Translational repression of f2 protein synthesis

Pathogen-derived resistance to viral infection using a negative regulatory molecule

The principle of pathogen-derived resistance (the use of pathogen-derived genes to interfere with the pathogenic process and thereby confer disease resistance to the host) has been put forward as a broadly applicable conceptual tool for use in the genetic engineering of resistance to pathogens and parasites. It was previously predicted that four mechanisms of pathogen-derived resistance could be established using the bacteriophage QB and its host, Escherichia coli, as a model system. This paper demonstrates and helps ellucidate the first of these mechanisms by using a viral regulatory protein, the QB coat protein, to block viral replication. The QB coat protein gene was transferred to susceptible E. coli. Expression of this gene had no obvious detrimental effect on the host. Low-level, constitutive expression of the coat protein conditions very high levels of resistance to QB infection. The resulting resistance is not associated with RNA interference or loss of pili as attachment sites, and does not appear to be associated with premature encapsidation. This low-level expression of the QB coat protein also produces an intermediate level of resistance to the closely related phage SP, but fails to protect against the unrelated phage f2. Thus the resistance does not result from a generalized antiviral host response induced by the presence of the coat protein. We conclude that the QB coat protein blocks viral infection, as was predicted, due to its action as a negative regulatory molecule. The use of negative regulatory molecules may provide an effective mechanism for use in the genetic engineering of pathogen-derived resistance.

Characterization of Op3, a lysis-defective mutant of bacteriophage f2

We have isolated a conditional lethal mutant of bacteriophage 12 which makes plaques only on E. coli strains carrying a UGA suppressor. It grows normally in nonsuppressing hosts but does not lyse such strains. The mutation complements with amber mutations in each of the three known phage cistrons. These observations lead us to postulate the existence of a fourth gene in the RNA phage.

Hexamer of bacteriophage f2 coat protein as a repressor of bacteriophage RNA polymerase synthesis

Formation of complex I between phage f2 RNA and coat protein, leading to repression of phage RNA polymerase synthesis, depends nonlinearly upon the concentration of the coat protein. Maximum formation of complex I was observed when six molecules of coat protein were bound to one molecule of RNA. RNase digestion of a glutaraldehyde-fixed complex left, as the products, coat protein oligomers. The heaviest, hexamers, predominated in the mixture. It was also shown that, in an ionic environment required for phage protein synthesis, coat protein at a concentration optimum for complex I formation exists in solution as a dimer. The results indicate that the translational repression of the RNA polymerase cistron is due to a cooperative attachment to phage template of three dimers of coat protein, forming a hexameric cluster on an RNA strand.

Template activity of complexes formed between bacteriophage f2 RNA and coat protein

Formation of complexes between f2 RNA polymerase cistron was partially inhibited, some RNA and coat protein was studied using salt conditions which are optimum for phage protein synthesis. In this ionic environment, coat protein precipitation can be prevented by sulfhydryl group-protecting agents. Complexes formed at different protein-RNA input molar ratios were isolated and tested for template activity in an in vitro protein synthesizing system. Simultaneously, the number of protein molecules bound per RNA strand in such complexes was measured by the membrane (Millipore) filtration technique. Under conditions in which translation of the RNA strands were complexed with six molecules of coat protein, whereas some remained unbound. Strong inhibition of the translation of the RNA polymerase cistron was observed when each of the RNA strands present in the mixture was associated with six molecules of coat protein.

Nucleotide sequence at the binding site for coat protein on RNA of bacteriophage R17

The binding of a few molecules [1-6] of RNA bacteriophage coat protein to 1 molecule of RNA represses in vitro translation of the RNA synthetase cistron. Digestion of the complex, R17 coat protein-R17 RNA, by T1 RNase yields an RNA fragment bound to the coat protein. The nucleotide sequence of this fragment (59 residues) reveals that it contains the punctuation signal between the coat protein and RNA synthetase cistrons, suggesting that this is the site on the RNA where the coat protein acts as a translational repressor.