Electron microscope heteroduplex studies of sequence relations among plasmids of Escherichia coli. V. ilv+ Deletion mutants of F14

Generation of Campylobacter fetus S-layer protein diversity utilizes a single promoter on an invertible DNA segment

Wild-type strains of Campylobacter fetus contain a monomolecular array of surface layer proteins (SLPs) and vary the antigenicity of the predominant SLP expressed. Reciprocal recombination events among the eight genomic SLP gene cassettes, which encode 97- to 149 kDa SLPs, permit this variation. To explore whether SLP expression utilizes a single promoter, we created mutant bacterial strains using insertional mutagenesis by rescue of a marker from plasmids. Experimental analysis of the mutants created clearly indicates that SLP expression solely utilizes the single sapA promoter, and that for variation C. fetus uses a mechanism of DNA rearrangement involving inversion of a 6.2 kb segment of DNA containing this promoter. This DNA inversion positions the sapA promoter immediately upstream of one of two oppositely oriented SLP gene cassettes, leading to its expression. Additionally, a second mechanism of DNA rearrangement occurs to replace at least one of the two SLP gene cassettes bracketing the invertible element. As previously reported promoter inversions in prokaryotes, yeasts and viruses involve alternate expression of at most two structural genes, the ability of C. fetus to use this phenomenon to express one of multiple cassettes is novel.

Sequence relations among the IncY plasmid p15B, P1, and P7 prophages

Electron microscopic analysis of heteroduplex molecules between the 94-kb plasmid p15B and the 92-kb phage P1 genome revealed nine regions of nonhomology, eight substitutions, and two neighboring insertions. Overall, the homologous segments correspond to 83% of the P1 genome and 81% of p15B. Heteroduplex molecules between p15B and the 99-kb phage P7 genome showed nonhomology in eight of the same nine regions; in addition, two new nonhomologous segments are present and P7 carries a 5-kb insertion representing Tn902. The DNA homology between those two genomes amounts to 79% of P7 DNA and 83% of p15B. Plasmid p15B contains two stem-loop structures. One of them has no equivalent structure on P1 and P7 DNA. The other substitutes the invertible C segments of P1 and P7 and their flanking sequences including cin, the gene for the site-specific recombinase mediating inversion.

Highly mobile DNA segment of IncI alpha plasmid R64: a clustered inversion region

When R64 DNA was digested with EcoRI, two DNA fragments not equimolar to the plasmid DNA were produced. A DNA region including these fragments was cloned (pKK009), and the pKK009 DNA sample was found to be a mixture of six or more DNA species with EcoRI, PstI, and AvaI cleavage sites at different positions, suggesting a complex rearrangement of DNA. When a part of the pKK009 DNA was removed by HindIII digestion, 33 different types of plasmids (pKK010-series plasmids) were obtained out of 58 clones tested, but no DNA rearrangement could be observed. On the basis of a comparison of the detailed restriction maps of these pKK010-series plasmids, we propose a model in which four DNA segments invert independently or in groups within the 1.95-kilobase region of R64, so that the arrangements of these four segments change randomly. The fixed pKK010-series plasmid DNA was again rearranged in the presence of R64, indicating that trans-acting gene function may be present to mediate the DNA rearrangement. The gene (tentatively designated as rci) was located on a 4.5-kilobase E9' fragment of R64.

Genetic location of genes encoding enterobacterial common antigen

A new rff mutation (rff-726) of Escherichia coli is described which affects the biosynthesis of the enterobacterial common antigen. This mutation was detected in an rfe-defective strain. A Tn10 insertion near the rfe locus was isolated to facilitate further mapping. Both mutations rfe and rff were mapped by transduction with bacteriophage P1, giving the gene order ilv rfe rff uvrD metE. The F' factor F14 was able to complement both mutations rfe and rff, whereas the F' factor F16 could complement the rfe but not the rff mutation. The rff mutation did not affect the biosynthesis of N-acetyl-D-mannosaminuronic acid, as the previously described rff mutations in Salmonella typhimurium do (H. C. Lew, H. Nikaido, and P. H. Mäkelä, J. Bacteriol. 136:227-233, 1978), and also did not affect the biosynthesis of other enterobacterial common antigen components; however, the biosynthesis of the complete enterobacterial common antigen molecule was blocked.

Bacteriophage P1 carries two related sets of genes determining its host range in the invertible C segment of its genome

The bacteriophage P1 genome carries an invertible C segment consisting of 3-kb unique sequences flanked by 0.6-kb inverted repeats. Host range mutations of P1 have been mapped in the C segment region. P1 derivatives carrying insertions and deletions in the left half of the C segment in one of two orientations termed C(+) do not affect the plaque-forming ability on Escherichia coli K12 and E coli C, whereas those having insertions in the right half of the C segment fail to form plaques on these hosts. An E. coli C mutant which allows the latter insertion mutants with the C segment in the C(-) configuration to form plaques has been isolated. Not only P1 C(-) but also P1 C(+) phages gave plaques on this E. coli C mutant. The results are consistent with the notion that the C segment of P1 carries two sets of genes for host specificity, and that C inversion alters the P1 host range through activation of one set of the genes. Furthermore, extended host range mutants can be isolated by point mutation in either set of the P1 genes. C inversion is a slow process, but it occurs on the phage genome upon its vegetative growth as well as on the prophage in the lysogenic state. The 3-kb invertible G segment of the phage Mu genome is known to be homologous with the central 3-kb part of the C segment of P1 and to carry also two sets of genes for Mu host specificity. While only Mu G(-) grows on E. coli C, both Mu G(+) and Mu G(-) phages form plaques on the E. coli C mutant sensitive to P1 C(-). In the discussion the gene organization of the P1 C segment is compared with that of the Mu G segment.

Physical analysis of the genomes of hybrid phages between phage P1 and plasmid p15B

The genomes of three plaque-forming recombinant phages between phage P1 and plasmid p15B were characterized by restriction cleavage analysis and electron microscopic heteroduplex studies. The structure of all three P1-15 hybrid genomes differs from that of P1 DNA in the res mod region coding for restriction and modification systems EcoP15 and EcoP1, respectively. P1-15 hybrid 2 shows an additional major difference to P1 around the site of the residential IS1 element of P1 and it does not carry an IS1 in its genome.

Cointegrational transduction and mobilization of gentamicin resistance plasmid pWP14a is mediated by IS140

The structures of two R-plasmids pWP14a and pWP12a (Tra-, Ap, Gm; 21 kb) and of several cointegrates they form with bacteriophages P1Cm and P1-15 were analyzed. In each case, replicon fusion was mediated by the element IS140 (about 0.8 kb), one copy of which resides on both plasmids adjacent to the gentamicin resistance determinant (AAC(3)-III). pWP14a cointegrated preferentially into or near the invertible C-loop structure of the P1 genome. Cointegrational mobilization of pWP14a was observed also with several conjugative R-factors. The process of replicon fusion is independent of the host's rec+ functions. Sequences homologous to IS140 are constituents of many R-factors, including RA1, R40a, R124, R144, Rts1, N3, and pJR255. IS140 also shows homology to two other sequences, IS15 delta and Tn2680, but not to other, well studied transposable elements. The ampicillin resistance determinant of pWP14a is within a Tn3-like transposon, Tn3651.

Genome fusion mediated by the site specific DNA inversion system of bacteriophage P1

The genome of bacteriophage P1 contains a segment which is invertible by site specific recombination between sequences near the outside ends of the inverted repeats which flank it. Immediately adjacent to this C segment is the coding sequence for cin, the enzyme catalyzing inversion. We show that multicopy plasmids carrying cin and the sequences at which it acts (cix) can form dimers in the absence of the host recA function. Further, such plasmids can be cotransduced with P1 markers at high frequency from recA lysogens, indicating cointegration with the P1 genome. It is thus demonstrated that a system whose primary role is the inversion of a specific DNA segment can also mediate intermolecular recombination.

Tn1525, a kanamycin R determinant flanked by two direct copies of IS15

We have isolated plasmid pIP112 (IncI1) from Salmonella panama and characterized by restriction endonucleases analysis and by recombinant DNA techniques a transposable element designated Tn1525. This 4.44 kilobase (kb) transposon confers resistance to kanamycin by synthesis of an aminoglycoside phosphotransferase (3') (5") type I and contains two copies of IS15 (1.5 kb) in direct orientation. The modular organisation of Tn1525 offers the possibility for intramolecular homologous recombination between the two terminal direct repeats and thus accounts for the in vivo structural lability of plasmid pIP112: instability of kanamycin resistance and tandem amplification of the kanamycin determinant. Other transposons mediating resistance to kanamycin by the same enzymatic mechanism were analysed by agarose and polyacrylamide gel electrophoresis, following digestion with restriction endonucleases, and by Southern hybridizations. These comparisons indicate that, although the structural genes for the phosphotransferases are homologous, Tn1525 differs from Tn903 and Tn2350 and is closely related but distinct from Tn6. Using the same techniques Tn1525 was detected on plasmids belonging to different incompatibility groups and originating from various species of Gram-negative clinical isolates. These results indicate that Tn1525 is representative of a new family of class I composite transposons already spread in diverse pathogenic bacterial genera.

A site-specific, conservative recombination system carried by bacteriophage P1. Mapping the recombinase gene cin and the cross-over sites cix for the inversion of the C segment

The bacteriophage P1 genome carries an invertible C segment consisting of 3-kb unique sequences flanked by 0.6-kb inverted repeats. With insertion and deletion mutants of P1 derivatives the site-specific recombinase gene cin for C inversion) has been mapped adjacent to the C segment and the cix sites (for C inversion cross-over) have been located at the outside ends of the inverted repeats. Inversion of the C segment functions as a biological switch and controls expression of the gene(s) responsible for phage infectivity carried on the C segment. The cin gene product can promote recombination between a 'quasi- cix ' site on plasmid pBR322 and a cix site on P1 DNA. The junctions formed on the resulting co-integrate can also serve as cix sites. This observation implies a potential evolutionary process to bring genes under the control of a biological switch acting by DNA inversion.

Homology between the invertible deoxyribonucleic acid sequence that controls flagellar-phase variation in Salmonella sp. and deoxyribonucleic acid sequences in other organisms

The invertible deoxyribonucleic acid (DNA) segment cloned from Salmonella sp. was radioactively labeled and used as a probe to search for homologous sequences by Southern hybridization. Only one copy of the invertible segment could be found on the Salmonella sp. genome. Partial sequence homology with the invertible region was detected in bacteriophage Mu and P1 DNA by low-stringency hybridization. Under these conditions, no homology was detected with Escherichia coli DNA. A strain of Salmonella sp. defective in phase variation carrying the vH2- allele was also analyzed by DNA-DNA hybridization. The results show that there is sequence divergence between diphasic and vH2- strains within the invertible sequence.

Recombinational instability of F' plasmids in Escherichia coli K-12: localization of fre-sites

The F' plasmids ORF-1 (purE+ tsxs proC+ lac+) and F'14 (argE+ metB+ ilv+) contain active regions of recombination, fre I and fre II correspondingly. The plasmid ORF-1 is stable in recF- cells (i.e., with the RecBC pathway of recombination) and decays in rec+ cells (RecBCF pathway) giving two types of product: F+ and plasmid pCK-1 (tsxs proC+ lac+) containing part of the initial DNA. They are extremely instable in the presence of the RecF pathway, (recBC- sbcB-), yielding F+ and plasmid pCK-2 (proC+ lac+). The instability of plasmids depends on a region of homology between the chromosome and the episome. The instability of ORF-1 shows the participation of IS3 elements (alpha 1 beta 3 and alpha 3 beta 1) in the recA, recF-dependent recombinational decay and allows localization of two active sites on the chromosome: fre I1 between purE and tsx markers and fre I2 between tsx and proC. The plasmid F'14, in accordance with published data, is able to yield F+ cells by recA-independent recombination. But eventually this plasmid may undergo a recA, recF-dependent decay. Genetic analysis of these events allows localization of an active point of recombination, freII1, between argE and metB. Another active point is localized inside the F factor. The recA-dependent decay of plasmid F-14 is also excluded on the RecBC pathway (recF- strains).

Characterization of P1argF derivatives from Escherichia coli K12 transduction. I. IS1 elements flank the argF gene segment

Specialized transducing derivatives of the temperate bacteriophage P1 (P1std) are selected by transduction into recipients with deletions in the corresponding genes (Stodolsky 1973). When Escherichia coli K12 strains are used as donors in such transduction experiments, P1argF derivatives can be selected. The argF gene is unique to these strains (Glansdorff et al. 1967). Under these experimental conditions P1argF are formed with frequencies 10,000 times greater than other P1std. The majority of the P1argF derivatives that have been analyzed are indistinguishable by cleavage analyses. One such derivative, P1argF5 has been characterized in detail. Heteroduplex analysis against P1, P7, and P1CmO identified an 11 kb insertion of DNA precisely at the naturally occurring IS1 locus of P1. Cleavage analysis with EcoRI, BamHI and PstI confirmed this finding. To further define the argF insertion, a P1Cm13argF derivative was constructed having the IS1 sequences of Cm13 and argF in opposite orientation. Intrastrand annealing of P1Cm13argF5 DNA established that the argF segment is flanked by directly repeated IS1 sequences. The IS1-argF-IS1 segment is designated Tn2901. The assignment of the map position of the argF gene within the 11 kb insert of P1argF5 is discussed. The evolutionary significance of this finding and a model for P1argF formation is also presented.

The ilvG gene is expressed in Escherichia coli K-12

Three genes code for isozymes of acetohydroxy acid synthase (AHAS) in Escherichia coli K-12. To test the previously published supposition that one of them, ilvG, is silent in ilvO+ strains, we isolated mutants which had deletions of various lengths in the ilvGEDA operon. Some of these mutants have severely reduced levels of AHAS activity. We conclude that ilvG is expressed in ilvO+ strains but is deleted in these mutants. In addition, we find that AHAS II, the ilvG gene product, is sensitive to feedback inhibition by valine. We hypothesize that ilvO- mutations are ilvG frameshift mutations which render AHAS II valine resistant and enhance transcription of distal genes.

Inversions of specific DNA segments in flagellar phase variation of Salmonella and inversion systems of bacteriophages P1 and Mu

Prophages P1 and Mu produces a trans-acting factor possessing the din+ activity which catalyzes the inversion of the specific DNA segment responsible for flagellar phase variation of Salmonella, din mutants were isolated from PICMclr100 phage by selecting phages that did not suppress the yh2 mutation of Salmonella in prophage state. No inversion loop structure was detected among DNA forms arising after denaturation and rehybridization of DNAs extracted from the din mutants. The DNA fragment containing C region of P1 was cloned on a plasmid vector, pCR1. The resulting hybrid plasmid, pKK2, was shown to possess the din+ activity: the vh2 mutant of Salmonella harboring the plasmid changed the flagellar phase. From analysis of the plasmid by use of BamHI and Bgl II, the din gene specifying the din+ activity was located near or within the C region of P1. It is highly plausible that the din gene of P1 was also involved in the inversion of the C region. Similarly, the DNA fragment containing the G and beta segments of Mu was cloned on pCR1. The resulting hybrid plasmid, pII101, also possessed the din+ activity.

Inversion in the lactose region of Escherichia coli K-12

A spontaneous mutant of Escherichia coli K-12, strain SY99, with an inversion in the lactose region was isolated and partially characterized. The inversion was detected due to inverse chromosomal conjugational transfer after introduction of an F42 (F'lac) episome. The termini of the inversion are between proAB and lac on one side and lac and proC on the other. The inverse conjugational transfer in SY99 did not appear to be absolute but was always accompanied by a residual "normal" counterclockwise mobilization. This residual transfer was further shown to be caused by the intrinsic instability of this region (at least in the line W3110). The possible involvement of IS3 elements flanking the lactose operon is discussed.

Multiple physical differences in the genome structure of functionally related bacteriophages P1 and P7

Comparative restriction cleavage analysis of the genomes of bacteriophage P7, of several recombinant phages between P7 and P1, and of bacteriophage P1 allowed to draw PstI, Bg/II, BamHI and HindIII cleavage maps of all genomes studied. The data obtained complement Yun and Vapnek's (1977) conclusions with regard to areas of major nonhomology based on electron microscopical heteroduplex analysis and they identify several additional minor differences between P1 and P7. The use of hybrid phage strains allowed to locate the genes for particular functions on the physical genome map.

Origin of replication, oriC, of the Escherichia coli chromosome: mapping of genes relative to R.EcoRI cleavage sites in the oriC region

A precise genetic-physical map of the tna-ilv region at 82 min on the genetic map of E. coli is obtained through deletion mapping and analysis by restriction endonuclease EcoRI of plasmids, derived from an F' carrying the genes between aroE and ilv. A locus, designated het, which in its diploid state results in slow growth and heterogeneity of cell size due to distorted cell division, maps between bglB and asn, 30-45 kb counterclockwise of ilv. The pattern of R.EcoRI cleavage sites in the het region is identical with the pattern obtained by Marsh and Worcel (1977) who analyzed DNA labeled preferentially in the region of the DNA replication origin (oriC). We suggest that oriC is identical with the het site and that it can be allocated to a position 32 kb counterclockwise of the ilv operon.

Physical mapping of BglII, BamHI, EcoRI, HindIII and PstI restriction fragments of bacteriophage P1 DNA

A cleavage map of bacteriophage P1 DNA was established by reciprocal double digestion with various restriction endonucleases. The enzymes used and, in parenthesis, the number of their cleavage sites on the P1clts genome are: PstI (1), HindIII(3), BglII (11), BamHI (14) and EcoRI (26). The relative order of the PstI, HindIII and BglII sites, as well as the order of 13 out of the 14 BamHI sites and of 17 out of the 26 EcoRI sites was determined. The P1 genome was divided into 100 map units and the PstI site was arbitrarily chosen as reference point at map unit 20. DNA packaging into phage heads starts preferentially at map unit 92 and it proceeds towards higher map units. The two inverted repeat sequences of P1 DNA map about at units 30 and 34.

Further mapping of IS2 and IS3 in the lac-purE region of the Escherichia coli K-12 genome: structure of the F-prime ORF203

The sequence organization of the F-prime ORF203 was determined by heteroduplex analysis. This large, type II F-prime (Scaife, 1967) contains lac, proC, and purE genes derived from the W1485 subline of Escherichia coli K-12. The IS3 and IS2 elements previously found in the lac-proC-purE region derived from the 58-161 subline (Hu et al., 1975) are also present in the same locations in the bacterial deoxyribonucleic acid (DNA) from the W1485 subline. Recombination between the IS2 region of F and an IS2 element located between lac and proC on the bacterial DNA apparently led to the formation of the perental Hfr, OR21. IS2 is thus directly repeated, with one copy of each element appearing at each of the two junctions between F and the bacterial sequences on ORF203. The F plasmid is found together with ORF203 in the plasmid DNA, and this probably forms from ORF203 by recombination between the directly repeated IS2 elements. ORF203 appears to have been excised from the Hfr chromosome by recombination between the IS3 sequence alpha3beta3 located counterclockwise of lac and the directly repeated IS3 sequence alpha4beta4 located clockwise of purE.

Transposition of a plasmid deoxyribonucleic acid sequence that mediates ampicillin resistance: independence from host rec functions and orientation of insertion

Insertion of the transposable deoxyribonucleic acid sequence that specifies the TEM beta-lactamase (TnA) occurred in at least 19 sites on the 5.5 x 10(6)-dalton plasmid RSF1010. There was no significant difference in the frequency of transposition or in the distribution of TnA insertion sites for recombinant plasmids isolated from recombination-proficient (rec+) or recombination-deficient (rec-) bacterial host cells. The site and orientation of TnA insertions were determined by both heteroduplex analysis and enzymatic digestion with restriction endonucleases. Insertion in the gene encoding for sulfonamide resistance occurred without circular permutation in one or the other of two distinct orientations. Insertions in orientation P were strongly polar on distal gene expression, whereas insertions in orientation M were mutagenic but not polar. In addition, we have observed that TnA elements from different R plasmids show fine structural heterogeneity, and that TnA insertion at a site adjacent to the origin of replication causes an increase in plasmid copy number.

Specialized transduction of D-serine deaminase genes: formation of lysogens that yield high lambda-d dsd/lambda ratios and formation of a dimeric lambda-d dsd

We have obtained two classes of double lysogens that on induction yield higher titers of lambda-d dsd transducing phage than of helper phage. One class was obtained by lysogenization of strain EM6116 (dsddelta attlambdadelta HfrC) with lambda-dsd type 2 (dsdC+ dsdO+ dsdA+, head-tail substitution). In the absence of either a normal attlambda or the homology of a chromosomal dsd region, the transducing phage integrated at other sites, at least one of which, in strain EM6177, is near the origin of HfrC. On induction, strain EM6177 yields a phage burst of 20 to 50 with a lambdadsd:lambda ratio of 10(4):1. The asnychronously high yield of lambda dsd is attributed to an efficiency of excision greater than that of lambda. The other class was obtained by lysogenization of strain EM1407 (dsdA attlambda+) with lambda-dsd type 2 (dsdO6 dsdA, partial deletion of dsdC). The DNA of mature lambda-dsd type 2 is a complete dimer. It lacks nearly all the phage late genes and b2 and carries about five bacterial genes. It could not be packaged as a monomer but is just within the packaging size limit as a dimer. Models for the derivation of these lambda dsd phages and the high-yielding lysogens are presented.

Isolation of inverted repeat sequences, including IS1, IS2, and IS3, in Escherichia coli plasmids

A method is described for isolation of inverted repeat DNA sequences that occur in E. coli plasmids. The procedures of the isolation involved: (a) denaturation of intact plasmid DNA, (b) a rapid, 30 sec, renaturation of inverted-repeat sequences in the genome, (c) digestion of the single-stranded portion by S1 nuclease to recover duplex DNA, and (d) detection and purification of the duplexes using 1.4% agarose gel electrophoresis. If a plasmid DNA carried inverted repeats of either one type or two different types of special DNA sequences, these procedures enabled us to observe either one or two characteristic DNA bands, respectively, in the agarose gels. If a plasmid DNA did not carry any inverted repeats, or if the plasmid DNA only carried direct repeat sequences, no characteristic DNA bands were recovered. Cleavage of the spacer DNA between inverted repeat sequences generated no gel bands. This indicated that the inverted repeat sequences must be in the same strand. Using this method, we isolated and purified several repeated sequences, including IS1, IS2, and IS3, from derivatives of F and R plasmids.

Novel genotypes among transductants made with bacteriophage P1 lysates from an F14 merogenote strain of Escherichia coli K-12

Among P1 transductants in Escherichia coli K-12 that were selected for the proximal and distal markers from the large F14 merogenote, a variety of unusual genotypes were found. As earlier workers had found, one class of these could transfer the proximal genes (argH, metB) and distal genes (ilvEDAC) of the F14 during conjugation. These F14 genes could be transferred into RecA recipients, indicating that they were carried on an F-merogenote rather than on an Hfr chromosome. The transduced F-merogenotes could transfer other F14 genes (metE, rha) as well. Transfer kinetic analysis showed that all of the latter transduced F-merogenotes that were examined were indistinguishable from the parental F14 in the order of transfer and the genetic distance between proximal and distal markers. This suggests that the whole F14 had been received somehow by the primary transductional recipients, a remarkable possibility since the F14 is much larger than the largest deoxyribonucleic acid segment normally transduced by P1. The mechanism of this phenomenon is not yet known. Many of the transductants did not transfer any of the F14 markers tested. Some of these transductants segregated certain F14 genes, indicating they were carried on self-replicating genetic elements, but others were not cured of F14 markers, even by acridine orange. Cotransductional analysis of this group was consistent with the hypothesis that the F14 markers in some of these strains had integrated into the chromosome in the expected manner, since in these latter the F14 alleles were linked to the expected chromosomal genes. Other strains among the stable transductants had acquired new linkages in that genes previously separated by several minutes could now be cotransduced. These latter included the novel cotransductional linkages of rbs-ilv-argH, rbs-ilv-argH-metB, and ilvD-argH-purD. Such strains might have been formed as a result of insertion into the chromosome of small circles derived from F14.

Use of gene 32 protein staining of single-strand polynucleotides for gene mapping by electron microscopy: application to the phi80d3ilvsu+7 system

A method for visualizing RNA-DNA duplex regions along a single strand of DNA in the electron microscope is described. A preparation of RNA molecules is hybridized to a long DNA strand containing the coding sequences (genes) for some of the RNAs. T4 gene 32 protein, which binds selectively and cooperatively only to the single-strand regions, is added, followed by glutaraldehyde. The resulting nucleic acid-gene 32 complex is adsorbed to the surface of an electron microscope grid in the presence of ethidium bromide. The single-strand regions are relatively thick (8.5 nm) compared to the duplex (RNA-DNA hybrid) regions (3.5 nm), so that the two kinds of regions are readily recognized by electron microscopy. In favorable cases, tRNA-DNA hybrids of length about 80 nucleotide pairs can be recognized (although with difficulty). The positions of a number of interesting genetic sequences on the DNA of the transducing phage phi80d3ilvsu+7 have been mapped. The r strand contains 16S, 23S, and 5S rRNA coding sequences in that order. The spacer between 16S and 23S genes has a length of 500 nucleotides and contains the coding sequence for a tRNA2Glu gene in agreement with previous biochemical observations. The spacer between the 23S and 5S genes has a length of 180 nucleotides. The su+7 tRNATrp coding sequence has been mapped on the l strand at a position just to the left of the ilv genes. Secondary structure loops due to short inverted repeat sequences flanking the 16S, 23S, tRNATrp, and F sequences in the DNA have been observed.

Genetic studies of coliphage P1. I. Mapping by use of prophage deletions

One hundred and ten amber mutants of coliphage P1 were isolated and localized into groups with respect to the existing genetic map by use of nonpermissive Escherichia coli K-12 strains lysogenic for P1 with deletions. These lysogens contain one of three types of deletion prophages: P1cry and its derivatives, P1dlacs, and P1dpros. Fourteen such lysogens were tested for their ability to rescue the amber mutants which were then assigned to one of nine deletion segments of the P1 genome defined by the termini of the various prophage deletions. The relationship of the nine deletion segments with the published P1 map is described, two new segments having been added. The deletions of the 14 prophages overlapped sufficiently to indicate that the P1 genetic prophage map should be represented in circular form, which is consistent with the fact that P1 is normally a circular plasmid in the prophage state. The distribution of mutants into deletion segments is nonrandom for at least one segment. In addition, the deletion termini of the 14 defective prophages coincided in five out of nine regions separating the nine deletion segments. Various possible explanations are discussed for the nonrandom recurrence of these deletion termini, including the evidence of hot spots of recombination.