Electron microscope heteroduplex studies of sequence relations among plasmids of Escherichia coli. VII. Mapping the ribosomal RNA genes of plasmid F14

Journey of a Molecular Biologist

My journey into a research career began in fermentation biochemistry in an applied science department during the difficult post-World War II time in Japan. Subsequently, my desire to do research in basic science developed. I was fortunate to be a postdoctoral fellow in the United States during the early days of molecular biology. From 1957 to 1960, I worked with three pioneers of molecular biology, Sol Spiegelman, James Watson, and Seymour Benzer. These experiences helped me develop into a basic research scientist. My initial research projects at Osaka University, and subsequently at the University of Wisconsin, Madison, were on the mode of action of colicins as well as on mRNA and ribosomes. Following success in the reconstitution of ribosomal subunits, my efforts focused more on ribosomes, initially on the aspects of structure, function, and in vitro assembly, such as the construction of the 30S subunit assembly map. After this, my laboratory studied the regulation of the synthesis of ribosomes and ribosomal components in Escherichia coli. Our achievements included the discovery of translational feedback regulation of ribosomal protein synthesis and the identification of several repressor ribosomal proteins used in this regulation. In 1984, I moved to the University of California, Irvine, and initiated research on rRNA transcription by RNA polymerase I in the yeast Saccharomyces cerevisiae. The use of yeast genetics combined with biochemistry allowed us to identify genes uniquely involved in rRNA synthesis and to elucidate the mechanism of initiation of transcription. This essay is a reflection on my life as a research scientist.

Characterisation of a highly repeated DNA sequence from Mycobacterium bovis

We report characterisation of a novel repeat sequence from a Mycobacterium bovis genomic library. The highly repeated sequence belongs to a family consisting of a 24 base pair (bp) direct repeat (DR), that appears to be organized into clusters on the chromosome. We classify the 24-bp DR into the group of prokaryotic DNA repeats known as the interspersed repetitive sequence elements. The 24-bp DR will be of potential use as a DNA fingerprinting tool in epidemiological studies of M. bovis.

Restriction fragment length polymorphism analysis of Fusobacterium necrophorum using a novel repeat DNA sequence and a 16S rRNA gene probe

A repeated DNA sequence was isolated from Fusobacterium necrophorum biotype AB, strain FnS1. The repeated sequence shared considerable homology with the transposase gene from the Pseudomonas syringiae insertion sequence IS801. The repeat sequence was used together with a 16S ribosomal RNA gene probe to type F. necrophorum isolates using restriction fragment length polymorphisms. The probes revealed differences between several clinical isolates and will be useful tools to study the epidemiology of ovine foot abscess and other diseases caused by F. necrophorum.

Characterization of a major polymorphic tandem repeat in Mycobacterium tuberculosis and its potential use in the epidemiology of Mycobacterium kansasii and Mycobacterium gordonae

In this study, the occurrence of repeated DNA sequences in the chromosome of Mycobacterium tuberculosis was investigated systematically. By screening a M. tuberculosis lambda gt-11 gene library with labeled total chromosomal DNA, five strongly hybridizing recombinants were selected, and these contained DNA sequences that were present in multiple copies in the chromosome of M. tuberculosis. These recombinants all contained repeated sequences belonging to a single family of repetitive DNA, which shares homology with a previously described repeated sequence present in recombinant pPH7301. Sequences analysis of pPH7301 showed the presence of a 10-bp sequence that was tandemly repeated and invariably separated by 5-bp unique spacer sequences. Southern blot analysis revealed that the majority of the repeated DNA in M. tuberculosis is composed of this family of repetitive DNA. Because the 10-bp repeats are slightly heterogeneous in sequence, we designated this DNA as a major polymorphic tandem repeat, MPTR. The presence of this repeated sequence in various other mycobacterial species was investigated. Among the MPTR-containing mycobacterial species the chromosomal location of the repetitive DNA is highly variable. The potential use of this polymorphism in the epidemiology of mycobacterioses is discussed.

Mapping of insertion elements IS1, IS2 and IS3 on the Escherichia coli K-12 chromosome. Role of the insertion elements in formation of Hfrs and F' factors and in rearrangement of bacterial chromosomes

The chromosome of an Escherichia coli K-12 strain W3110 contains seven copies of insertion element IS1, 12 copies of IS2 and six copies of IS3. We determined the approximate locations of six copies of IS1 (named is1A to is1F), ten copies of IS2 (named is2A to is2J), and five copies of IS3 (named is3A to is3E) on the W3110 chromosome by plaque hybridization using the "mini-set" of the lambda phage library that includes 476 clones carrying chromosomal segments that cover the W3110 chromosome almost entirely. Cleavage maps of the W3110 chromosome and cleavage analysis of phage DNAs carrying insertion elements allowed us to assign more precise locations to most of the insertion elements and to determine their orientations. Insertion elements were distributed randomly along the W3110 chromosome in one or other orientation. Several of these were located at the same positions on the chromosome of another E. coli K-12 strain, JE5519, and they were assumed to be the original complement of insertion elements in E. coli K-12 wild-type. Locations and orientations of such insertion elements were correlated well with Hfr points of origin and with crossover points for excision of some F' factors derived from several Hfrs. Insertion elements may be involved also in rearrangement of bacterial chromosomes.

Age-related RNA polymerase I activity in isolated nuclei of PHA stimulated human lymphocytes

In order to extend to the immune system previous findings that there is an age-related loss of hybridizability of the genes for ribosomal RNA (rRNA) in several tissues of mice, dogs and humans, we have investigated the function of the genes for rRNA in human T lymphocytes. These cells were chosen because they show a substantial decline in function with age, greater than that of other components of the immune system. rRNA synthesis was determined by measuring tritiated-UTP incorporation into acid precipitable counts as a result of the action of RNA polymerase I in nuclei isolated from phytohemagglutinin (PHA) stimulated peripheral-blood lymphocytes from 24 young adult and old human donors. The number of PHA-responsive cells from each donor was determined by counting grains in autoradiographs after a pulse of tritiated-uridine had been administered to them. The aggregate PHA induced synthesis of rRNA in the cultures decreased as a function of the age of the donor. However, the number of PHA-responsive cells also dropped with age. When the data are normalized for the number of PHA-responsive cells in each culture, it appears that rRNA synthesis per PHA-responding cell does not significantly decline with age, even though there is a suggestion of a decrease after corrections are made. On the average, differences between individuals of the same age group were as great or greater than age-related differences.

recA-dependent recombination between rRNA operons generates type II F' plasmids

The formation of type II F' ilv cya metE plasmids from the Salmonella typhimurium Hfr strain SA722 occurs by general recombination between repeated rrn.

Chromosomal locations of the genes for rRNA in Escherichia coli K-12

Chromosomal locations of the seven rRNA operons in Escherichia coli K-12 were studied by digesting DNA from various merodiploid strains with SalI restriction enzyme followed by Southern gel analysis with 32P-labeled 23S rRNA as a probe. The seven unique SalI DNA fragments revealed in the autoradiograms were first correlated to the seven rRNA operons previously isolated as hybrid plasmids or transducing phages. The chromosomal locations of six (rrnA, B, C, D, E, and G) of the seven isolated operons were confirmed by increased gene dosage demonstrated in autoradiograms after Southern gel analysis of DNA from relevant merodiploid strains. The gene dosage analysis showed that the location of the remaining operon (now called rrnH) is between metD and proA. No evidence was obtained for the presence of rrnF, which was previously reported to map between aroB and malA. The chromosomal location of rrnH was confirmed by P1 transduction in the following way: a DNA fragment adjacent to rrnH was cloned into pBR322; the resulting hybrid plasmid was integrated at the homologous region of the chromosome of a polA mutant; and the ampicillin resistance marker originally carried by pBR322 was then used for mapping of the nearby rrnH by P1 transduction. A close linkage of rrnH to metD (about 60% cotransduction) was observed, and the data were consistent with the order metD-rrnH-proA. Thus, mapping of all seven rRNA operons has been completed. The present study has also determined the orientation of rrnG and rrnH and demonstrated that the direction of transcription of all the rRNA operons is identical to that of DNA replication.

Transposition of a chromosomal segment bounded by redundant rRNA genes into other rRNA genes in Escherichia coli

We have constructed several mutants of Escherichia coli which have the chromosomal segment between the directly repeated rrnB and rrnE genes deleted from the normal position and transposed into another one of the seven redundant rRNA genes. We have examples where the transposition has been into rrnC, rrnD, rrnG, and rrnH. Included in the evidence for each of these transpositions was the finding that each transposition specifically affected a different one of the seven BamHI-PstI restriction nuclease fragments known to correspond to the seven rrn genes. The transposition mutants were generally healthy, but sensitive mixed-growth experiments revealed that most of them grew somewhat more slowly than the parental control in rich medium. The maximal detrimental effect was a 4 to 5% reduction in growth rate when the transposition of the rrnB-rrnE segment was into rrnG. We have found that a rrnF gene, reported by others to be linked to malA, does not exist in our standard strain, a derivative of Cavalli Hfr. Instead of rrnF, we identified a new rrn gene, rrnH, which mapped near min 5.

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).

Deletion of a ribosomal ribonucleic acid operon in Escherichia coli

One (rrnE) of the seven operons which codes for ribosomal ribonucleic acid in Escherichia coli was deleted. No significant change in phenotype was observed even under maximum laboratory growth conditions.

Involvement of ribosomal ribonucleic acid operons in Salmonella typhimurium chromosomal rearrangements

As part of our efforts to understand factors influencing chromosomal organization and rearrangements, we studied a family of Salmonella typhimurium tandum duplication mutants. We found that the duplications were originally generated by unequal recombination between pairs of similarly oriented ribosomal ribonucleic acid operons (rrn). This demonstration involved the physical isolation of the duplicated material as circular deoxyribonucleic acid excised from the duplication. The four rrn operons involved embraced the ilv pur D segment of the chromosome and occurred at positions closely analogous to those previously observed for Escherichia coli. The interval between rrnC and rrnA of S. typhimurium was similar in size to that of E. coli (43 versus 39 kilobases), as was the interval between rrnB and rrnE (94 versus 91 kilobases). The rrnA-to-rrnB interval of S. typhimurium, however, was 155 kilobases, substantially greater than the 126 kilobases observed for E. coli.

Organization of the nuclear ribosomal DNA of Chlamydomonas reinhardii

Hybridization of cytoplasmic ribosomal RNA (rRNA) to restriction endonuclease digests of nuclear DNA of Chlamydomonas reinhardii reveals two BamHI ribosomal fragments of 2.95 and 2.35 x 10(6) d and two SalI ribosomal fragments of 3.8 and 1.5 x 10(6) d. The ribosomal DNA (rDNA) units 5.3 x 10(6) d in size, appear to be homogeneous since no hybridization of rDNA to other nuclear DNA fragments can be detected. The two BamHI and SalI ribosomal fragments have been cloned and a restriction map of the ribosomal unit has been established. The location of the 25S, 18S and 5.8S rRNA genes has been determined by hybridizing the rRNAs to digests of the ribosomal fragments and by observing RNA/DNA duplexes in the electron microscope. The data also indicate that the rDNA units are arranged in tandem arrays. The 5S rRNA genes are not closely located to the 25S and 18S rRNA genes since they are not contained within the nuclear rDNA unit. In addition no sequence homology is detectable between the nuclear and chloroplast rDNA units of C. reinhardii.

DNA sequences of promoter regions for rRNA operons rrnE and rrnA in E. coli

The nucleotide sequences have been determined for the promoter regions of two ribosomal RNA operons, rrnA and rrnE, in E. coli. The sequences cover the two in vitro transcription start sites identified for each operon (Gilbert, der Boer and Nomura, 1979). The first two start sites are 283 and 291 bp preceding the mature 16S rRNA (m16S rNA) coding regions for rrnE and rrnA, respectively; the second start sites are 174 and 174 +/- 1 bp preceding the m16S rRNA coding regions for rrnE and rrnA, respectively. Each of these start sites has an identifiable "Pribnow box" sequence 6-7 bp upstream from the start site. The nucleotide sequences of the two operons have nearly complete homology from the m16S rRNA coding regions to positions 145 bp upstream from those regions, and at the regions surrounding the Pribnow boxes preceding the first start sites. The DNA sequences indicate that the RNAs transcribed from the first start sites of rrnE and rrnA are quite different in their first 150 nucleotides. These heterogeneous regions, however, precede the RNAse III cleavage sites (deduced previously by Young and Steitz, 1978), and the "precursor 16S rRNA" molecules are largely homogeneous. The nucleotide sequences of the promoter regions of the two rRNA operons are also compared with those or rrnD and rrnX, determined by Young and Steitz (1979), and some common features are discussed.

The structure of the phi 80d3 ilv+ Su+7 transducing phage and the origin of its Su+7 tRNA-gene containing fragment

The Bam HI, XhoI, and EcoRI sites of the transducing phage phi 80d3Su+7ilv+ are located. The 1.2 x 10(6) MD EcoRI fragment which, when cloned, contains tRNAAsp and expresses the mutant tRNATry gene, Su+7, and which also relaxes control of stable RNA synthesis is found immediately adjacent to the rrnC region. Its tRNA genes, tRNAAsp and tRNATry, are transcribed in the same direction as the ribosomal RNA genes, though no mature rRNA subsequences are on the fragment. This fragment also exists as such in another F-prime factor derived from the same Hfr host, and therefore presumably also in the Hfr chromosome itself. It is composed of about half ordinary chromosomal and half F DNA sequences, the latter from the gamma-delta region of F. The advantages of a novel mapping method used are discussed.

A ribosomal RNA gene, rrnC, of Escherichia coli, mapped by specialized transducing lambdadilv and lambda drbs phages

Specialized transducing phages carrying segments of the Escherichia coli chromosome from the rbs-ilv region including rrn genes have been isolated. These phages carry rrn transcription units coding for 16S and 23S rRNA with the direction of transcription clockwise towards the ilv operon. While one of the phages (lambdad279rbs) appears to carry the genuine rrn gene, denoted rrnC, located between rbs and ilv at 82 min on the E. coli chromosome another one isolated as an ilv transducing phage, lambda5ilv, carries a hybrid rrn gene, denoted rrnX, which has originated from a recombinational cross-over between the rrnC and one of the other rrn genes.

Structure, function, and regulation of Escherichia coli rRNA in Proteus mirabilis

Escherichia coli rRNA genes have been introduced into Proteus mirabilis on an F-prime factor (F'14). A portion of the ribosomes in the resulting merodiploid consist of E. coli rRNA and P. mirabilis ribosomal proteins. These ribosomes are structurally similar to normal P. mirabilis or E. coli ribosomes and exhibit many or all of the functional properties of normal ribosomes. The accumulation of E. coli rRNA in the merodiploid is regulated in a way similar to the the regulation of P. mirabilis rRNA.

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.

Characterization of hybrid plasmids carrying individual ribosomal ribonucleic acid transcription units of Escherichia coli

We have screened the strains with ColE1 hybrid plasmids constructed by Clarke and Carbon (Cell 9:91-99, 1976) for the presence of ribosomal ribonucleic acid (rRNA) genes on the plasmids and identified 16 strains whose plasmids carry rRNA genes. The structures of these 16 plasmids were compared by heteroduplex analysis, and the plasmids were classified into six groups on the basis of their chromosomal origins. Homology with known transducing-phage deoxyribonucleic acids and genetic mapping have assigned locations on the Escherichia coli chromosome to three of the six groups. These are rrnB near rif at 88 min, rrnC near ilvE at 83 min, and rrnD near aroE at 71 min. A fourth group is probably rrnA at 85 min (T. Ikemura and M. Nomura, Cell, 11:779-793, 1977). We conclude that the minimum number of rRNA transcription units per haploid chromosomes is seven, that is, the six groups identified in this work plus a known operon (rrnE near metA at 89 min) that we failed to find among the hybrid plasmids. This heteroduplex analysis also suggests that there are only two kinds of rRNA operons with respect to their spacer region; three of the six rRNA operon groups studied here have one kind, whereas the remaining three have the other kind.

Linkage of 5S RNA and 16S+23S RNA genes on the E. coli chromosome

Episomes carrying limited regions of the chromosome where 5S RNA genes have previously been located are described. The DNA purified from each of these episomes contains one gene per molecule for each of the three ribosomal RNA species as shown by hybridization experiments.

Evolutionary drift of the argF and argl genes. Coding for isoenzyme forms of ornithine transcarbamylase in E. coli K12

Considerable genetic drift has occurred during the evolution of the two genes, argF and argl, which individually code for isoenzyme forms of ornithine transcarbamylase in E. coli K12. The use of the experimental protocol described in this work established that between 25-40% of the base pairs in the genes argF and argl have changed since they diverged from a hypothetical ancestral gene. The extent of divergence of the genes was determined by mRNA-DNA hybridization utilizing arginine transducing DNA as a hybridization probe and mRNA prepared in vivo from appropriate bacterial strains and with mRNA synthesized in vitro using template DNA isolated from the specialized transducing phages gammacI857dargl and phi80dargF.

Transcription of Escherichia coli ribosomal DNA in Proteus mirabilis

Transcription of Escherichia coli ribosomal DNA introduced into Proteus mirabilis on F14 is described. We have developed an assay for E. coli coded ribosomal RNA involving fingerprinting of ribonuclease T1 digests of RNA isolated from ribosomal subunits. Sequence differences in the ribosomal RNA of the two species have allowed us to detect E. coli coded 16S, 23S, and 5S ribosomal RNA in ribosomal subunits of the E. coli-P. mirabilis hybrid. The proportion of E. coli coded rRNA in the hybrid is found at a level which is compatible with the number of E. coli (and P. mirabilis) ribosomal DNA sequences. The resulting ribosomal RNA appears in ribosomes in a form which indicates extensive compatibility of E. coli coded ribosomal RNA with P. mirabilis ribosomal proteins and maturational factors.

A proposal for a uniform nomenclature for the genetics of bacterial protein synthesis

A new genetic nomenclature for the macromolecules involved in bacterial protein synthesis is proposed and explained. Genes for ribosomal proteins are designated rsp, rpl and rpm while genes for ribosomal RNAs are rrs and rrl. Protein synthesis factors and ribosome assembly and modification activities are also consistantly named.

A ribosomal RNA gene of Escherichia coli (rrnD) on lamnda daro E specialized transducing phages

Lambda-transducing phages carrying segments of the Escherichia coli chromosome in the aroE-trkA region have been isolated and shown by hybridization to carry an rRNA gene (rrnD). The most likely gene order is trkA aroE rrnD. The EcoRI and SmaI endonuclease cutting pattern of the rrnD gene is identical with the one of rrnB, differented from rrnC.

Stability of "spacer" sequences of pre-ribosomal RNA in Escherichia coli

"SPACER" SEQUENCES OF AN RRNA gene transcript were detected with high efficiency by hybridization with DNA of the specilized transducing phase phi80rrn. Hybridization-competition studies revealed that 20 to 23% of the 30S precursor rRNA, obtained from E. coli mutant strain AB301/105, consist of "spacer" sequences. The "spacer" sequences formed hybrids with E. coli DNA, but not with Vibrio DNA. Experiments with RNA labeling in the presence of rifampicin showed that more than 80% of the spacer sequences arrive in full-length 30S pre rRNA chains before any cleavage of the RNA occurs. The hybridization assays also permitted the detection of "spacer" sequences in pulse-labeled rRNA of wild-type cells, in which the 30S pre-rRNA is already cleaved during its synthesis. Many of these "spacer" sequences degraded to alcohol-soluble materials with a half-life time of 1.2 min. The half-life was not lengthened by the treatment of cells with chloramphenicol, which stabilizes bulk mRNA. However, unstable "spacer" sequences transcribed in cells deficient in RNase III exhibited slower degradation, with a half-life time of about 9 min, whereas the cleavage of 30S pre-rRNA to smaller RNA species occurred with a half-life of about 3 min. These results are consistent with the notion that a rate-limiting action of RNase III in the initial attack leads to degradation of "spacer" sequences in rRNA gene transcript; and that degradation is not at all connected with ribosome translocation.

Transfer RNA genes between 16S and 23S rRNA genes in rRNA transcription units of E. coli

We have identified genes for tRNAGLU/2 on the transducing phages o80d3ilvsu7+ (see Ohtsubo et al., 1974) and lambdarifd18 (Kirschbaum and Konrad, 1973), and a gene for tRNAlle/1 on the transducing phage o80rifr (Konrad, Kirschbaum, and Austin, 1973). All these phages have previously been shown to carry genes for rRNA (Ohtsubo et al., 1974; Lindahl et al., 1975; Jaskunas et al., 1975a). We have analyzed the position of these tRNA genes by hybridizing purified RNAs to restriction fragments of the phage DNA. The tRNA genes are located inside the rRNA transcription unit in the spacer region between the 16S and 23S rRNA genes.

Direct selection of mutants restricting efficiency of suppression and misreading levels in E. coli B

We describe a method for the direct selection of E. coli mutants restricting efficiency of suppression and misreading levels using a T4-coded nonsense suppressor. One mutant isolated has the phenotype expected for a restrictive mutant and may be ribosomal. Other possibilities are discussed.

Cluster of genes in Escherichia coli for ribosomal proteins, ribosomal RNA, and RNA polymerase subunits

The transducing phage lambdarifd18 isolated by Kirschbaum and Konrad [(1973 J. Bacteriol. 116, 517-526] was found to carry structural genes for several 50S ribosomal proteins and 16S and 23S rRNA. It has previously been demonstrated [Kirschbaum & Scaife (1974) Mol. Gen. Genet. 132, 193-201] that this phage carries genes for the DNA-dependent RNA polymerase (nucleosidetriphosphate:RNA nucleotidyltransferase; EC 2.7.7.6) subunits beta and beta'. Thus, the region of the E. coli chromosome carried by lambdarifd18 contains a cluster of genes essential for transcription and translation.

Electron microscopic heteroduplex studies of sequence relations among plasmids of Escherichia coli: structure of F13 and related F-primes

The structure of F13, a plasmid containing lac, purE, and proC, has been determined by heteroduplex analysis. As expected for an F-prime formed by a type II excision event, it contains all the sequences of F plus a large segment of Escherichia coli chromosomal deoxyribonucleic acid. There is a sequence of F with coordinates 16.3-17.6F which has been shown in other studies to be the insertion sequence IS2. This IS2 occurs twice on F13, once at each of the two junctions of F deoxyribonucleic acid with chromosomal deoxyribonucleic acid. The sequence alpha beta which occurs twice on F with coordinates 93.2-94.5/OF and 13.7-15.0F occurs an additional three times, twice in an inverted order relative to the alpha beta sequences of F, on the chromosomal sequences of F13. The structures of the plasmids F13-4 and F210 have been determined. The common sequences of F13 with F152-1 (a derivative of F152, the classical F2gal) and with F13-4 and F210 have been mapped. These results partially map lac, proC, tsx, and purE on F13. On the basis of all of these results, it is proposed that Hfr 13 (the parent of F13) was formed by recirpocal recombination between IS2 on F and an IS2 resident at a point between lac and proC on the chromosome of the F+ parent of Hfr 13. It is proposed that this IS2 and the several alpha beta sequences on the chromosomal part of F13 are hot spots for recombination with F, i.e., for Hfr formation. The point of origin and direction of transfer of many Hfr's can be explained by this hypothesis. In particular, the sequence relations of F42-1 (Flac) and of F152-1 (F 2gal) with F13 are completely consistent with this model.