An extended Escherichia coli "selenocysteine insertion sequence" (SECIS) as a multifunctional RNA structure.

The genetic code, once thought to be rigid, has been found to permit several alternatives in its reading. Interesting alternative relates to the function of the UGA codon. Usually, it acts as a stop codon, but it can also direct the incorporation of the amino acid selenocysteine into a polypeptide. UGA-directed selenocysteine incorporation requires a cis-acting mRNA element called the "selenocysteine insertion sequence" (SECIS) that can form a stem-loop RNA structure. Here we discuss our investigation on the E. coli SECIS. This includes the follows: 1) The nature of the minimal E. coli SECIS. We found that in E. coli only the upper-stem and loop of 17 nucleotides of the SECIS is necessary for selenocysteine incorporation on the condition that it is located in the proper distance from the UGA [34]; 2) The upper stem and loop structure carries a bulged U residue that is required for selenocysteine incorporation [34] because of its interaction with SelB; and 3) We described an extended fdhF SECIS that includes the information for an additional function: The prevention of UGA readthrough under conditions of selenium deficiency [35]. This information is contained in a short mRNA region consisting of a single C residue adjacent to the UGA on its downstream side, and an additional segment consisting of the six nucleotides immediately upstream from it. These two regions act independently and additively and probably through different mechanisms. The single C residue acts as itself; the upstream region acts at the level of the two amino acids, arginine and valine, for which it codes. These two codons at the 5' side of the UGA correspond to the ribosomal E and P sites. Finally, we present a model for the E. coli fdhF SECIS as a multifunctional RNA structure containing three functional elements. Depending on the availability of selenium the SECIS enables one of two alternatives for the translational machinery: Either selenocysteine incorporation into a polypeptide or termination of the polypeptide chain.

Postsegregational killing mediated by the P1 phage "addiction module" phd-doc requires the Escherichia coli programmed cell death system mazEF.

"Addiction modules" consist of two genes; the product of the second is long lived and toxic, while the product of the first is short lived and antagonizes the lethal action of the toxin. The extrachromosomal addiction module phd-doc, located on the P1 prophage, is responsible for the postsegregational killing effect (death of plasmid-free cells). The Escherichia coli chromosomal addiction module analogue, mazEF, is responsible for the induction of programmed cell death. Here we show that the postsegregational killing mediated by the P1 phd-doc module depends on the presence of the E. coli mazEF system. In addition, we demonstrate that under conditions of postsegregational killing, mediated by phd-doc, protein synthesis of E. coli is inhibited. Based on our findings, we suggest the existence of a coupling between the phd-doc and mazEF systems.

The bulged nucleotide in the Escherichia coli minimal selenocysteine insertion sequence participates in interaction with SelB: a genetic approach.

The UGA codon, which usually acts as a stop codon, can also direct the incorporation into a protein of the amino acid selenocysteine. This UGA decoding process requires a cis-acting mRNA element called the selenocysteine insertion sequence (SECIS), which can form a stem-loop structure. In Escherichia coli, selenocysteine incorporation requires only the 17-nucleotide-long upper stem-loop structure of the fdhF SECIS. This structure carries a bulged nucleotide U at position 17. Here we asked whether the single bulged nucleotide located in the upper stem-loop structure of the E. coli fdhF SECIS is involved in the in vivo interaction with SelB. We used a genetic approach, generating and characterizing selB mutations that suppress mutations of the bulged nucleotide in the SECIS. All the selB suppressor mutations isolated were clustered in a region corresponding to 28 amino acids in the SelB C-terminal subdomain 4b. These selB suppressor mutations were also found to suppress mutations in either the loop or the upper stem of the E. coli SECIS. Thus, the E. coli SECIS upper stem-loop structure can be considered a "single suppressible unit," suggesting that there is some flexibility to the nature of the interaction between this element and SelB.

A sequence in the Escherichia coli fdhF "selenocysteine insertion Sequence" (SECIS) operates in the absence of selenium.

The UGA codon context of the Escherichia coli fdhF mRNA includes an element called the selenocysteine insertion sequence (SECIS) that is responsible for the UGA-directed incorporation of the amino acid selenocysteine into a protein. Here, we describe an extended fdhF SECIS that includes the information for an additional function: the prevention of UGA readthrough under conditions of selenium deficiency. This information is contained in a short mRNA region consisting of a single C residue adjacent to the UGA on its downstream side, and an additional segment consisting of the six nucleotides immediately upstream from it. These two regions act independently and additively, and probably through different mechanisms. The single C residue acts as itself; the upstream region acts at the level of the two amino acids, arginine and valine, for which it codes. These two codons at the 5' side of the UGA correspond to the ribosomal E and P sites. Here, we present a model for the E. coli fdhF SECIS as a multifunctional RNA structure containing three functional elements. Depending on the availability of selenium, the SECIS enables one of two alternatives for the translational machinery: either selenocysteine incorporation into a polypeptide or termination of the polypeptide chain.

rexB of bacteriophage lambda is an anti-cell death gene.

In Escherichia coli, programmed cell death is mediated through "addiction modules" consisting of two genes; the product of one gene is long-lived and toxic, whereas the product of the other is short-lived and antagonizes the toxic effect. Here we show that the product of lambdarexB, one of the few genes expressed in the lysogenic state of bacteriophage lambda, prevents cell death directed by each of two addiction modules, phd-doc of plasmid prophage P1 and the rel mazEF of E. coli, which is induced by the signal molecule guanosine 3',5'-bispyrophosphate (ppGpp) and thus by amino acid starvation. lambdaRexB inhibits the degradation of the antitoxic labile components Phd and MazE of these systems, which are substrates of ClpP proteases. We present a model for this anti-cell death effect of lambdaRexB through its action on the ClpP proteolytic subunit. We also propose that the lambdarex operon has an additional function to the well known phenomenon of exclusion of other phages; it can prevent the death of lysogenized cells under conditions of nutrient starvation. Thus, the rex operon may be considered as the "survival operon" of phage lambda.

The nature of the minimal 'selenocysteine insertion sequence' (SECIS) in Escherichia coli.

The UGA codon, usually a stop codon, can also direct the incorporation into a protein of the modified amino acid selenocysteine. This UGA decoding process requires a cis -acting mRNA element called 'selenocysteine insertion sequence' (SECIS) that can form a stem-loop structure. In Escherichia coli the SECIS of the selenoprotein formate dehydrogenase (FdhH) mRNA has been previously described to consist of at least 40 nucleotides following the UGA codon. Here we determined the nature of the minimal SECIS required for the in vivo UGA-directed selenocysteine incorporation in E.coli . Our study is based on extensive mutational analysis of the fdhF SECIS DNA located in a lac' Z fusion. We found that the whole stem-loop RNA structure of the E.coli fdhF SECIS previously described is not required for the UGA-directed selenocysteine incorporation in vivo . Rather, only its upper stem-loop structure of 17 nucleotides is necessary on the condition that it is located in a proper distance (11 nucleotides) from the UGA codon. Based on these observations, we present a new model for the minimal E.coli SECIS.

A rapid fluorescence bioassay for the determination of selenium on agar plates.

The essential trace element selenium (Se) is involved in the form of selenocysteine at the active site of several prokaryotic and eukaryotic proteins called selenoproteins. These proteins have recently attracted attention particularly in relation to their application to human health and new characteristics of the genetic code. We have recently described a selenium bioassay based on a recombinant DNA construct in which the expression of the lac' Z gene in Escherichia coli is proportionally and specifically driven by UGA-directed selenocysteine incorporation. Here we have further developed this bioassay for more rapid and sensitive detection and measurement of selenium that permits screening of the selenium status on agar plates. Again, the inclusion of selenium into the lac'Z-fusion product is reflected by the level of beta-galactosidase activity, which in turn is reflected by the intensity of fluorescence on agar plates. This fluorescing agent is a 4-methylumbelliferyl moiety which is released through the cleavage by the enzyme of 4-methylumbelliferyl-beta-D-galactoside. The intensity of the fluorescence is easily detected by uv irradiation and photographed by polaroid or video cameras.

A recombinant DNA bio-assay for selenium in blood.

The trace element selenium (Se) is included in the form of selenocysteine (Sec) at the active site of several prokaryotic and eukaryotic proteins known as selenoproteins (SePro). The growing implications of SePro in cell physiology and human health point to the need for an adequate means of assessing Se status in biological fluids. Here, we describe a new approach based on a recombinant DNA construct, in which the expression of the 'lacZ gene in Escherichia coli is proportionally and specifically driven by UGA-directed Sec incorporation. Se status is determined in samples of rat blood first treated by acid hydrolysis for protein degradation. As compared to other methods, this simple, sensitive bioassay (BIO) for determining Se status seems to be unique in its ability to measure all functional Sec residues in SePro in blood serum.

A bioassay based on recombinant DNA technology for determining selenium concentration.

The trace element selenium has recently attracted attention, particularly because (i) selenocysteine is involved in the active site of various prokaryotic and eukaryotic enzymes, some of which have a role in human health; (ii) selenocysteine incorporation into these proteins is coded by UGA codons; and (iii) as a result, selenocysteine is now considered to be the 21st amino acid in an expanded genetic code. Here, we built recombinant DNA constructs in which expression of the lac'Z gene is driven in Escherichia coli by UGA-directed selenocysteine incorporation. In this system, levels of beta-galactosidase activity are proportionally and specifically related to the presence and concentrations of several specific simple selenium derivatives. The system can thus be used as a sensitive bioassay for their determination. This bioassay is one of a few using recombinant DNA technology to provide a reporter for simple detection of a chemical trace element.

Influence of codon context on UGA suppression and readthrough.

We studied the influence of the codon context on UGA suppression by a suppressor tRNA and on UGA readthrough by a normal tRNA in Escherichia coli. This was done by a series of constructs where only the immediate context of the TGA codon was varied by only one nucleotide at a time. For both UGA suppression and UGA readthrough the codon context had a similar influence according to the following rules. (1) The nature of the nucleotide immediately adjacent to the 3' side of the UGA is an important determinant; at that position the level of UGA translation is influenced by the nucleotides in the order A greater than G greater than C greater than U. (2) At extremely high or low levels of UGA translation this influence of the adjacent 3' nucleotide is not seen. (3) In all cases, the nature of both the nucleotide immediately adjacent to the 5' side of the codon and that following the base adjacent to the 3' side of the codon have little effect, if any, on UGA translation. The varying influence of the codon context effect on UGA translation is discussed in relation to its role in gene expression.

DNA sequence and regulation of ermD, a macrolide-lincosamide-streptogramin B resistance element from Bacillus licheniformis.

The DNA sequence of ermD , a macrolide-lincosamide-streptogramin B (MLS) resistance determinant cloned from the chromosome of Bacillus licheniformis, has been determined. ermD encodes an erythromycin inducible protein of molecular weight 32,796. S1 nuclease mapping of the ermD promoter has revealed the presence of an approximately 354 base leader sequence on the ermD transcript. This leader contains a short open reading frame sufficient to encode a 14 amino acid peptide, which is preceded by a potential ribosomal binding site. The leader sequence has the potential to fold into several base paired structures, in some of which the ribosomal binding site for the ermD product would be sequestered. Deletion analysis demonstrated that the leader contains regulatory sequences. Removal of the ermD promoter and fusion to an upstream promoter did not interfere with induction, strongly suggestion that ermD regulation is posttranscriptional. Based on these features it appears likely that ermD is regulated by a translational attenuation mechanism, analogous to that suggested for ermC , a resistance element from Staphylococcus aureus ( Gryczan et al. 1980; Horinouchi and Weisblum 1980). Comparison of the ermD sequence and that of its product to two other sequenced MLS determinants reveals substantial phylogenetic relatedness, although the three genes are not homologous by the criterion of Southern blot hybridization.

Evolutionary relationships of the Bacillus licheniformis macrolide-lincosamide-streptogramin B resistance elements.

Naturally occurring erythromycin (Em) resistance was found in 11 of the 18 Bacillus licheniformis isolates tested but was absent from a wide variety of other Bacillus strains. The Em resistance elements confer inducible macrolide-lincosamide-streptogramin B (MLS) resistance and are related to ermD , an MLS resistance element previously cloned from the chromosome of B. licheniformis 749. The MLS sensitive B. licheniformis strains and the other sensitive Bacillus strains tested, lack sequences with detectable homology to ermD . The sensitive B. licheniformis strains do exhibit homology to sequences which flank ermD in B. licheniformis 749. The relative sizes of the homologous DNA fragments suggest that the sensitive strains are lacking a 3.6 kb segment which contains ermD . It is shown that ermD is homologous to chromosomal DNA from Streptomyces erythreus ATCC 11635, an Em producing organism. These observations suggest to us that MLS resistance may have arisen in the Streptomyces and spread to B. licheniformis, another gram positive bacterium found in soil. It is further proposed that ermD is or was located on a transposon-like element and has spread and evolved further to yield a variety of related Staphylococcal and Streptococcal MLS determinants.

Induction of macrolide-lincosamide-streptogramin B resistance requires ribosomes able to bind inducer.

Plasmids were constructed containing the regulatory regions and N-terminal portions of ermC and of ermD , fused in phase with the coding sequence of the Escherichia coli lacZ gene. ermC and ermD are erythromycin (Em) inducible macrolide-lincosamide-streptogramin B resistance elements derived from Staphylococcus aureus and Bacillus licheniformis, respectively. The fusion plasmids were introduced into B. subtilis and used to study ermC and ermD regulation. In both cases, beta-galactosidase synthesis could be induced by low levels of Em. Induction was prevented by introduction of ole-2, a chromosomal mutation which decreases ribosomal affinity for Em. Induction also did not occur in the presence of intact copies of ermC , suggesting that prior or concomitant methylation of 23S rRNA, a treatment known to decrease ribosomal affinity for Em, was capable of interfering with ermC and ermD induction. These experiments are consistent with the translational attenuation model of ermC regulation, and together with other evidence, suggest that ermD is regulated by a similar mechanism.

Q beta-defective particles produced in a streptomycin-resistant Escherichia coli mutant.

This paper describes Q beta noninfectious particles produced at 41 degrees C in a streptomycin-resistant Escherichia coli mutant which is temperature sensitive for suppression of a nonsense codon. The noninfectious particles resembled Q beta under the electron microscope and contained coat protein molecules in an amount similar to the amount in Q beta. However, they did not adsorb to F-piliated bacteria, and they were deficient in both minor capsid proteins of Q beta, maturation (IIa) and read-through (IIb). Proteins IIa and IIb were not produced in Qbeta-infected mutant cells at 41 degrees C. In addition, instead of the 30S RNA of Q beta, a shorter RNA, which sedimented mainly at 23 S, was found in the defective particles. The results are discussed in relation to the roles of proteins IIa and IIb of Q beta.

The requirement of nonsense suppression for the development of several phages.

A spontaneous streptomycin-resistant Escherichia coli mutant which is temperature-sensitive for suppression of a nonsense codon was studied for its ability to propagate phages T2, T4D, T5, phi K, f2, MS2, R17, Q beta, lambda as well as filamentous phages fl, fd and M13. Of all phages tested, only the growth of Q beta, lambda, and filamentous phages is inhibited in the mutant at 42 degree C. This selective inhibition suggests that, like Q beta, lambda and filamentous phages also require a read-through proten(s) which results from suppression of a termination codon.

Streptomycin-resistant Escherichia coli mutant temperature sensitive for the production of Qbeta-infective particles.

A streptomycin-resistant Escherichia coli mutant has been isolated that is temperature sensitive for Qbeta phage, but not for the group I RNA phages f2, MS2, and R17. The growth of Qbeta in the mutant at the nonpermissive temperature (42 degrees C) results in the release of a near-normal burst of noninfectious particles that cosediment with Qbeta in a sucrose gradient. It is assumed that the mutant is defective at elevated temperatures in the suppression of nonsense codons, thereby producing Qbeta-like particles which are noninfectious because of the lack of the read-through protein A1.

Discriminative effect of rifampin of RNA replication of various RNA bacteriophages.

Rifampin interferes exclusively with RNA replication in vivo of the group I phages MS2, f2, and R17, whereas QbetaRNA replication is unaffected by the drug. In addition, rifampin has a discriminative effect of group I phage RNA replication. In the experimental system employed by us the antibiotic differentially interferes with the synthesis of minus RNA strands in f2, whereas it has almost no effect on the synthesis of progeny plus strands. In MS2, the drug differentially arrests the synthesis of progeny plus strands and almost fails to affect the synthesis of minus RNA strands. In R17 both steps of its RNA replication are affected by rifampin, although each step is only partially (approximately 50%) inhibited. The relation of the present results to the possible role of bacterial proteins and tertiary structure of phage RNA in the process of template recognition is discussed.