An intercistronic region and ribosome-binding site in bacterial messenger RNA.

A messenger RNA fragment about 220 nucleotides long has been isolated from 32-P-labeled tryptophan operon mRNA of Escherichia coli. When point mutations at the end of trpB and the beginning of trpA were introduced, the resulting nucleotide changes were found; hence the mRNA fragment must include the trpB-trpA intercistronic region. Most of the nucleotide sequences can be assigned to specific locations in the structural genes, based on the amino-acid sequences of the trpB and trpA proteins. In vitro, ribosomes bind to this piece of mRNA and protect from nuclease attack a region about 40 nucleotides long, containing a central AUG codon. The triplet codons to the 3' side of this AUG correspond to the first seven amino acids of the trpA protein; the codons to the 5' side correspond to the last six amino acids of the trpB protein. Translation of trpB is terminated by single UGA codon, which overlaps the trpA AUG initiation codon: UGAUG. Thus the untranslated "intercistronic" region consists of only two nucleotides. The RNA sequence spanning this region undoubtedly fulfills two functions, specifying ribosome recognition signals as well as encoding amino-acid sequences.     

Nucleotide sequence surrounding a ribonuclease III processing site in bacteriophage T7 RNA.

We have determined a nucleotide seuqence of 87 residues surrounding a ribonuclease III (endoribonuclease III; EC 3.1.4.24) processing site in the bacteriophage T7 intercistronic region between early genes 0.3 and 0.7. The structural requirements necessary for proper recognition and cleavage by RNase III are discussed. In addition, other structural features characteristic of this intercistronic boundary are described.     

Precursor of C4 antisense RNA of bacteriophages P1 and P7 is a substrate for RNase P of Escherichia coli.

The C4 repressor of the temperate bacteriophages P1 and P7 inhibits antirepressor (Ant) synthesis and is essential for establishment and maintenance of lysogeny. C4 is an antisense RNA acting on a target, Ant mRNA, which is transcribed from the same promoter. The antisense-target RNA interaction requires processing of C4 RNA from a precursor RNA. Here we show that 5' maturation of C4 RNA in vivo depends on RNase P. In vitro, Escherichia coli RNase P and its catalytic RNA subunit (M1 RNA) can generate the mature 5' end of C4 RNA from P1 by a single endonucleolytic cut, whereas RNase P from the E. coli rnpA49 mutant, carrying a missense mutation in the RNase P protein subunit, is defective in the 5' maturation of C4 RNA. Primer extension analysis of RNA transcribed in vivo from a plasmid carrying the P1 c4 gene revealed that 5'-mature C4 RNA was the predominant species in rnpA+ bacteria, whereas virtually no mature C4 RNA was found in the temperature-sensitive rnpA49 strain at the restrictive temperature. Instead, C4 RNA molecules carrying up to five extra nucleotides beyond the 5' end accumulated. The same phenotype was observed in rnpA+ bacteria which harbored a plasmid carrying a P7 c4 mutant gene with a single C-->G base substitution in the structural homologue to the CCA 3' end of tRNAs. Implications of C4 RNA processing for the lysis/lysogeny decision process of bacteriophages P1 and P7 are discussed.     

RNase III stimulates the translation of the cIII gene of bacteriophage lambda.

The bacteriophage lambda cIII gene product regulates the lysogenic pathway by stabilizing the lambda cII regulatory protein. Our results show that the expression of the lambda cIII gene is subject to specific requirements. Tests of a set of cIII-lacZ gene and operon fusions reveal that a sequence upstream of the cIII ribosome binding site is needed for cIII translation. The sequence contains an inefficient RNase III processing site. Furthermore, expression of cIII is drastically reduced in cells lacking RNase III. We have isolated a phage carrying a mutation (r1), which lies in the upstream sequence, that leads to a reduction in cIII translation and inactivates the RNase III processing site. The r1 mutant is nevertheless still dependent on RNase III for cIII translation; r1 reduces cIII translation by a factor of 3 in wild-type cells and by a factor of approximately equal to 30 in an RNase III mutant host. We propose that RNase III stimulates cIII translation by binding to the upstream sequence and thereby exposing the cIII ribosome binding site. This stimulation does not involve RNA cleavage. Consistent with this hypothesis is our finding that, in vitro, unprocessed cIII mRNA is translated, whereas RNase III-cleaved cIII mRNA is not.     

Site-specific cleavage by T1 RNase of U-1 RNA in u-1 ribonucleoprotein particles.

The structures and functions of small nuclear ribonucleoprotein particles have become of interest because of their suggested role in processing heterogeneous nuclear RNA [Lerner, M. R., Boyle, J. A., Mount, S. M., Wolin S. L. & Steitz, J. A. (1980) Nature (London) 283, 220-224]. To determine the conformation of U-1 RNA in U-1 ribonucleoprotein particles and whether proteins of these particles protect segments of U-1 RNA, intact particles and isolated U-1 RNA were digested with T1 RNase. The digested particles were immunoprecipitated with anti-Sm antibodies. A 5'-end fragment containing nucleotides 1-107 and 3'-end fragments containing nucleotides 108-165 and 108-153 were recovered in nearly quantitative yield from digestion of the particles, suggesting that position 107 is the principal cleavage site in them. At the same T1 RNase concentrations, deproteinized U-1 RNA was cleaved into many fragments. At low T1 RNase concentrations, major cleavage site of deproteinized U-1 RNA was at nucleotide 69. Comparison of the cleavage sites of free U-1 RNA and of U-1 RNA in U-1 ribonucleoprotein particles suggested similar secondary structures. The resistance of the 5' end of U-1 RNA to T1 RNase was unexpected inasmuch as this region has been implicated in hydrogen bonding with heterogeneous nuclear RNA splice junctions.     

A small RNA induced late in simian virus 40 infection can associate with early viral mRNAs.

Analysis of total cytoplasmic and polyadenylylated cytoplasmic RNA from cells lytically infected with simian virus 40 (SV40) has demonstrated the presence of a small RNA, approximately 65 nucleotides long, that is induced late in lytic infection. This small RNA is apparently specific in size and sequence and is not selected on columns of oligo(dT)-cellulose. It is homologous to a region of the early SV40 mRNAs (and to the late DNA strand), starting approximately 250 nucleotides from the 3' end of the early mRNAs (SV40 map position 0.21). The function of this RNA in the viral cycle and its source are unknown at this time; however, its temporal expression, unique sequence, and interesting region of homology within the SV40 genome suggest a possible role in the control of SV40 gene expression.