Genetic studies of the lac repressor. XIII. Extensive amino acid replacements generated by the use of natural and synthetic nonsense suppressors.

We have altered the amino acid sequence of the lac repressor one residue at a time by utilizing a collection of nonsense suppressors that permit the insertion of 13 different amino acids in response to the amber (UAG) codon, as well as an additional amino acid in response to the UGA codon. We used this collection to suppress nonsense mutations at 141 positions in the lacI gene, which encodes the 360 amino acid long lac repressor, including 53 new nonsense mutations which we constructed by oligonucleotide-directed mutagenesis. This method has generated over 1600 single amino acid substitutions in the lac repressor. We have cataloged the effects of these replacements and have interpreted the results with the objective of gaining a better understanding of lac repressor structure, and protein structure in general. The DNA binding domain of the repressor, involving the amino-terminal 59 amino acids, is extremely sensitive to substitution, with 70% of the replacements resulting in the I- phenotype. However, the remaining 301 amino acid core of the repressor is strikingly tolerant of substitutions, with only 30% of the amino acids introduced causing the I- phenotype. This analysis reveals the location of sites in the protein involved in inducer binding, tighter binding to operator and thermal stability, and permits a virtual genetic image reconstruction of the lac repressor protein.

Genetic studies of the lac repressor. XIV. Analysis of 4000 altered Escherichia coli lac repressors reveals essential and non-essential residues, as well as "spacers" which do not require a specific sequence.

Amber mutations have been constructed at 328 positions, corresponding to residues 2 to 329 in the E. coli lac repressor protein. Synthetic and naturally occurring nonsense suppressors have been used to insert, in series, 12-13 amino acids at positions specified by an amber (UAG) codon in the lacI mRNA. The resulting set of over 4000 single amino acid replacements in the lac repressor protein allows a detailed analysis of its substitution tolerance along the linear array of residues, and reveals structure-function relationships in lac repressor and in proteins in general. (1) There are two main regions in the repressor which are extremely sensitive to amino acid replacements. One, the amino-terminal 59 residues, has been implicated in DNA and operator binding by a large body of work. The second, extending from approximately residues 239 to 289/292, forms the repressor core and shares the most homology with other repressor and DNA binding proteins. (2) Throughout the rest of the protein, segments of 6 to 14 amino acids, which are highly tolerant to single amino acid replacements, appear to act as "spacers" between one or several hydrophobic residues that are relatively intolerant to substitutions. (3) We have replaced the amino acids in these tolerant regions with spans of alanine residues, from 5 to 13 amino acids. In all five of the regions tested, alanine replacements, sometimes of up to 8 amino acids, still allowed functional repressor, while deletion of the same residues destroyed repressor function. This reinforces the view that many regions of a protein do not require a specific sequence to serve as spacers between more important residues. (4) A distinct pattern of substitutions leading to the I(s) phenotype suggests the location of residues involved in inducer binding. (5) A number of general substitution patterns can be recognized. For instance, proline is not tolerated at over 40 sites which tolerate all the other amino acid replacements. Another set of sites tolerates only non-polar amino acids, whereas a third set tolerates a subset of the smallest amino acids, (serine, alanine, glycine and cysteine, and sometimes threonine and valine). (5) Overall, 93 of 328 sites (28%) tolerate all 13 amino acids tested, and 144 of 328 (44%) tolerate 12/13 or all 13 substitutions. We judge that 192 of 328 sites (59%) are generally tolerant to substitutions.

Genetic studies of the Lac repressor. XV: 4000 single amino acid substitutions and analysis of the resulting phenotypes on the basis of the protein structure.

Each amino acid from position 2 to 329 of Lac repressor was replaced by 12 or 13 of the 20 natural occurring amino acids. The resulting phenotypes are discussed on the basis of (1) the recently published structure of the Lac repressor core complexed with the inducer IPTG and (2) a model of the dimeric Lac repressor built by homology modelling from the X-ray structure of the purine repressor-corepressor-operator complex. This phenotype analysis, based on 4000 well-defined mutants, yields a functional description of each amino acid position of Lac repressor. In most cases, mutant effects can be directly correlated with the structure and function of the protein. This connection between the amino acid position and the structure and function of the protein is in most cases direct and not complicated: amino acids which are directly involved in sugar binding are affected in Lac repressor mutants of the Is type; small amino acids which can only be replaced by other small acids are located in the core of the protein; positions at which nearly all amino acids are tolerated are in most cases located on the surface of the protein. Amino acids which are highly conserved throughout the LacI family of repressors, and not directly involved in specific functions of the protein like DNA recognition or sugar binding, form a network of contacts with other amino acids. Such amino acids are either located inside one subunit, mostly at the interface between secondary structure elements, or are involved in the dimerisation interface.

Construction of Escherichia coli amber suppressor tRNA genes. II. Synthesis of additional tRNA genes and improvement of suppressor efficiency.

Using synthetic oligonucleotides, we have constructed 17 tRNA suppressor genes from Escherichia coli representing 13 species of tRNA. We have measured the levels of in vivo suppression resulting from introducing each tRNA gene into E. coli via a plasmid vector. The suppressors function at varying efficiencies. Some synthetic suppressors fail to yield detectable levels of suppression, whereas others insert amino acids with greater than 70% efficiency. Results reported in the accompanying paper demonstrate that some of these suppressors insert the original cognate amino acid, whereas others do not. We have altered some of the synthetic tRNA genes in order to improve the suppressor efficiency of the resulting tRNAs. Both tRNA(CUAHis) and tRNA(CUAGlu) were altered by single base changes, which generated -A-A- following the anticodon, resulting in a markedly improved efficiency of suppression. The tRNA(CUAPro) was inactive, but a hybrid suppressor tRNA consisting of the tRNA(CUAPhe) anticodon stem and loop together with the remainder of the tRNA(Pro) proved highly efficient at suppressing nonsense codons. Protein chemistry results reported in the accompanying paper show that the altered tRNA(CUAHis) and the hybrid tRNA(CUAPro) insert only histidine and proline, respectively, whereas the altered tRNA(CUAGlu) inserts principally glutamic acid but some glutamine. Also, a strain deficient in release factor I was employed to increase the efficiency of weak nonsense suppressors.

Construction of Escherichia coli amber suppressor tRNA genes. III. Determination of tRNA specificity.

Using synthetic oligonucleotides, we have constructed a collection of Escherichia coli amber suppressor tRNA genes. In order to determine their specificities, these tRNAs were each used to suppress an amber (UAG) nonsense mutation in the E. coli dihydrofolate reductase gene fol. The mutant proteins were purified and subjected to N-terminal sequence analysis to determine which amino acid had been inserted by the suppressor tRNAs at the position of the amber codon. The suppressors can be classified into three groups on the basis of the protein sequence information. Class I suppressors, tRNA(CUAAla2), tRNA(CUAGly1), tRNA(CUAHisA), tRNA(CUALys) and tRNA(CUAProH), inserted the predicted amino acid. The class II suppressors, tRNA(CUAGluA), tRNA(CUAGly2) and tRNA(CUAIle1) were either partially or predominantly mischarged by the glutamine aminoacyl tRNA synthetase. The class III suppressors, tRNA(CUAArg), tRNA(CUAAspM), tRNA(CUAIle2), tRNA(CUAThr2), tRNA(CUAMet(m)) and tRNA(CUAVal) inserted predominantly lysine.

Cave biosignature suites: microbes, minerals, and Mars.

Earth's subsurface offers one of the best possible sites to search for microbial life and the characteristic lithologies that life leaves behind. The subterrain may be equally valuable for astrobiology. Where surface conditions are particularly hostile, like on Mars, the subsurface may offer the only habitat for extant lifeforms and access to recognizable biosignatures. We have identified numerous unequivocally biogenic macroscopic, microscopic, and chemical/geochemical cave biosignatures. However, to be especially useful for astrobiology, we are looking for suites of characteristics. Ideally, "biosignature suites" should be both macroscopically and microscopically detectable, independently verifiable by nonmorphological means, and as independent as possible of specific details of life chemistries--demanding (and sometimes conflicting) criteria. Working in fragile, legally protected environments, we developed noninvasive and minimal impact techniques for life and biosignature detection/characterization analogous to Planetary Protection Protocols. Our difficult field conditions have shared limitations common to extraterrestrial robotic and human missions. Thus, the cave/subsurface astrobiology model addresses the most important goals from both scientific and operational points of view. We present details of cave biosignature suites involving manganese and iron oxides, calcite, and sulfur minerals. Suites include morphological fossils, mineral-coated filaments, living microbial mats and preserved biofabrics, 13C and 34S values consistent with microbial metabolism, genetic data, unusual elemental abundances and ratios, and crystallographic mineral forms.

Antiviral effects of a thiol protease inhibitor on foot-and-mouth disease virus.

The thiol protease inhibitor E-64 specifically blocks autocatalytic activity of the leader protease of foot-and-mouth disease virus (FMDV) and interferes with cleavage of the structural protein precursor in an in vitro translation assay programmed with virion RNA. Experiments with FMDV-infected cells and E-64 or a membrane-permeable analog, E-64d, have confirmed these results and demonstrated interference in virus assembly, causing a reduction in virus yield. In addition, there is a lag in the appearance of virus-induced cellular morphologic alterations, a delay in cleavage of host cell protein p220 and in shutoff of host protein synthesis, and a decrease in viral protein and RNA synthesis. The implications of using E-64-based compounds as potential antiviral agents for FMDV are discussed.

Construction of two Escherichia coli amber suppressor genes: tRNAPheCUA and tRNACysCUA.

Amber suppressor genes corresponding to Escherichia coli tRNAPhe and tRNACys have been constructed for use in amino acid substitution studies as well as protein engineering. The genes for either tRNAPheGAA or tRNACysGCA both with the anticodon 5' CTA 3' were assembled from four to six oligonucleotides, which were annealed and ligated into a vector. The suppressor genes are expressed constitutively from a synthetic promoter, derived from the promoter sequence of the E. coli lipoprotein gene. The tRNAPhe suppressor (tRNAPheCUA) is 54-100% efficient in vivo, while the tRNACys suppressor (tRNACysCUA) is 17-50% efficient. To verify that the suppressors insert the predicted amino acids, both genes were used to suppress an amber mutation in a protein coding sequence. NH2-terminal sequence analysis of the resultant proteins revealed that tRNAPheCUA and tRNACysCUA insert phenylalanine and cysteine, respectively. To demonstrate the potential of these suppressors, tRNAPheCUA and tRNACysCUA have been used to effect amino acid substitutions at specific sites in the E. coli lac repressor.

Protein engineering with synthetic Escherichia coli amber suppressor genes.

We have constructed synthetic genes encoding different Escherichia coli suppressor tRNAs for use in amino acid substitution studies and protein engineering. We used oligonucleotides to assemble the genes for different tRNAs with the anticodon 5' CTA 3'. The suppressor genes are expressed from a synthetic promoter derived from the promoter sequence of the E. coli lipoprotein gene. The genes have been used to suppress an amber mutation in a protein coding sequence, and the resulting altered protein has been subjected to sequence analysis to determine the nature of the amino acid inserted at the amber site. Twelve amino acids can now be added in response to the amber codon. We have employed these suppressors to study amino acid substitutions in the lac repressor.