Electron microscope heteroduplex studies of sequence relations among plasmids of Escherichia coli: VIII. The structure of bacteriophage φ80d3ilv+su+7, including the mapping of the ribosomal RNA genes

The sequences present on the DNA of the transducing phage, φ80d₃ilv⁺su⁺7 have been mapped by electron microscope heteroduplex methods. In addition to some φ80 sequences, the phage DNA contains sequences from the extreme counterclockwise region and from the extreme clockwise region of the bacterial chromosomal part of F14. The former includes ilv, the latter a 16 S and a 23 S ribosomal RNA gene. These two regions are joined on the transducing phage DNA by the 2.8 to 8.5F sequence.By direct observation of the structure of the rRNA/DNA hybrids, the 16 S and 23 S genes have lengths of 1.38 ± 0.14 and 2.66 ± 0.17 kilobases. They are separated by a spacer of length 0.57 ± 0.13 kilobases.The rRNA genes (rrn) of φ80d₃ilv⁺su⁺7 are derived from and are identical with the rrnB gene set of F14. In heteroduplexes between the rrnB gene set of φ80d₃ilv⁺su⁺7, and the rrnA gene set of F14 we observe that there is a region of non-homology of length 0.25 ± 0.06 kilobases within the spacer sequence. This confirms observations in the preceding paper on the structure of out-of-register duplexes of the two rRNA gene sets of F14.A model for the integration and excision events involved in the formation of φ80d₃ilv⁺su⁺ 7 from φ80dmet(K) is proposed.     

A technique for mapping transfer RNA genes by electron microscopy of hybrids of ferritin-labeled transfer RNA and DNA: the phi-80hpsu+3-system

A method for mapping transfer RNA genes on single strands of DNA is described. tRNA is covalently coupled to the electron-opaque label, ferritin. The ferritinlabeled tRNA, Fer-tRNA, is hybridized to a single strand of DNA, or to a single- strand region of a DNA in a heteroduplex. The sites where the Fer-RNA binds to the complementary sequence on the DNA are then mapped by electron microscopy. Several alternative coupling procedures are described (see Fig. 1). In HzI a — COCH₂Br group is attached to ferritin by acylation. 3'-Oxidized tRNA is joined to HSRCONHNH₂ by hydrazone formation. Ferritin is then coupled to tRNA by reaction of the CBr and SH bonds. In the BI procedure a lysine amino group of ferritin is coupled by Schiff base formation with 3'-oxidized RNA. The conjugate is stabilized by borohydride reduction. In the BII procedure, a —COCH₂Br group is attached to ferritin. (H₂NCH₂CH₂S—)₂ is coupled to oxidized tRNA by Schiff base formation and borohydride reduction. An SH group is exposed by reduction. This HS-tRNA is coupled to a —COCH₂Br group attached to ferritin. All the procedures work but BII is recommended. Methods for purifying the Fer-tRNA and the Fer-tRNA-DNA hybrid are described. For the transducing phages, φ80hpsu^+,?_III and φ80hpsu^?_III, the DNA molecules each carry a piece of bacterial DNA of length 0·066±0·007 λ unit (3100 nucleotide pairs; we find the length of λ is 8·99 φX174 units) replacing a piece of phage DNA of φ80h of length 0·045±0·005 λ unit. The left junction of this bacterial DNA with phage DNA (referred to as P-B′) is at or close to the att site. The two tandem tyrosine genes of φ80hpsu^+,?_III and the single tRNA gene of φ80hpsu^?_III have been mapped at a position 1100 nucleotides to the right of the left (P·B′) junction of phage DNA and bacterial DNA, by hybridizing Escherichia coli Fer-tRNA to φ80hpsu_III/φ80h heteroduplexes. The separation of the two ferritin labels in φ80hpsu^+,?_III hybrids gives 140±20 nucleotides as the size of a single tyrosine tRNA gene.     

Excision and duplication of su3+-transducing fragments carried by bacteriophage φ80: II. Red- or rec-dependent excision and duplication

During vegetative growth φ80)sus2psu3⁺ and φ80int3sus2psu3⁺ segregate su3^? progeny phages, which have lost suppressor activity, at high frequency, even in the absence of the host Rec system. DNA molecules of the su3^? segregants were equivalent to φ80 DNA, as determined by heteroduplex analysis. Loss of suppressor activity is ascribed either to unequal intermolecular crossing-over or to excision by internal recombination between two homologous regions of the phage genome which bracket the bacterial segment containing the su3⁺ gene. To investigate the recombination system acting on the segregation of su3^? phages, a fec^?int^? deletion derivative of φ80sus2psu3⁺, φ80Δ4sus2psu3⁺, has been isolated that is stable even after several cycles of growth in the absence of the host Rec system. However, segregation of su3^? phages from φ80Δ4sus2psu3⁺ was observed when it was complemented in vivo with the hybrid phage λatt⁸⁰imm⁸⁰ in the absence of the host Rec system. The Δ4 deletion is 12.4% of the φ80 genome, starting at a distance of 1.6% φ80 unit to the right from the φ80 crossover point, pp′, i.e. located between 54.6% and 67.0% φ80 unit, as measured from the left (0%) termini of the mature φ80 DNA molecules. By locating the regions of homology between the DNAs of λ and φ80 (Fiandt et al., 1971), the region deleted in φ80Δ4sus2psu3⁺ was assigned to the genes of the phage Red system and a part of the int gene. In the presence of the host Rec system, φ80Δ4-sus2psu3⁺ segregates both phages, φ80Δ4sus2 and φ80Δ4sus2p(su3⁺)₂, which were excised or duplicated for su3⁺-transducing fragments. The loss of the duplication in φ80Δ4sus2p(su3⁺)₂ is also promoted by the host Rec system. Either of two generalized recombination systems, viral Red system or host Rec system, can play a role in the production of the excisions and the duplications of transducing fragments.     

Secondary structure in transfer RNA genes

The bacterial strand of the heteroduplex of λh80 dglyTsu⁺₃₆tyrTthrT with λh80 carries a cluster of three transfer RNA genes. The bacterial strands of the heteroduplexes of φ80hpsu^+,?_III and φ80hpsu^?_III with φ80h carry two and one genes for tyrosine tRNA, respectively. When these heteroduplexes are spread under weakly denaturing conditions (low formamide), secondary structure features consisting of one or several closely clustered, short duplex regions (folds) are observed. The features map at the positions of the tRNA gene clusters. They are not seen if the DNA is hybridized to Escherichia coli tRNA. It is concluded that the secondary structure features are due to self-complementary sequences in the tRNA genes. In some cases, the duplex folds appear to involve base pairing between sequences on different tRNA genes of a cluster and may also involve the spacer sequences between the tRNA sequences.     

Purification of a hybrid molecule composed of tyrosine transfer RNA and its complementary DNA sequence

The transducing bacteriophage φ80psu_III⁺ carries one structural Escherichia coli gene specifying tyrosine tRNA.The r strand of bacteriophage φ80psu_III⁺ was hybridized with E. coli transfer RNA and the hybrid digested with Neurospora crassa endonuclease. The analysis of the products of enzymic digestion demonstrated the release of a cistron-hybrid composed of tyrosine tRNA and its complementary DNA sequence. The cistron-hybrid was purified from unhybridized DNA by cesium sulphate density-gradient centrifugation and gel filtration.The ratio between tyrosine tRNA and its complementary DNA sequence in the final product was 1:1 as demonstrated by radioisotopic analysis. This purification represents a 30,000-fold enrichment of the E. coli genome for a specific DNA sequence.     

Relative stabilities of RNA/DNA hybrids: effect of RNA chain length in competitive hybrization

Escherichia coli DNA and fragmented rRNA were used as a model system to study the effect of RNA fragment size in hybridization-competition experiments. Though no difference in hybridization rates was observed, the relative stabilities of the RNA/DNA hybrids were found to be largely affected by the fragment size of the RNA molecule. Intact rRNA was shown to replace shorter homologous rRNA sequences in their hybrids, the rate of the displacement being dependent on the molecular size of the RNA fragments. Hybridization-competition experiments between molecules of different lengths are expected to be complicated by the displacement reaction. The synthesis of tRNA^Tyr-like sequences transcribed in vitro on φ80psu₃⁺ bacteriophage DNA was measured by hybridization competition assays. Indirect competition with labelled E. coli tRNA^Tyr hybridization revealed that the in vitro-synthesized RNA contained significant amounts of tRNA^Tyr; these sequences could not, however, be detected by the direct competition method in which labelled in vitro-synthesized RNA competes with E. coli tRNA^Tyr for hybridization to φ80psu₃⁺ DNA. These contradictory results can be traced to the differences in size of the competing molecules in the hybridization-competition reaction. Indeed, in vitro-transcribed tRNA^Tyr-like sequences, longer than mature tRNA, were found to displace efficiently E. coli tRNA^Tyr from its hybrids with φ80psu₃⁺ DNA. These findings explain why such sequences could not be detected by direct competition with E. coli tRNA^Tyr.     

Physical measurements on the lipid-containing bacteriophage φ6

Bacteriophage φ6 has been studied by small-angle X-ray scattering, intensity-fluctuation spectroscopy, analytical ultracentrifugation, and spectroscopy. The sedimentation coefficient (s₂₀⁰, w) is 375 S, the diffusion coefficient (D₂₀⁰, w) is 2.66 · 10^?8 cm²/s. Using the Svedberg equation and an estimate of the partial specific volume, the M_r is 1.49 ± 0.32 · 10⁸.A simple model which describes φ6, is a central sphere consisting of RNA and protein of radius 330 Å and an outer shell of low electron density 40 Å thick. The RNA may form five concentric shells in the region $\text{r = 140?290}\text{A}\text{?}$     

Bacteriophage lambda FII gene protein: role in head assembly

The in vitro completion of bacteriophage lambda F_II^? heads to form phage can be used as an assay for the λ F_II gene protein. F_II protein activity is released from highly purified phage particles or phage heads by treatment with heat or denaturing agents. F_II protein was purified from isolated phage particles and from an extract of E^? infected cells in which it is not bound to any large structures. No differences in molecular weight (11,500), isoelectric point (4.75), electrophoretic mobility, or purification properties could be demonstrated between the F_II proteins from the two sources. Thus the polypeptide does not seem to be modified during assembly.Phage φ80 is closely related to λ. φ80 heads will join to φ80 tails in vitro but will not join to λ tails, though λ heads will join to either type of tail. Mixing experiments between F_II^? heads, tails, and F_II protein from λ or φ80 show that the specificity of head-tail joining is correlated with the source of the F_II protein and not with the source of the other head proteins. Thus, F_II protein is apparently responsible for this specificity of head-tail joining.     

High molecular weight RNA containing histone messenger in the sea urchin Paracentrotus lividus

Sea urchin RNA extracted from early and mesenchyme blastula embryos and oocytes and fractionated on denaturing sucrose density gradients, was hybridized with histone DNA recombinants of Psammechinus miliaris (clone λh22) and of Paracentrotus lividus (clone pPH70). Histone sequences are found in the 9 S and larger than 9 S regions of the formamide/sucrose density gradients. The melting of the RNA-DNA duplexes obtained by hybridization of polysomal and high molecular weight RNA of embryos of P. lividus at the stage of early blastula, suggests a degree of heterogeneity in the high M_r RNA. The high M_r RNA contains at least four of the five histone gene sequences covalently linked.     

Formation of the parental replicative form DNA of bacteriophage phi-X174 and initial events in its replication

Intracellular φX174 DNA was studied under a variety of conditions that prevent the replication of the parental replicative form DNA. These conditions included treatment with 150 μg of chloramphenicol per ml., the use of the rep₃⁻ mutation of the host cell, amber mutation (am 8) in the viral gene responsible for RF replication (gene A) ^† and combinations thereof. In all cases the majority of the parental RF was in the covalently closed form (RFI). The relative amount of RF with a discontinuity in one strand (RFII) in these cases was between 2 and 10% of the total RF and independent of the multiplicity of infection. The only exception was seen in infections of rep₃ cells with φX am 3 (a mutant in the lysis gene, gene E, used as a wild-type representative). In this case a fairly constant absolute amount of RFII (1 to 4 per cell), independent of the multiplicity of infection, was formed, consisting almost exclusively of a closed complementary and an open parental viral strand. Since the formation of this type of RFII was dependent on protein synthesis and the presence of the product of φX gene A, it is concluded that the discontinuity in the parental viral strand represents the result of the action of the gene A product on the DNA. Possible mechanisms for the mode of action of the gene A product are discussed.     

Synthesis of Lectin-Like Protein in Developing Cotyledons of Normal and Phytohemagglutinin-Deficient Phaseolus vulgaris

The genome of the common bean Phaseolus vulgaris contains a small gene family that encodes lectin and lectin-like proteins (phytohemagglutinin, arcelin, and others). One of these phytohemagglutinin-like genes was cloned by L. M. Hoffman et al. ([1982] Nucleic Acids Res 10: 7819-7828), but its product in bean cells has never been identified. We identified the product of this gene, referred to as lectin-like protein (LLP), as an abundant polypeptide synthesized on the endoplasmic reticulum (ER) of developing bean cotyledons. The gene product was first identified in extracts of Xenopus oocytes injected with either cotyledonary bean RNA or LLP-mRNA obtained by hybrid-selection with an LLP cDNA clone. A tryptic map of this protein was identical with a tryptic map of a polypeptide with the same SDS-PAGE mobility detectable in the ER of bean cotyledons pulse-labeled with either [³H]glucosamine or [³H]amino acids, both in a normal and in a phytohemagglutinin-deficient cultivar (cultivars Greensleeves and Pinto UI 111). Greensleeves LLP has M_r 40,000 and most probably has four asparagine-linked glycans. Pinto UI 111 LLP has M_r 38,500. Unlike phytohemagglutinin which is a tetramer, LLP appears to be a monomer by gel filtration analysis. Incorporation of [³H]amino acids indicates that synthesis of LLP accounts for about 3% of the proteins synthesized on the ER, a level similar to that of phytohemagglutinin.