constructed, including accurate positions for all 41 cut sites made by 12 different restriction enzymes. Over 100 fragments from single, multiple, and partial enzyme digestions were measured versus standards that were calibrated with respect to DNA molecules of known sequence. The data were subjected to least-squares analysis to assign map coordinates. In no case did a fragment size predicted from the map differ from the measurement of the fragment by more than +/- 5%. This low error rate was consistent in all size ranges of fragments. The total length of lambda was calculated as 49,133 nucleotide pairs. This probably is accurate to within 500 base pairs.

Restriction maps for twenty-one Charon vector phages

The mapping of the sites of cleavage of nine restriction endonucleases (EcoRI, HindIII, BamHI, SalI, KpnI, SstI, BglII, XhoI, and XbaI) on 21 Charon phage vectors is described. Maps of individual subsections were obtained and then combined to assemble the complete vector maps. Calculations of maximum and minimum sizes of inserts which may be carried by the vectors using different restriction endonucleases or pairs of restriction endonucleases are presented. The regions mapped include several parts of phi 80 that had not been mapped previously.