RESUMEN
A novel method, not relying on genetic complementation of a mutation, was used to clone a gene for translational initiation factor IF2. Two clones from a cosmid library of total Escherichia coli DNA were isolated for their ability to overproduce IF2 in vivo as determined by quantitative immunoblotting. "Maxicell" analysis of cosmid-encoded proteins and specific immune precipitation of the labeled proteins showed that the structural gene for IF2 (inf B) had been cloned. Subcloning fragments from the original cosmids located the inf B gene to a 4.8-kilobase pair HindIII/BamHI fragment. This fragment has been inserted into an integration-deficient recombinant lambda phage that lysogenizes by homology. By mapping the point of lysogenization on the E. coli chromosome, inf B has been located at 68 min, very close to argG, nusA, rpsO, and pnp. Because the gene for initiation factor IF3 is located at 38 min on the chromosome, the genes for translational initiation factors are not grouped together.
Asunto(s)
Genes Bacterianos , Factores de Iniciación de Péptidos/genética , Bacteriófago lambda , Mapeo Cromosómico , Cromosomas Bacterianos/ultraestructura , Clonación Molecular , Escherichia coli/genética , Regulación de la Expresión Génica , Genes , PlásmidosRESUMEN
Bacteriophage P1 has been shown previously to determine a product ban that can substitute in DNA replication for the protein specified by cis-tron dnaB of Escherichia coli. However, ban product furnished by P1 bac prophage (ban constitutive) substitutes only poorly for DNA replication in the absence of dnaB product in a strain bearing an unsuppressed amber mutation, dnaB266, as shown by the cryosensitivity of the dnaB266 (P1 bac) lysogen and its unability to support lambda growth. An additional mutation (termed crr) in the P1 bac prophage has been obtained which confers cryoresistance to the sup+ dnaB266 (P1 bac crr) lysogen and restores its ability to support lambda growth. ban product produced in P1 bac crr lysogen fulfills all dnaB roles in vivo, especially in the various instances in which ban product expressed in P1 bac lysogens does not. The ban product is expressed constitutively in P1 crr prophage. The crr-1 mutation is tightly linied to the bac-1 and ban-1 mutations and is dominant over crr+. The nature of the crr mutation is discussed: two hypotheses are considered, that of a mutation in the ban gene rendering the ban product more active or that of a site mutation in the ban operon increasing the level of ban expression. Expression of ban product (wild type or altered) leads to interactions with the variously altered dnaB product. Both positive and negative interactions are described. Genetic results presented here suggest that ban and dnaB subunits interact to form hybrid dnaB-like molecules; the average composition of which depends on the relative quantities of ban and dnaB subunits in the cell.
Asunto(s)
Colifagos/genética , Replicación del ADN , Escherichia coli/genética , Genes Virales , ADN Bacteriano/genética , ADN Viral/genética , FenotipoRESUMEN
In bacteriophage P1 an amber mutation in a new gene, bof, has been isolated. The bof-1 phage mutant exhibits a pleiotropic phenotype; bof product is non-essential, and acts as a positive modulator. In P1 bac-1 mutants, in which a dnaB analog product, ban, is expressed constitutively, the bof product activates ban expression both in the prophage state and in lytic growth: P1 bof bac prophages have a reduced ban activity and in lytic growth P1 bof bac phages show a lower ban activity than P1 wild type. This effect on ban activity is observed specifically in P1 bac-1 mutants; it is not mediated by the c1 repressor of the lytic functions (repressor of the ban operon) since this effect occurs even if the phage carries a heat sensitive c1 repressor. Thus we concluded that the bac mutation put the ban operon under an abnormal, unknown control, modulated by the bof product. P1 bof lysogens show an increased immunity to superinfecting P1 phage and are affected in their inducibility properties; in the presence of the altered c1-100 repressor, bof product is required for maintenance of lysogeny, as shown by the induction of P1 c1-100 bof-1 lysogens at 30 degrees. P1 bof superinfecting phage can be established together with a resident P1 bof prophage in a recA host, unlike P1 wild type which cannot form double lysogens. P1 bof double lysogens are unstable and segregate one or the other prophage. P1 Cm bof and P1 Km bof lysogens show higher levels of antibiotic resistance than the corresponding bof+ lysogens. The bof gene has been mapped, in an interval defined by P1 prophage deletion end points, far from both ban and c1. All bof phenotypes are reversed by single mutations.