A procedure for amino acid sequencing in internal regions of proteins

Reported translational bypass in a trpR'-lacZ' fusion is accounted for by unusual initiation and +1 frameshifting

I. Benhar and H. Engelberg-Kulka reported that a 55 nucleotide translational bypass occurs in decoding a fusion of the Escherichia coli tryptophan repressor, trpR, and lacZ genes. The start of the bypass occurred in the trpR gene and coding resumed in the lacZ gene. It was considered that bypassing likely occurred in expression of trpR itself to produce an additional 10 kDa product which may be biologically important. We report here that bypass is undetectable in the same and related trpR'-lacZ' fusions. The beta-galactosidase activity derived from the fusions is accounted for by unusual internal initiation and +1 frameshifting, both of which occur in the lacZ part of the fusion. The 10 kDa product reportedly encoded by the trpR gene was not detectable to a level of 1% of the full-length 12 kDa tryptophan repressor product, at least when expressed from a T7 promoter.

The localization of the phosphorylation site of BglG, the response regulator of the Escherichia coli bgl sensory system

BglG, the response regulator of the bgl sensory system, was recently shown to be phosphorylated on a histidine residue. We report here the localization of the phosphorylation site to histidine 208. Localization of the phosphorylated histidine was carried out in two steps. We first engineered BglG derivatives with a specific protease (factor Xa) cleavage site that allowed asymmetric splitting of each prephosphorylated protein to well defined peptides, of which only one was labeled by radioactive phosphate. This allowed the localization of the phosphorylation site to the last 111 residues. Subsequently, we identified the phosphorylated histidine by mutating each of the three histidines located in this region to an arginine and following the ability of the resulting mutants to be in vivo regulated and in vitro phosphorylated by BglF, the bgl system sensor. Histidine 208 was the only histidine which failed both tests. The use of simple techniques to map the phosphorylation site should make this protocol applicable for the localization of phosphorylation sites in other proteins. The bgl system represents a new family of sensory systems. Thus, the mapping reported here is an important step toward the definition of the functional domains involved in the transduction of a signal by the components that constitute systems of this novel family.

Polyamines regulate the expression of ornithine decarboxylase antizyme in vitro by inducing ribosomal frame-shifting

We provide here an example of a mammalian cellular gene expressed by frame-shifting. Conventional reading of the sequence of ornithine decarboxylase-antizyme mRNA (a protein that modulates the rate of ornithine decarboxylase degradation) results in premature termination at an in-frame termination codon (stop-1), located shortly after the initiation codon. By translating, in vitro in reticulocyte lysate, antizyme mRNA with a full coding capacity and various mutants derived from it, we demonstrate that antizyme expression requires that ribosomes shift from the first open reading frame (termed ORF0) to a second +1 open reading frame (ORF1). Our studies show that this frame-shifting, which occurs at maximal efficiency of approximately 20%, is stimulated by polyamines and requires the functional integrity of the stop codon (stop-1) of ORF0. By introducing in-frame deletions, we have shown that an 87-nt segment surrounding stop-1 enhances frame-shifting efficiency, whereas the 6 nt located just upstream to stop-1 are absolutely essential for this process. Because this segment does not contain sequences that were previously characterized as shifty segments, our results suggest that another mechanism of frame-shifting is involved in mediating antizyme expression.

Frameshifting in the expression of the E. coli trpR gene occurs by the bypassing of a segment of its coding sequence

The E. coli trpR gene encodes the 108 amino acid long trp repressor. We have previously shown that a +1 frameshifting event occurs during the expression of trpR. Here we show that the transition from the 0 to the +1 frame of trpR occurs by the bypassing of a 55 nt long segment of the trpR+1-lacZ mRNA. This bypassing event is not pretranslational, and it probably takes place during translation. Two adjacent elements are required: a specific sequence of trpR, which must be preceded by a nonspecific 5' end longer than 10 translatable codons. Unique to trpR-lacZ bypassing is that the 55 nt long region must be translated in frame 0 to enable bypassing into the +1 frame. Translational bypassing as a newly discovered mechanism of gene expression is discussed, and the possible existence of translational introns is suggested.

Frameshifting in the expression of the Escherichia coli trpR gene

The trpR gene of Escherichia coli carries an open reading frame that encodes the trp repressor, 108 amino acids long. Here we show that translation of an additional (+1) reading frame of trpR occurs both in vivo and in vitro. This results in the synthesis of a stable +1 frame polypeptide. Using site-specific mutagenesis, immunological techniques and amino acid sequencing we have found that the N-terminus of the +1 frame product and that of the known 0 frame product are identical but that their C-termini differ. Our results are discussed in relation to the role of natural frameshifting as a regulatory mechanism of gene expression in general, and with respect to tryptophan biosynthesis in particular.