Evidence that the neck appendages are adsorption organelles in Bacillus subtilis bacteriophage phi29.

A mutant of Bacillus subtilis unable to adsorb phage phi29 efficiently has been isolated. This mutant can be infected by host range mutants of the phage. Since the host range mutations map in cistron 12, which codes for neck appendage protein, this would tend to confirm that these organelles are involved in viral adsorption.     

The Anatomy and Function of a Segment of the X Chromosome of DROSOPHILA MELANOGASTER

An average size chromomere of the polytene X chromosome of Drosophila melanogaster contains enough DNA in each haploid equivalent strand to code for 30 genes, each 1,000 nucleotides long. We have attempted to learn about the organization of chromosomes by asking how many functional units can be localized within a chromomere. This was done by 1) recovery of mutants representative of every cistron in the 3A2-3C2 region; 2) the characterization of the function of each mutant type and grouping by complementation tests; 3) the determination of the genetic and cytological position of each cistron by recombination and deletion mapping. The data clearly show one functional group per chromomere. It is postulated that a chromomere is one cistron within which much of the DNA is regulatory in function.     

Identification of a phi X174 coded protein involved in the inhibition of beta-galactosidase synthesis in Escherichia coli

The synthesis of β-galactosidase (EC 3.2.1.23: β-D-galactoside galactohydrolase) in $\text{Escherichia}\text{coli}$ is repressed as a result of infection with single-stranded DNA phage ØX174. An $\text{amber}$ mutant in ØX174 cistron A, which codes for two proteins, does not inhibit the enzyme synthesis while $\text{amber}$ mutants in all other genes do cause repression. A mutant near the amino-terminal end of cistron A, which produces the small 35,000 molecular weight cistron A polypeptide, also inhibits the synthesis of β-galactosidase. Inhibition is also observed in an $\text{Escherichia}\text{coli}\text{rep}$ mutant which does not support the replication of replicative-form DNA. Exogenous nucleotide bases and cyclic 3′,5′-adenosine monophosphate (cyclic AMP) do not have any effect on the degree of repression.     

Mating type control in Saccharomyces cerevisiae: a frameshift mutation at the common DNA sequence, X, of the HML alpha locus.

A mutation defective in the homothallic switching of mating type alleles, designated hml alpha-2, has previously been characterized. The mutation occurred in a cell having the HO MATa HML alpha HMRa genotype, and the mutant culture consisted of ca. 10% a mating type cells, 90% nonmater cells of haploid cell size, and 0.1% sporogenous diploid cells. Genetic analyses revealed that nonmater haploid cells have a defect in the alpha 2 cistron at the MAT locus. This defect was probably caused by transposition of a cassette originating from the hml alpha-2 allele by the process of the homothallic mating type switch. That the MAT locus of the nonmater cells is occupied by a DNA fragment indistinguishable from the Y alpha sequence in electrophoretic mobility was demonstrated by Southern hybridization of the EcoRI-HindIII fragment encoding the MAT locus with a cloned HML alpha gene as the probe. The hml alpha-2 mutation was revealed to be a one-base-pair deletion at the ninth base pair in the X region from the X and Y boundary of the HML locus. This mutation gave rise to a shift in the open reading frame of the alpha 2 cistron. A molecular mechanism for the mating type switch associated with the occurrence of sporogenous diploid cells in the mutant culture is discussed.     

Fidelity of Initiation of Protein Synthesis After Premature Chain Termination in Polarity Mutants

beta-Isopropylmalate dehydrogenase, the product of the second cistron of the leucine operon in Salmonella typhimurium, produced by strains bearing nonsense or frameshift mutations in the first cistron of the operon was shown to be homogeneous as judged by electrophoretic and immunological techniques. Amino terminal analyses suggest that the enzyme produced by the mutant strains is identical with the wild-type enzyme. This view is supported by the observation that a nonsense mutant strain beta-isopropylmalate dehydrogenase copurifies with the wild-type enzyme. The results suggest that the uncoupling of normal chain termination and reinitiation does not interfere with the fidelity of subsequent polypeptide chain initiation in a polycistronic messenger ribonucleic acid.     

On Some Genetic Aspects of Phage λ Resistance in E. COLI K12

Most mutations rendering E. coli K12 resistant to phage lambda, map in two genetic regions malA and malB.-The malB region contains a gene lamB specifically involved in the lambda receptor synthesis. Twenty-one independent lamB mutations studied by complementation belonged to a single cistron. This makes it very likely that lamB is monocistronic. Among the lamB mutants some are still sensitive to a host range mutant of phage lambda. Mutations mapping in a proximal gene essential for maltose metabolism inactivate gene lamB by polarity confirming that both genes are part of the same operon. Because cases of intracistronic complementation have been found, the active lamB product may be an oligomeric protein.-Previously all lambda resistant mutations in the malA region have been shown to map in the malT cistron. malT is believed to be a positive regulatory gene necessary for the induction of the "maltose operons" in the malA region and in the malB region of the E. coli K12 genetic map. No trans dominant malT mutation have been found. Therefore if they exist, they occur at a frequency of less than 10(-8), or strongly reduce the growth rate of the mutants.     

Morphogenesis of Bacteriophage φ80: Identification of the Cistron 13 Product

An in vitro complementation reaction leading to the assembly of bacteriophage phi80 tails from component proteins is described. Tail assembly occurs when a lysate of any mutant in cistron 13 is mixed with a second lysate of a mutant in any of the other cistrons involved in tail formation. Lysates of mutants that are blocked in tail formation contain phage heads that can unite with free tails to form infective particles. The rate of the complementation reaction shows little dependence upon temperature, suggesting that the assembly depends largely upon the kinetic encounter of the interacting components. The tail component missing in cistron 13 mutant lysates was purified approximately 55-fold and shown to be, at least in part, a protein having a molecular weight of approximately 22,000. This protein was also released from highly purified infective phi80 particles after osmotic shock followed by heattreatment, suggesting that it most probably is an integral structural protein of the phage tail. Lysates of mutants of bacteriophage lambda that are defective in tail formation were shown to contain a tail component identical with or similar to the phi80 cistron 13 product.     

The Genetic Basis for Mucoidy and Radiation Sensitivity in capR (lon) Mutants of E. coli K-12

CapR mutants of E. coli K-12 overproduce capsular polysaccharide (mucoid phenotype) and enzymes involved in capsular polysaccharide synthesis, and they are sensitive to radiation. It has been uncertain whether both properties are mediated by damage to a single cistron or by a polar effect on a second cistron in the same operon. Introduction of a polarity suppressor caused no change in the overproduction of polysaccharide, in the enzymes of polysaccharide synthesis or in radiation sensitivity of the capR mutant. Thus mucoidy and radiation sensitivity resulting from capR (lon) mutations are both the consequences of impairment of the same cistron. The experiments demonstrate the advantage of the use of polarity suppressors (over conventional nonsense suppressors) in determining whether pleiotropic effects of a mutation are the result of polarity.     

Sequence of 1000 nucleotides at the 3'' end of tobacco mosaic virus RNA.

The sequence of 1000 nucleotides at the 3' end of tobacco mosaic virus RNA has been determined. The sequence contains the entire coat protein cistron as well as regions to its left and right. Sequence characterization was by conventional methods for use with uniformly 32P labeled RNA complemented by newer methods for in vitro 5' and 3' 32P end-labeling of RNA and its subsequent rapid analysis. The noncoding region separating the coat protein cistron from the 3' terminus is 204 residues long and may be folded into a clover-leaf-type secondary structure. The distribution of termination codons to the left of the coat protein cistron suggests that the end of the adjacent cistron is separated from the beginning of the coat protein cistron by only two nucleotides. The subgenomic viral coat protein mRNA was isolated from infected tissue and shown to be capped. The nontranslated sequence separating the cap from the AUG initiation codon is 9 residues long and thus overlaps a portion of the adjacent cistron on the genome RNA.     

Bacteriophage lambda-E. coli K12 vector-host system for gene cloning and expression under lactose promoter control. II. DNA fragment insertion at the vicinity of the lac UV5 promoter.

Summary Recombinant plasmids containing the entire 16S RNA gene from the rrn B cistron of E. coli inserted in Col E1 and pBR322 plasmid vectors have been constructed. These plasmids have been mapped using several restriction endonucleases as well as by DNA-RNA hybridization. These maps reveal previously undetected restriction sites in the rrn B cistron and in Col E1 plasmid DNA.     

Defective lysis of streptomycin-resistant escherichia coli cells infected with bacteriophage f2

A lysis defect was found to account for the failure of a streptomycin-resistant strain of Escherichia coli to form plaques when infected with the male-specific bacteriophage f2. The lysis defect was associated with the mutation to streptomycin resistance. Large amounts of apparently normal bacteriophage accumulated in these cells. Cell-free extracts from both the parental and mutant strains synthesized a potential lysis protein in considerable amounts in response to formaldehyde-treated f2 RNA but not in response to untreated RNA. As predicted from the nucleotide sequence of the analogous MS2 phage, the protein synthesized in vitro had the expected molecular weight and lacked glycine. The cistron for the lysis protein overlapped portions of the coat and replicase cistrons and was translated in the +1 reading frame. Initiation at the lysis protein cistron may be favored by translation errors that expose the normally masked initiation site, and streptomycin-resistant ribosomes, known to have more faithful translation properties, may be unable to efficiently synthesize the lysis protein.     

Binding of mammalian ribosomes to MS2 phage RNA reveals an overlapping gene encoding a lysis function.

The main binding site for mammalian ribosomes on the single-stranded RNA of bacteriophage MS2 is located nine tenths of the way through the coat protein gene. Translation initiated at an AUG triplet in the +1 frame yields a 75 amino acid polypeptide which terminates within the synthetase gene at a UAA codon, also in the +1 frame. Partial amino acid sequence analysis of the product synthesized in relatively large amounts by mammalian ribosomes confirms this assignment of the overlapping cistron. The same protein is made in an E. coli cell-free system, but only in very small amounts. Analysis of the translation products directed by RNA from op3, a UGA nonsense mutant of phage f2, identifies the overlapping cistron as a lysis gene. In this paper we show that the op3 mutation is a C yield U transition occurring in the second codon of the synthetase cistron, which explains the lowered production of phage replicase (as well as lack of lysis) upon op3 infection of nonpermissive cells. We discuss the properties of the overlapping gene in relation to its lysis function, recognition of the lysis initiator region by E. coli versus eucaryotic ribosomes and op3 as a ribosome binding site mutant for the f2 synthetase cistron.     

Model polycistron operon for studying conjugated translation in E. coli cells. The role of a stream of ribosomes

The role of "stream" of ribosomes upon translation of polycistronic mRNAs has been studied using an artificial polycistron. It has been found that the levels of activation of cistron Ci + 1 out of two adjacent cistrons (Ci and Ci + 1) depends, in addition to earlier described effects of mutual arrangement of initiation and termination signals, also on efficiency of translation of the foregoing cistron Ci. The results obtained lead to the conclusion that in polycistronic systems the levels of translation of cistron Ci + 1 can be regulated by "stream" of ribosomes resulted from translation of the proximal cistron Ci.     

φX-174 Bacteriophage Structural Mutants Which Affect Deoxyribonucleic Acid Synthesis

Seven cistrons in X-174 were identified and one in particular was studied intensively: cistron A, which is assigned a protein in the mature phage. Amber mutants in this cistron synthesize a new deoxyribonucleic acid (DNA) form in addition to circular phage DNA upon infection of the restrictive host. This DNA is linear, non-infectious, and single-stranded; it is formed from the phage strand of replicative form X-174 DNA. These mutants produce two different defective particles in the restrictive host. One particle contains circular phage DNA but is not infectious; the other contains the new DNA form and is similar to the 70S particles found in wild-type phage lysates. The mutant A gene product acts independently of normal A protein upon mixed infection of the restrictive host with an A mutant and a mutant from any other cistron or wild type.     

Assembly of Bacillus subtilis phage phi29. 1. Mutants in the cistrons coding for the structural proteins.

The effect of mutations in the cistrons coding for the phage structural proteins has been studied by analyzing the phage-related structures accumulated after restrictive infection. Infection with susmutants in cistron 8, lacking both the major head and the fiber protein, does not produce any phage-related structure, suggesting a single route for the assembly of phage phi29; infection with ts mutants in this cistron produces isometric particles. Mutants is cistron 9, coding for the tail protein, TP1, produce DNA-free prolate heads with an internal core; these particles are abortive and contain the head proteins HPO, HP1 and HP3, the upper collar protein NP2 and the nonstructural proteins p7, p15 and p16. Mutants in cistron 10, coding for the upper collar protein, NP2, produce DNA-free isometric heads also with an internal core; they contain the head proteins and the nonstructural protein p7, suggesting that this protein forms the internal core. Mutants in cistrons 11 and 12, coding for the lower collar protein, NP3, and the neck appendages, NP1, respectively, give rise to the formation of DNA-containing normal capsids and DNA-free prolate particles, more rounded at the corners than the normal capsids and with an internal core; the DNA-containing 11-particles are formed by the head proteins and the upper collar protein; the DNA-free 11-particles contain, besides these proteins, the nonstructural protein p7 and a small amount of proteins p15 and 16. The DNA-containing 12-particles have all the normal phage structural proteins except the neck appendages, formed by protein NP1; the DNA-free particles are similar to the DNA-free 11-particles. After restricitive infection mutant sus14(1241) has a delayed lysis phenotype and produces a phage burst higher than normal, after artificial lysis. It produces DNA-containing particles, identical to wild-type phage, which have all the normal phage structural proteins, and DNA-free prolate particles, more rounded at the corners than the final phage particles and with an internal core; the last particles contain the same proteins as the DNA-free 11 or 12-particles. These particles could represent a prohead state, ready for DNA encapsulation. None of the DNA-containing particles have the nonstructural proteins p7, p15 or p16, suggesting that these proteins are released from the proheads upon DNA encapsulation.     

Role of glutamic acid 177 of the ricin toxin A chain in enzymatic inactivation of ribosomes.

The gene for the A chain of ricin toxin was fused to a beta-galactosidase marker cistron via a DNA sequence encoding a short collagen linker, and the tripartite fusion protein was expressed in Escherichia coli. Site-specific mutagenesis was used to change glutamic acid residue 177 to aspartic acid or alanine. When the mutant proteins were expressed, purified, and tested quantitatively for enzymatic activity, the carboxylate function at position 177 was found not to be absolutely essential for ricin toxin A-chain catalysis.     

The influence of the reading context upon the suppression of nonsense codons

Summary We have examined the response of phage T4 nonsense mutations located at various sites within the same cistron to different suppression agents. A wide range of suppression efficiency is found for both ochre (UAA) and amber (UAG) mutations under conditions where suppression provides a measurement of the amount of chain propagation past the mutated site. We have established a relationship between our measurement-the size of the phage yield-and the amount of rIIB product present in the infection. Our data suggest that the 1000-fold range of variations in yields observed in the rIIB cistron corresponds to a 30-fold range of variation in the level of rIIB product, i.e. in the relative frequency of chain propagation past the various nonsense codons included in our test.From the parallelism of response of any particular mutant to very different suppression mechanisms we conclude that the efficiency of suppression is site specific, that is to say, that the main factor determining the frequency of chain propagation at a nonsense codon by any type of suppression mechanism is the nucleotide sequence adjacent to the nonsense codon (reading context).We propose that the recognition of a natural termination signal involves a sequence longer than a nonsense codon and that nonsense codons outside of their natural environment induce variable termination rates which are reflected in the suppression potential.