Features of the formate dehydrogenase mRNA necessary for decoding of the UGA codon as selenocysteine

The 5' untranslated region of the human cellular glutathione peroxidase gene is indispensable for its expression in COS-7 cells

We studied the expression of the human cellular glutathione peroxidase (GPx) gene, from which a key enzyme containing selenocysteine (Scy) at the active site is produced. Expression of some human GPx gene mutants in COS-7 cells revealed that the 5' untranslated region (utr) was necessary for expression of the GPx gene, since mutant genes having 10 base pairs (bps) at the 5'utr (the complete had 311 bps) expressed GPx at very low levels. The genes with 311 or 408 bps at the 5'utr were better expressed than those having 257 bps. The GPx gene having 133 bps at the 3'utr (80 bps shorter than the entire length) was highly expressed. This deletion did not influence expression. We constructed some mutants in which 3 bases were altered at the upstream region of the Scy UGA codon in the frame of the GPx gene, by site-directed mutagenesis. GPx expression decreased but the expression was restored. Therefore, the upstream region of the in-frame Scy codon was not essential in the Scy decoding mechanisms. Finally, the 5'utr was essential for the expression of GPx gene. However, the deletion of a part of the 3'utr and the site-directed mutation upstream of the Scy codon did not show drastic effects on the expression.

Clostridium sticklandii glycine reductase selenoprotein A gene: cloning, sequencing, and expression in Escherichia coli

Gene grdA, which encodes selenoprotein A of the glycine reductase complex from Clostridium sticklandii, was identified and characterized. This gene encodes a protein of 158 amino acids with a calculated M(r) of 17,142. The known sequence of 15 amino acids around the selenocysteine residue and the known carboxy terminus of the protein are correctly predicted by the nucleotide sequence. An opal termination codon (TGA) corresponding to the location of the single selenocysteine residue in the polypeptide was found in frame at position 130. The C. sticklandii grdA gene was inserted behind the tac promotor of an Escherichia coli expression vector. An E. coli strain transformed with this vector produced an 18-kDa polypeptide that was not detected in extracts of nontransformed cells. Affinity-purified anti-C. sticklandii selenoprotein A immunoglobulin G reacted specifically with this polypeptide, which was indistinguishable from authentic C. sticklandii selenoprotein A by immunological analysis. Addition of the purified expressed protein to glycine reductase protein components B and C reconstituted the active glycine reductase complex. Although synthesis of enzymically active protein A depended on the presence of selenium in the growth medium, formation of immunologically reactive protein did not. Moreover, synthesis of enzymically active protein in a transformed E. coli selD mutant strain indicated that there is a nonspecific mechanism of selenocysteine incorporation. These findings imply that mRNA secondary structures of C. sticklandii grdA are not functional for UGA-directed selenocysteine insertion in the E. coli expression system.

Codon context effect in virus translational readthrough. A study in vitro of the determinants of TMV and Mo-MuLV amber suppression

To assess the role of codon context on the efficiency of eukaryotic suppression of termination codons, we have compared, in a rabbit cell-free translation system, the readthrough efficiency related to two synthetic transcripts differing by the codon context around an amber codon. The codon contexts are derived from tobacco mosaic virus (TMV) and Moloney murine leukemia virus (Mo-MuLV) RNAs. The Mo-MuLV-like codon context does not promote suppression. Substituting TMV-derived triplets in the Mo-MuLV-like codon context shows that the two codons downstream from the TMV UAG signal are important determinants of suppression, as recently demonstrated in vivo.

Identification of the major soluble cuticular glycoprotein of lymphatic filarial nematode parasites (gp29) as a secretory homolog of glutathione peroxidase

We have cloned and identified the major cuticular glycoprotein (gp29) of lymphatic filarial nematode parasites as a homolog of the antioxidant enzyme glutathione peroxidase. The derived amino acid sequence predicted a protein of 25.8 kDa, with an amino-terminal hydrophobic signal peptide and two sites for N-linked glycosylation, consistent with the documented properties of gp29. Transcription of a full-length cDNA in an SP65 vector and subsequent translation of the RNA in reticulocyte lysates in vitro generated a protein of 27 kDa, which was glycosylated upon the addition of pancreatic microsomal membranes. A postulated role for this secreted enzyme could be inhibition of the oxidative burst of leukocytes and neutralization of secondary products of lipid peroxidation, thus providing one explanation for the resistance of these parasites to immune effector mechanisms and their persistence in the mammalian host.

Some properties of murine selenocysteine synthase

Selenocysteine (Scy) was synthesized on natural opal suppressor tRNA(Ser) by conversion from seryl-tRNA. We studied the mechanisms of the synthesis of mammalian Scy-tRNA using hydro[75Se]selenide (H75Se-). We found Scy synthase activity in the 105,000 g supernatant of a murine liver extract. The supernatant was chromatographed on DEAE-cellulose, and the activity was eluted at 0.12 M-KCl. The reaction mixture for synthesis of Scy-tRNA contained suppressor tRNA, serine, ATP, seryl-tRNA synthetase (SerRS), HSe- and the enzyme to synthesize Scy-tRNA. These are all essential for the synthesis of Scy-tRNA. Scy in the tRNA product was confirmed by five t.l.c. systems. The conversion from seryl-tRNA to Scy-tRNA was also confirmed with the use of [14C]- and [3H]-serine. The apparent Km values for the substrates serine, tRNA, ATP and HSe- were 30 microM, 140 nM, 2 mM and 40 nM respectively. The active eluates from DEAE-cellulose contained no tRNA kinase. This result showed that Scy-tRNA was not synthesized through phosphoseryl-tRNA. ATP was necessary when Scy-tRNA was synthesized from seryl-tRNA and HSe-. Therefore ATP is used for not only the synthesis of seryl-tRNA but also for the synthesis of Scy-tRNA from seryl-tRNA. The active fraction from DEAE-cellulose was chromatographed on Sephacryl S-300, but the activity disappeared. However, the activity was recovered by mixing the eluates corresponding to proteins of 500 kDa and 20 kDa. In order to examine the binding of HSe- to proteins, a mixture of the active fraction, H75Se- and ATP was analysed by chromatography on Sephacryl S-300. The 75Se radioactivity was found at the position of a 20 kDa protein in the presence of ATP. Thus the 20 kDa protein plays a role in binding HSe- in the presence of ATP. The 500 kDa protein must have a role in the synthesis of Scy-tRNA. There are two natural suppressor serine tRNAs, tRNA(NCA) and tRNA(CmCA), in cell cytosol. The present paper shows that the suppressor tRNA fraction, eluted later on benzoylated DEAE-(BD-)cellulose, is a better substrate with which to synthesize Scy-tRNA. Thus we consider that murine Scy-tRNA is synthesized from a suppressor seryl-tRNA on the 500 kDa protein with the activated HSe-, which is synthesized with ATP on the 20 kDa protein. This mammalian mechanism used to synthesize Scy is similar to that seen in Escherichia coli.

Methanococcus voltae harbors four gene clusters potentially encoding two [NiFe] and two [NiFeSe] hydrogenases, each of the cofactor F420-reducing or F420-non-reducing types

Four gene clusters were identified in Methanococcus voltae which probably all encode hydrogenases of the [NiFe] type. One of these contains four genes, including those for the three subunits of the known [NiFeSe] hydrogenase capable of reducing the natural deazaflavin cofactor F420. In a second homologous cluster, the gene encoding the subunit corresponding to that which contains selenium in the known enzyme has a cysteine codon in the relevant position. In addition, two more gene clusters were detected which are very similar both in gene order and sequence to one which encodes a hydrogenase that reduces viologens in Methanobacterium thermoautotrophicum, but whose natural electron acceptor is as yet unknown. Again, in one of these clusters, one of the structural genes, which codes for a hydrogenase subunit containing the putative Ni-binding site, contains a selenocysteine codon. The homologous gene in the other clusters again shows a cysteine codon in the corresponding location. The four gene clusters are closely linked. Those encoding the two selenium-free enzymes are arranged in opposite polarities with a relatively short intergenic region. This arrangement is discussed in terms of a possible joint transcriptional regulation.

Recent evidence for evolution of the genetic code

The genetic code, formerly thought to be frozen, is now known to be in a state of evolution. This was first shown in 1979 by Barrell et al. (G. Barrell, A. T. Bankier, and J. Drouin, Nature [London] 282:189-194, 1979), who found that the universal codons AUA (isoleucine) and UGA (stop) coded for methionine and tryptophan, respectively, in human mitochondria. Subsequent studies have shown that UGA codes for tryptophan in Mycoplasma spp. and in all nonplant mitochondria that have been examined. Universal stop codons UAA and UAG code for glutamine in ciliated protozoa (except Euplotes octacarinatus) and in a green alga, Acetabularia. E. octacarinatus uses UAA for stop and UGA for cysteine. Candida species, which are yeasts, use CUG (leucine) for serine. Other departures from the universal code, all in nonplant mitochondria, are CUN (leucine) for threonine (in yeasts), AAA (lysine) for asparagine (in platyhelminths and echinoderms), UAA (stop) for tyrosine (in planaria), and AGR (arginine) for serine (in several animal orders) and for stop (in vertebrates). We propose that the changes are typically preceded by loss of a codon from all coding sequences in an organism or organelle, often as a result of directional mutation pressure, accompanied by loss of the tRNA that translates the codon. The codon reappears later by conversion of another codon and emergence of a tRNA that translates the reappeared codon with a different assignment. Changes in release factors also contribute to these revised assignments. We also discuss the use of UGA (stop) as a selenocysteine codon and the early history of the code.

Overproduction of a selenocysteine-containing polypeptide in Escherichia coli: the fdhF gene product

The fdhF gene of Escherichia coli codes for the selenocysteine-including protein subunit of formate dehydrogenase H. The protein subunit consists of 715 amino acid residues containing a single selenocysteine residue at position 140 which is encoded by a UGA codon. The decoding of this opal termination codon occurs under anaerobic growth conditions by means of a specific tRNA, i.e. the selC gene product. The ability of E. coli cells to overproduce a selenopolypeptide was examined using the fdhF gene as a model system. Surprisingly, E. coli was able to synthesize the fdhF gene product at the level of approximately 12% of the total cellular protein. This was achieved by cloning fdhF in a multicopy plasmid together with a synthetic selC gene under the Ipp promoter. FdhF production was absolutely dependent upon the addition of selenium to the culture medium and was almost completely blocked in the presence of oxygen. The product was specifically labelled with 75Se, proving that it consisted of a selenoprotein. The product was purified to homogeneity and shown to exhibit the catalytic properties characteristic of formate dehydrogenase H.

Targeted insertion of selenocysteine into the alpha subunit of formate dehydrogenase from Methanobacterium formicicum

Selenocysteine incorporation into proteins is directed by an opal (UGA) codon and requires the existence of a stem-loop structure in the mRNA flanking the UGA at its 3' side. To analyze the sequence and secondary-structure requirements for UGA decoding, we have introduced mutations into the fdhA gene from Methanobacterium formicicum, which codes for the alpha subunit of the F420-reducing formate dehydrogenase. The M. formicicum enzyme contains a cysteine residue at the position where the Escherichia coli formate dehydrogenase H carries a selenocysteine moiety. The codon (UGC) for this cysteine residue was changed into a UGA codon, and mutations were successively introduced at the 5' and 3' sides to generate a stable secondary structure of the mRNA and to approximate the sequence of the predicted E. coli fdhF mRNA hairpin structure. It was found that introduction of the UGA and generation of a stable putative stem-loop structure were not sufficient for decoding with selenocysteine. Efficient selenocysteine incorporation, however, was obtained when the loop and the immediately adjacent portion of the putative stem had a sequence identical to that present in the E. coli fdhF mRNA structure.

Ribosomal frameshifting, jumping and readthrough

New examples of high-level ribosomal frameshift and readthrough events have been described over the past year and a half. These include -1 frameshifting at tandem codons and +1 frameshifting at neighboring slow codons. Several bizarre examples of ribosome jumping and multiple stop-codon readthrough continue to perplex investigators in this field.

[Biology and biochemistry of selenium]

The importance of selenium as an essential trace element has progressively emerged during the last years due to the analysis of selenium deficiency diseases and to the identification and characterization of a number of selenoenzymes. Selenium is incorporated in the catalytic site of the enzymes as an integral selenocysteine residue. The pathway of selenocysteine biosynthesis and incorporation has been elucidated recently for Escherichia coli. This article presents an overview on these subjects and describes the mechanisms which confer selenocysteine specificity in the framework of protein biosynthesis. In addition, some considerations concerning the phylogeny of selenocysteine incorporation are presented and a model for the evolution of the selenocysteine pathway is proposed.

Catalytic properties of an Escherichia coli formate dehydrogenase mutant in which sulfur replaces selenium

Formate dehydrogenase H of Escherichia coli contains selenocysteine as an integral amino acid. We have purified a mutant form of the enzyme in which cysteine replaces selenocysteine. To elucidate the essential catalytic role of selenocysteine, kinetic and physical properties of the mutant enzyme were compared with those of wild type. The mutant and wild-type enzymes displayed similar pH dependencies with respect to activity and stability, although the mutant enzyme profiles were slightly shifted to more alkaline pH. Both enzymes were inactivated by reaction with iodoacetamide; however, addition of the substrate, formate, was necessary to render the enzymes susceptible to alkylation. Alkylation-induced inactivation was highly dependent on pH, with each enzyme displaying an alkylation vs. pH profile suggestive of an essential selenol or thiol. Both forms of the enzyme use a ping-pong bi-bi kinetic mechanism. The mutant enzyme binds formate with greater affinity than does the wild-type enzyme, as shown by reduced values of Km and Kd. However, the mutant enzyme has a turnover number which is more than two orders of magnitude lower than that of the native selenium-containing enzyme. The lower turnover number results from a diminished reaction rate for the initial step of the overall reaction, as found in kinetic analyses that employed the alternative substrate deuterioformate. These results indicate that the selenium of formate dehydrogenase H is directly involved in formate oxidation. The observed differences in kinetic properties may help explain the evolutionary conservation of selenocysteine at the enzyme's active site.

Recognition of UGA as a selenocysteine codon in type I deiodinase requires sequences in the 3' untranslated region

Selenocysteine is incorporated cotranslationally at UGA codons, normally read as stop codons, in several bacterial proteins and in the mammalian proteins glutathione peroxidase (GPX), selenoprotein P and Type I iodothyronine 5' deiodinase (5'DI). Previous analyses in bacteria have suggested that a stem-loop structure involving the UGA codon and adjacent sequences is necessary and sufficient for selenocysteine incorporation into formate dehydrogenase and glycine reductase. We used the recently cloned 5'DI to investigate selenoprotein synthesis in eukaryotes. We show that successful incorporation of selenocysteine into this enzyme requires a specific 3' untranslated (3'ut) segment of about 200 nucleotides, which is found in both rat and human 5'DI messenger RNAs. These sequences are not required for expression of a cysteine-mutant deiodinase. Although there is little primary sequence similarity between the 3'ut regions of these mRNAs and those encoding GPX, the 3'ut sequences of rat GPX can substitute for the 5'DI sequences in directing selenocysteine insertion. Computer analyses predict similar stem-loop structures in the 3'ut regions of the 5'DI and GPX mRNAs. Limited mutations in these structures reduce or eliminate their capacity to permit 5'DI translation. These results identify a 'selenocysteine-insertion sequence' motif in the 3'ut region of these mRNAs that is essential for successful translation of 5'DI, presumably GPX, and possibly other eukaryotic selenocysteine-containing proteins.

Study of mammalian selenocysteyl-tRNA synthesis with [75Se]HSe

The mechanisms of the synthesis of mammalian selenocysteyl-(Scy)-tRNA were studied using [75SE]H2Se. H2Se was prepared from [75Se]selenite, glutathione, NADPH and glutathione reductase, and was purified by chromatography. It was confirmed that this H2Se was a Se donor in the reaction of the synthesis of Scy-tRNA. [75Se]Scy, liberated from aminoacyl-tRNA, was analyzed by TLC on silica gel an subsequent autoradiography. The activity of Scy-tRNA synthesis was found in the supernatant at 105,000 x g of the murine liver extract, but not in the precipitate. The supernatant was chromatographed on DEAE-cellulose, and the activity was eluted at a concentration of 0.17 M KCl. This position is at the front shoulder of the peak of seryl-tRNA synthetase which was eluted at 0.20 M KCl. Major serine tRNA(IGA) is not a substrate on which to synthesize Scy-tRNA, but natural opal suppressor serine tRNA is. On a chromatographic pattern of a Scy-tRNA preparation on Sephacryl S-200, the radioactivity of 75Se was eluted at the tRNA peak. This showed that Scy bound to tRNA. The active protein fraction from DEAE-cellulose did not contain tRNA kinase, therefore Scy-tRNA must be directly synthesized from seryl-tRNA, not through phosphoseryl-tRNA. This mechanism is similar to that seen in Escherichia coli [1991, J. Biol. Chem. 266, 6324].

Evidence that a downstream pseudoknot is required for translational read-through of the Moloney murine leukemia virus gag stop codon

Approximately 5% of the ribosomes translating the gag gene of murine leukemia viruses read through the UAG terminator and translate the in-frame pol gene to produce the gag-pol fusion polyprotein, the sole source of the pol gene products. We show that a pseudoknot located eight nucleotides 3' of the UAG codon in the Moloney murine leukemia virus is required for read-through. This requirement is markedly different from that known to be involved in other cases of read-through but surprisingly similar to some stimulatory sequences known to promote ribosomal frameshifting.

Expression and operon structure of the sel genes of Escherichia coli and identification of a third selenium-containing formate dehydrogenase isoenzyme

A detailed analysis of the expression of the sel genes, the products of which are necessary for the specific incorporation of selenium into macromolecules in Escherichia coli, showed that transcription was constitutive, being influenced neither by aerobiosis or anaerobiosis nor by the intracellular selenium concentration. The gene encoding the tRNA molecule which is specifically aminoacylated with selenocysteine (selC) proved to be monocistronic. In contrast, the other three sel genes (selA, -B, and -D) were shown to be constituents of two unlinked operons. The selA and selB genes formed one transcriptional unit (sel vector AB), while selD was shown to be the central gene in an operon including two other genes, the promoter distal of which (topB) encodes topoisomerase III. The promoter proximal gene (orf183) was sequenced and shown to encode a protein consisting of 183 amino acids (Mr, 20,059), the amino acid sequence of which revealed no similarity to any currently known protein. The products of the orf183 and topB genes were required neither for selenoprotein biosynthesis nor for selenation of tRNAs. selAB transcription was driven by a single, weak promoter; however, two major selD operon transcripts were identified. The longer initiated just upstream of the orf183 gene, whereas the 5' end of the other mapped in a 116-bp nontranslated region between orf183 and selD. Aerobic synthesis of all four sel gene products incited a reexamination of a weak 110-kDa selenopolypeptide which is produced under these conditions. The aerobic appearance of this 110-kDa selenopolypeptide was not a consequence of residual expression of the gene encoding the 110-kDa selenopolypeptide of the anaerobically inducible formate dehydrogenase N (FDHN) enzyme, as previously surmised, but rather resulted from the expression of a gene encoding a third, distinct selenopolypeptide in E. coli. A mutant strain no longer capable of synthesizing the 80- and 110-kDa selenopolypeptides of FDHH and FDHN, respectively, still synthesized this alternative 110-kDa selenopolypeptide which was present at equivalent levels in cells grown aerobically and anaerobically with nitrate. Furthermore, this strain exhibited a formate- and sel gene-dependent respiratory activity, indicating that it is probable that this selenopolypeptide constitutes a major component of the formate oxidase, an enzyme activity initially discovered in aerobically grown E. coli more than 30 years ago.

Selenocysteyl-tRNA occurs in the diatom Thalassiosira and in the ciliate Tetrahymena

Selenocysteyl-tRNAs that decode UGA were identified previously in animal and bacterial cells and the genes for these tRNAs have been shown to be widespread in animals and eubacteria. In the present study, we identify a selenocysteyl-tRNA that codes for UGA in Thalassiosira pseudonana, which is a diatom, and in Tetrahymena borealis, which is a ciliate. The fact that these very diverse unicellular organisms also contain a selenocysteyl-tRNA suggests that selenocysteine-containing proteins and the use of UGA as a codon for selenocysteine are widespread, if not ubiquitous, in nature.

Selenoprotein A component of the glycine reductase complex from Clostridium purinolyticum: nucleotide sequence of the gene shows that selenocysteine is encoded by UGA

The gene encoding the selenoprotein A component of glycine reductase was isolated from Clostridium purinolyticum. The nucleotide sequence of this gene (grdA) was determined. The opal termination codon (TGA) was found in-frame at the position corresponding to the location of the selenocysteine residue in the gene product. A comparison of the nucleotide sequences and secondary mRNA structures corresponding to the selenoprotein A gene and the fdhF gene of Escherichia coli formate dehydrogenase shows that there is a similar potential for regulation of the specific insertion of selenocysteine at the UGA codon.

Selenocysteine: the 21st amino acid

Great excitement was elicited in the field of selenium biochemistry in 1986 by the parallel discoveries that the genes encoding the selenoproteins glutathione peroxidase and bacterial formate dehydrogenase each contain an in-frame TGA codon within their coding sequence. We now know that this codon directs the incorporation of selenium, in the form of selenocysteine, into these proteins. Working with the bacterial system has led to a rapid increase in our knowledge of selenocysteine biosynthesis and to the exciting discovery that this system can now be regarded as an expansion of the genetic code. The prerequisites for such a definition are co-translational insertion into the polypeptide chain and the occurrence of a tRNA molecule which carries selenocysteine. Both of these criteria are fulfilled and, moreover, tRNASec even has its own special translation factor which delivers it to the translating ribosome. It is the aim of this article to review the events leading to the elucidation of selenocysteine as being the 21st amino acid.

Interspecies compatibility of selenoprotein biosynthesis in Enterobacteriaceae

Several species of Enterobacteriaceae were investigated for their ability to synthesize selenium-containing macromolecules. Seleniated tRNA species as well as seleniated polypeptides were formed by all organisms tested. Two selenopolypeptides could be identified in most of the organisms which correspond to the 80 kDa and 110 kDa subunits of the anaerobically induced formate dehydrogenase isoenzymes of E. coli. In those organisms possessing both isoenzymes, their synthesis was induced in a mutually exclusive manner dependent upon whether nitrate was present during anaerobic growth. The similarity of the 80 kDa selenopolypeptide among the different species was assessed by immunological and genetic analyses. Antibodies raised against the 80 kDa selenopolypeptide from E. coli cross-reacted with an 80 kDa polypeptide in those organisms which exhibited fermentative formate dehydrogenase activity. These organisms also contained genes which hybridised with the fdhF gene from E. coli. In an attempt to identify the signals responsible for incorporation of selenium into the selenopolypeptides in these organisms we cloned a portion of the fdhF gene homologue from Enterobacter aerogenes. The nucleotide sequence of the cloned 723 bp fragment was determined and it was shown to contain an in-frame TGA (stop) codon at the position corresponding to that present in the E. coli gene. This fragment was able to direct incorporation of selenocysteine when expressed in the heterologous host, E. coli. Moreover, the E. coli fdhF gene was expressed in Salmonella typhimurium, Serratia marcescens and Proteus mirabilis, indicating a high degree of conservation of the seleniating system throughout the enterobacteria.

Mutagenesis of selC, the gene for the selenocysteine-inserting tRNA-species in E. coli: effects on in vivo function

The selenocysteine-inserting tRNA (tRNA(Sec)) of E. coli differs in a number of structural features from all other elongator tRNA species. To analyse the functional implications of the deviations from the consensus, these positions have been reverted to the canonical configuration. The following results were obtained: (i) inversion of the purine/pyrimidine pair at position 11/24 and change of the purine at position 8 into the universally conserved U had no functional consequence whereas replacements of U9 by G9 and of U14 by A14 decreased the efficiency of selenocysteine insertion as measured by translation of the fdhF message; (ii) deleting one basepair in the aminoacyl acceptor stem, thus creating the canonical 7 bp configuration, inactivated tRNA(Sec); (iii) replacement of the extra arm by that of a serine-inserting tRNA abolished the activity whereas reduction by 1 base or the insertion of three bases partially reduced function; (iv) change of the anticodon to that of a serine inserter abolished the capacity to decode UGA140 whereas the alteration to a cysteine codon permitted 30% read-through. However, the variant with the serine-specific anticodon efficiently inserted selenocysteine into a gene product when the UGA140 of the fdhF mRNA was replaced by a serine codon (UCA). Significantly, none of these changes resulted in the non-specific incorporation of selenocysteine into protein, indicating that the mRNA context also plays a major role in directing insertion. Taken together, the results demonstrate that the 8-basepair acceptor stem and the long extra arm are crucial determinants of tRNA(Sec) which enable decoding of UGA140 in the fdhF message.

Genetic code 1990. Outlook

The genetic code is evolving as shown by 9 departures from the universal code: 6 of them are in mitochondria and 3 are in nuclear codes. We propose that these changes are preceded by disappearance of a codon from coding sequences in mRNA of an organism or organelle. The function of the codon that disappears is taken by other, synonymous codons, so that there is no change in amino acid sequences of proteins. The deleted codon then reappears with a new function. Wobble pairing between anticodons and codons has evolved, starting with a single UNN anticodon pairing with 4 codons. Directional mutation pressure affects codon usage and may produce codon reassignments, especially of stop codons. Selenocysteine is coded by UGA, which is also a stop codon, and this anomaly is discussed. The outlook for discovery of more changes in the code is favorable, and open reading frames should be compared with actual sequential analyses of protein molecules in this search.

Sequence analysis suggests that tetra-nucleotides signal the termination of protein synthesis in eukaryotes

An increasing number of cases where tri-nucleotide stop codons do not signal the termination of protein synthesis are being reported. In order to identify what constitutes an efficient stop signal, we analysed the region around natural stop codons in genes from a wide variety of eukaryotic species and gene families. Certain stop codons and nucleotides following stop codons are over-represented, and this pattern is accentuated in highly expressed genes. For example, the preferred signal for Saccharomyces cerevisiae and Drosophila melanogaster highly expressed genes is UAAG, and generally the signals UAA(A/G) and UGA(A/G) are preferred in eukaryotes. The GC% of the organism or DNA region can affect whether there is A or G in the second or fourth positions. We suggest therefore, that the stop codon and the nucleotide following it comprise a tetra-nucleotide stop signal. A model is proposed in which the polypeptide chain release factor, a protein, recognises this sequence, but will tolerate some substitution, particularly A to G in the second or third positions.

Downstream secondary structure facilitates recognition of initiator codons by eukaryotic ribosomes

Recognition of an AUG initiator codon in a suboptimal context improves when a modest amount of secondary structure is introduced near the beginning of the protein-coding sequence. This facilitating effect depends on the position of the downstream stem-loop (hairpin) structure. The strongest facilitation is seen when the hairpin is separated from the preceding AUG codon by 14 nucleotides. Because 14 nucleotides corresponds to the approximate distance between the leading edge of the ribosome and its AUG-recognition center as measured by ribonuclease protection experiments, a likely explanation for the enhancing effect of a downstream hairpin is that secondary structure slows scanning, thereby providing more time for recognition of the AUG codon, and the facilitation is greatest when the 40S ribosome stalls with its AUG-recognition center directly over the AUG. The variable ability of mammalian ribosomes to initiate at non-AUG codons in vitro is also explicable by the presence or absence of a stem-loop structure just downstream from the alternative initiator codon. This may be relevant to recent reports of adventitious upstream initiation events at non-AUG codons in some vertebrate mRNAs that have structure-prone, G + C-rich leader sequences.