Fine mapping of the ribosomal RNA genes of HeLa cell mitochondrial DNA

A fine mapping study of the ribosomal RNA region of HeLa cell mitochondrial DNA has been carried out by using as an approach the protection by hybridized 12 S and 16 S rRNA of the complementary sequences in DNA against digestion with the single strand-specific Aspergillus nuclease S₁ or Escherichia coli exonuclease VII. No inserts have been detected in the main body of the 12 S and 16 S rRNA cistrons, in contrast to the situation described in the large mitochondrial ribosomal RNA gene of some strains of yeast and of Neurospora crassa. Furthermore, it has been possible to assign more precisely than previously the positions of the 5′ and 3′-ends of the 12 S rRNA and 16 S rRNA genes in the HpaII restriction map of HeLa cell mitochondrial DNA.     

Restriction endonuclease mapping of a plasmid that confers oncogenicity upon Agrobacterium tumefaciens strain B6-806

The 26 SmaI digest fragments of pTi-B6-806 plasmid have a total molecular weight (121 × 10⁶) which accounts for the size of the plasmid as determined by contour length measurements. We have determined the physical arrangement of all SmaI digest fragments with reference to HpaI digest fragments. Hybridization of individual labeled SmaI digest fragments to HpaI digest fragments (cellulose nitrate transfers) allowed the latter to be ordered and located the SmaI boundary fragments. Recleavage of isolated HpaI fragments with SmaI revealed the SmaI fragments located within each HpaI fragment. The order of these internal SmaI fragments within a given HpaI fragment was determined by partial digestion of the latter with SmaI and hybridization of the resulting fragments with SmaI boundary fragments. From the sizes of partial digest fragments containing each boundary, the order of occurrence of SmaI fragments from each end was deduced. The complete map of the SmaI digest fragments is presented. The map of the HpaI digest fragments is presented with the following ambiguity: The order of fragments 12, 15, and 16, which map within SmaI fragment 1, was not determined. The SmaI digest fragments that contain DNA sequences transferred to plant cells during tumor induction, fragments 3b and 10c, were found to be contiguous on the physical map.     

Precise localization of the origin of replication in a physical map of HeLa cell mitochondrial DNA and isolation of a small fragment that contains it

The precise positions of the origin of replication³ and of the D-loop within the HpaII restriction map of HeLa cell mitochondrial DNA have been investigated. For this purpose, 7 S DNA, which is the heavy-chain initiation sequence, was used as a template for fragment-primed DNA synthesis by Escherichia coli DNA polymerase I. The results indicate clearly that the origin of replication lies in HpaII fragment 8 at about 80 base-pairs from the border with fragment 17, and that the D-loop region extends from this site, through fragment 17, to a position in fragment 10 which is about 365 base-pairs from the border with fragment 17. Sequential digestion of fragment 8 with HaeIII enzyme has allowed the isolation of a subfragment, about 200 base-pairs long, that contains the origin of replication.     

Physical mapping of plasmid pDB101: A potential vector plasmid for molecular cloning in streptococci

A physical map of the streptococcal macrolides, lincomycin, and streptogramin B (MLS) resistance plasmid pDB101 was constructed using six different restriction endonucleases. Ten recognition sites were found for HindIII, seven for HindII, eight for HaeII, and one each for EcoRI, HpaII, and KpnI. The localization of the restriction cleavage sites was determined by double and triple digestions of the plasmid DNA or sequential digestions of partial cleavage products and isolated restriction fragments, and all sites were aligned with a single EcoRI reference site. Plasmid pDB101 meets all requirements essential for a potential molecular cloning vehicle in streptococci; i.e., single restriction sites, a MLS selection marker, and a multiple plasmid copy number. The vector plasmid described here makes it possible to clone selectively any fragment of DNA cleaved with EcoRI, HpaII, or KpnI, or since the sites are close to each other in map position, any combination of two of these restriction enzymes.     

HindII, HindIII,and HpaI restriction fragment maps of the left arm of bacteriophage λ DNA

The sites on the left arm of bacteriophage λ DNA cleaved by the restriction endonucleases isolated from Hemophilus influenzae strain Rc (HincII) and Rd (HindII+III), and Hemophilus parainfluenzae (HpaI) were localized on the λ physical map, and the fragments resulting from these cleavages were identified by gel electrophoresis. The restriction sites within the b2 region of λ were mapped by analysis of the digestion profiles of deletion and substitution derivatives of λ, as well as by digesting individual fragments produced by one restriction endonuclease with another restriction endonuclease. The restriction sites on the λ genome between the left vegetative end and the b2 region were mapped entirely by successive digestion experiments. The restriction fragment map for the right arm of λ may be found in the accompanying paper (Robinson and Landy, 1977).     

Fine structure of polyoma virus DNA.

A fine structure map of polyoma DNA has been made based on cleavage with a number of restriction endonucleases (including HaeII and III, BamI, HindII and III, BumI, HpaII, and in part, HphI) and depurination of wild-type DNA, the eight HpaII restriction fragments and some HaeIII fragments. This analysis has made possible some correlation with simian virus 40 DNA, and has facilitated detailed examination of various polyoma strains and variants. Sequences from the region of the origin of DNA replication have been examined.     

Physical mapping of bacteriophage lambda DNA with restriction endonuclease HpaI

The restriction endonuclease from Haemophilus parainfluenzae, endoR·HpaI cleaves λcI857s7 DNA into 14 fragments. The sizes of these fragments were determined and a physical map was constructed. The ordering of the fragments was carried out using different deletion and substitution mutants of λ phage, double cleavages with another restriction enzyme, endoR·BamHI, and partial protection of individual HpaI recognition sites by the antibiotics distamycin A and actinomycin D. HpaI produces fragments from the left arm of the λ DNA genome, which may help in investigating the structure and function of this part of the phage.     

Isolation,physical map and gene map of mitochondrial DNA from the cryptomonad Pyrenomonas salina

Mitochondrial DNA (mtDNA) from the cryptomonad Pyrenomonas salina was isolated by CsCl-buoyant density centrifugation of whole-cell DNA in the presence of Hoechst dye 33258. mtDNA consists of circular molecules about 47 kb in size as estimated from restriction enzyme analysis. A physical map for six restriction enzymes (Bam HI, Bge I, Eco RI, Pst I, Sac I and Sac I) has been constructed. Genes coding for the small subunit of rRNA, cytochrome oxidase subunits I and II, and apocytochrome b were localized on this map using Southern blot hybridization with heterologous gene probes from Oenothera. Genes for 5S rRNA and NADH dehydrogenase subunit 5 are absent from P. salina mtDNA. The mitochondrial genome, being the first analysed to this extent in chromophytic algae, should be valuable for taxonomic and phylogenetic studies.     

Molecular cloning and physical map of bacteriophage PM2 DNA

The entire genome and the DNA fragments of the lipid-containing bacteriophage pM2 were cloned in the pBR322 plasmid vector. A physical map including the sites for the following restriction enzymes was obtained: HpaII, HaeIII, TthI, Sau96I, AvaII, PstI, BstNI, AccI, HincII, HpaI and HindIII. No restriction sites on PM2 DNA were found for BalI, BamHI, BclI, BglI, BglII, BstEII, KpnI, PvuII, SacI, SalI, Sau3A, XbaI and XhoI.     

A physical map of plasmid pDU1 from the cyanobacterium Nostoc PCC 7524

Nostoc 7524 contains three different plasmids of molecular weight, 4, 8, and 28 Mdal. The smallest plasmid, designated pDU1, because of its size and ease of isolation, may prove to be useful as a cloning vector. Plasmid pDU1 was incubated separately with 26 different restriction enzymes and only 8 of the enzymes tested cut pDU1. A composite restriction enzyme map consisting of a total of 17 restriction sites was constructed for BglI, HindIII, HpaI, and XbaI. The sites of restriction enzyme cleavage were determined by single, double, and partial digests of plasmid DNA or redigestion of isolated restriction fragments. All the restriction sites were aligned relative to the single BglI site. This is the first restriction enzyme map of a plasmid from a filamentous cyanobacterium.     

Unmethylated regions in the intergenic spacer of maize and teosinte ribosomal RNA genes

The restriction endonucleases Hpa II and Msp I were used to examine cytosine methylation in the ribosomal RNA genes (rDNA) of inbred lines of maize and species of teosinte. In all of the rDNAs examined, Msp I (not sensitive to mCpG) digestion yielded a distribution of lower molecular weight fragments indicative of multiple recognition sites. The majority of the rDNA arrays in an individual were inaccessible to Hpa II (sensitive to mCpG) cleavage, but a significant fraction (10–25%) was cleaved at least once by Hpa II into repeat unit length fragments (9.1 kbp). In some maize inbred lines, one or two additional fragment populations (less than 9.1 kbp in length) were also produced by Hpa II digestion. All of the unmethylated Hpa II sites mapped to the intergenic spacer (IGS), and the major unmethylated site was located approximately 800 bp 5 to the start of the 18S RNA coding sequence. An Eco RI polymorphism, present in the 26S gene of certain inbred lines and hybrids, was utilized to investigate the organization of unmethylated repeat units in the rDNA array. In double digest experiments with Hpa II/Eco RI, the fragments from repeat units with two Eco RI sites were sensitive to Hpa II digestion, whereas, the fragments from repeat units with a single Eco RI site were almost completely resistant to Hpa II digestion. Similar digestion patterns were also observed in Eco RII (sensitive to mCNG)/Eco RI digests. These results suggest that unmethylated and Eco RI polymorphic sites occur in the same repeat units.     

Fine structure of the 21S ribosomal RNA region on yeast mitochondria DNA. I. Construction of the physical map and localization of the cistron for the 21S mitochondrial ribosomal RNA.

1. We have used restriction enzyme analysis of petite mtDNAs to construct a detailed physical map of the 21S region on the mtDNA of the Saccharomyces cerevisiae strain JS1-3D. The map covers a segment of about 20,000 bp, on which the recognition sites of the enzymes HapII, HindII, HindIII, Sa1I, XhoI and HhaI have been localized (22 sites in total). This map has been checked in various ways against the independently constructed overall physical map of the mtDNA of strain JS1-3D. In addition, we have constructed a physical map with a resolution of about 200 bp of a HapII fragment of 1850 bp long, which carries the loci omega, RIB-1 and probably RIB-2. 2. The 21S rRNA hybridizes with the five adjacent HindII + III fragments TD9, DT19, TD15, DT14 and TT1, which lie in that order on the physical map of the 21S region. Of these, the two non-adjacent fragments TD9 and DT14 show a much stronger hybridization with 21S rRNA than DT19, TD15, and TT1. 3. The fragment DD5 (= DT19 + TD15) and part of DT14 belong to a sequence of about 1000 bp, which is absent from Saccharomyces carlsbergensis mtDNA. Although DD5 and DT14 show (very weak, respectively stronger) hybridization with 21S rRNA, the 1000 bp insert probably does not code for the 21S rRNA: the 21S rRNA of S. carlsbergensis comigrates with the 21S rRNA of JS1-3D on polyacrylamide gels under denaturing conditions. 4. Fragment DT14 hybridizes with the HindII + III fragment TD9, which shows the strongest hybridization with 21S rRNA. The presence of these sequence homologies has hampered the precise mapping of the 21S rRNA cistron. Our results are compatible, however, with the hypothesis that the sequences, coding for 21S rRNA, are located on HindII + III fragments that are not adjacent on JS1-3D mtDNA, namely TD9, DT14 and TT1.     

A physical map of belomycin-specific fragmentation sites on PM2 bacteriophage DNA

Bleomycin treatment of PM2 DNA results in fragmentation of the genome at several specific sites. Application of restriction endonuclease digestion followed by bleomycin treatment has provided the basis for constructing a physical map of bleomycin fragmentation sites. Eleven sites have been located on the physical map relative toHpa II,Pst I, andHindIII cleavage sites. The fragmentation sites are not clustered in a particular region of the PM2 genome but 3 of the 11 sites do occur between theHpa II andPst I cleavage sites, a segment of DNA which comprises 14% of the PM2 DNA length.     

Pulse-label analysis and mapping of the two terminal regions of asynchronous complementary strand replication of mitochondrial DNA in transformed hamster cells

In vivo pulse-chase radioactive labeling studies were performed to localize within the physical map of $\text{C}{}_{13}\text{B}{}_4$ hamster mtDNA² the two terminal regions of heavy and light complementary strand synthesis. These terminal segments have been defined operationally as that region on the H- and L-strand that is synthesized last. mtDNA of monolayer cultures was pulsed with [³H]thymidine for a minimum period of 10 minutes, which is about one-tenth of one round of mtDNA synthesis, followed by chase periods of up to 120 minutes. The properties of the labeled closed circular replicative intermediates E-mtDNA, C-mtDNA and D-mtDNA were analyzed in $\text{CsCl}\text{PrI}{}_2$ gradients and in neutral sucrose velocity and alkaline CsCl gradients. Both terminally labeled α and β daughter molecules were found to pass through the E-mtDNA stage. Sensitivity of $\text{C}{}_{13}\text{B}{}_4$ mtDNA to alkali and ribonuclease A indicated the presence of covalently linked ribonucleotides. The distribution (specific activity) of pulse-chase radioactivity relative to uniform label was followed in electrophoretically separated HpaII + HinIII and HpaI restriction fragments (freed of 7 S initiation sequences) and corrected for thymine content. The strand specificity of the pulse-label was determined by hybridization of restriction fragments with H- and L-strands of mtDNA. The kinetic data agree precisely with electron microscopic determinations of H- and L-strand origins at respective genome positions of 0 and 67 ± 3, which are located on HpaII + HindIII fragments 9 and 6, respectively (Nass, 1980). The two terminal regions are within the predicted genome sector between about 67 and 100/0 map units; the highest terminal pulse-chase radioactivity extends within 5 to 15% of the genome's length behind each origin. The kinetics of early labeling events were found to differ at the two termini. The evidence indicates that the majority of L-strand initiation/termination sites are in the region near map position 67 ± 3, and confirms the highly asynchronous replication mechanism of this DNA.     

RFLP analysis of the PCR-amplified 28S rDNA inRhizoctonia solani

RFLP analyses of a portion of the 28S rDNA gene region were conducted by using four restriction endonucleases for 57 isolates of 13 intraspecific groups (ISGs) representing 7 anastomosis groups (AGs) ofRhizoctonia solani. Variations in the PCR-amplified rDNA products and the polymorphisms on digestion with restriction enzymes (BamHI,HaeIII,HhaI andHpaII) were observed among three AGs, AG 1, 2 and 4. These differences were also conserved among some ISGs of AG 1 and AG 2. Among ISGs of AG 1, the pattern of rDNA fragments of AG 1-IA obtained by digestion withHpaII was significantly different from those of AG 1-IB and IC. Such difference in the fragment pattern was also observed among AG 2-1, 2-2 IIIB and 2-2 IV by the digestion withHhaI andHpaII. A dendrogram derived from the restriction enzyme data showed that ISGs from AG 1 and AG 2 can each be subdivided into distinct groups, those are distantly related to the majority isolates of the other AGs.     

Restriction map of Chinese hamster mitochondrial DNA containing replication coordinates: comparison with Syrian hamster mitochondrial genome

A precise physical map, containing the structurally and operationally defined D-loop origin, terminal region, and direction of heavy-strand replication, has been constructed for mitochondrial DNA (mtDNA) from ovary (CHO-KI) and lung cells of Chinese hamster (Cricetulus griseus 2 N = 22), and compared with our previously established genome coordinates for mtDNA from Syrian hamster ( Mesocricetus auratus 2 N = 44). All four HpaI sites in Cricetulus are conserved in Mesocricetus (8 sites). Extensive variation exists for hexanucleotides cleaved by EcoRI HindIII PstI. KpnI and BamHI. Sequence divergence between Chinese and Syrian hamster mtDNAs, as reflected from analysis of the mapped recognition sites for these six endonucleases, is estimated as 5–9% base substitutions. mtDNAs from both hamster and several other mammalian species contain a commonly conserved HpaI site in the region of light strand initiation.     

Combined Physical and Genetic Map of the Pseudomonas putida KT2440 Chromosome

A combined physical and genetic map of the Pseudomonas putida KT2440 genome was constructed from data obtained by pulsed-field gel electrophoresis techniques (PFGE) and Southern hybridization. Circular genome size was estimated at 6.0 Mb by adding the sizes of 19 SwaI, 9 PmeI, 6 PacI, and 6 I-CeuI fragments. A complete physical map was achieved by combining the results of (i) analysis of PFGE of the DNA fragments resulting from digestion of the whole genome with PmeI, SwaI, I-CeuI, and PacI as well as double digestion with combinations of these enzymes and (ii) Southern hybridization analysis of the whole wild-type genome digested with different enzymes and hybridized against a series of probes obtained as cloned genes from different pseudomonads of rRNA group I and Escherichia coli, as P. putida DNA obtained by PCR amplification based on sequences deposited at the GenBank database, and by labeling of macrorestriction fragments of the P. putida genome eluted from agarose gels. As an alternative, 10 random mini-Tn5-Km mutants of P. putida KT2440 were used as a source of DNA, and the band carrying the mini-Tn5 in each mutant was identified after PFGE of a series of complete chromosomal digestions and hybridization with the kanamycin resistance gene of the mini-Tn5 as a probe. We established a circular genome map with an average resolution of 160 kb. Among the 63 genes located on the genetic map were key markers such as oriC, 6 rrn loci (rnnA to -F), recA, ftsZ, rpoS, rpoD, rpoN, and gyrB; auxotrophic markers; and catabolic genes for the metabolism of aromatic compounds. The genetic map of P. putida KT2440 was compared to those of Pseudomonas aeruginosa PAO1 and Pseudomonas fluorescens SBW25. The chromosomal backbone revealed some similarity in gene clustering among the three pseudomonads but differences in physical organization, probably as a result of intraspecific rearrangements.     

Physical map of DNA from a new cauliflower mosaic virus strain

The restriction enzymes AluI, BamHI, BglII, EcoRI, HindIII, and SalI have been used to characterize and map a new cauliflower mosaic virus strain (Cabb-S). These fragments have been ordered by examining their overlapping regions after double enzymatic digestion. The single SalI cleavage site was chosen as the point of origin. We compare this strain with those already described.