Lars Liljas

Compensatory adaptation to the deleterious effect of antibiotic resistance in Salmonella typhimurium

Most chromosomal mutations that cause antibiotic resistance impose fitness costs on the bacteria. This biological cost can often be reduced by compensatory mutations. In Salmonella typhimurium, the nucleotide substitution AAA42 → AAC in the rpsL gene confers resistance to streptomycin. The resulting amino acid substitution (K42N) in ribosomal protein S12 causes an increased rate of ribosomal proofreading and, as a result, the rate of protein synthesis, bacterial growth and virulence are decreased. Eighty‐one independent lineages of the low‐fitness, K42N mutant were evolved in the absence of antibiotic to ameliorate the costs. From the rate of fixation of compensated mutants and their fitness, the rate of compensatory mutations was estimated to be ≥ 10−7 per cell per generation. The size of the population bottleneck during evolution affected fitness of the adapted mutants: a larger bottleneck resulted in higher average fitness. Only four of the evolved lineages contained streptomycin‐sensitive revertants. The remaining 77 lineages contained mutants that were still fully streptomycin resistant, had retained the original resistance mutation and also acquired compensatory mutations. Most of the compensatory mutations, resulting in at least 35 different amino acid substitutions, were novel single‐nucleotide substitutions in the rpsD, rpsE, rpsL or rplS genes encoding the ribosomal proteins S4, S5, S12 and L19 respectively. Our results show that the deleterious effects of a resistance mutation can be compensated by an unexpected variety of mutations.

Structure of Satellite tobacco necrosis virus at 3.0 Å resolution

Abstract The structure of Satellite tobacco necrosis virus (STNV) has been determined to 3.0 A resolution by X-ray crystallography. Electron density maps were obtained with phases based on one heavy-atom derivative and several cycles of phase refinement using the 60-fold non-crystallographic symmetry in the particle. A model for one protein subunit was built using a computer graphics display. The subunit is constructed mainly of a β-roll structure forming two β-sheets, each of four antiparallel strands. The N-termini of the subunits form bundles of three α-helices extending into the RNA region of the virus at the 3-fold axis. The topology of the polypeptide chain is the same as, and the conformation clearly similar to, that of the shell domains of the Tomato bushy stunt virus (TBSV) and Southern bean mosaic virus (SBMV) protein subunits. The subunit packing in the T = 1 STNV structure is, however, significantly different from the packing of these T = 3 viruses: parts of some of the structural elements facing the RNA in TBSV and SBMV are utilized for subunit-subunit contacts in STNV. No RNA structure is obvious in the present icosahedrally averaged electron density maps. The protein surface facing the RNA contains mainly hydrophilic residues, especially lysine and arginine.

The crystal structure of bacteriophage Qβ at 3.5 å resolution

Abstract Background: The capsid protein subunits of small RNA bacteriophages form a T=3 particle upon assembly and RNA encapsidation. Dimers of the capsid protein repress translation of the replicase gene product by binding to the ribosome binding site and this interaction is believed to initiate RNA encapsidation. We have determined the crystal structure of phage Qβ with the aim of clarifying which factors are the most important for particle assembly and RNA interaction in the small phages. Results The crystal structure of bacteriophage Qβ determined at 3.5 a resolution shows that the capsid is stabilized by disulfide bonds on each side of the flexible loops that are situated around the fivefold and quasi-sixfold axes. As in other small RNA phages, the protein capsid is constructed from subunits which associate into dimers. A contiguous ten-stranded antiparallel β sheet facing the RNA is formed in the dimer. The disulfide bonds lock the constituent dimers of the capsid covalently in the T=3 lattice. Conclusion The unusual stability of the Qβ particle is due to the tight dimer interactions and the disulfide bonds linking each dimer covalently to the rest of the capsid. A comparison with the structure of the related phage MS2 shows that although the fold of the Qβ coat protein is very similar, the details of the protein–protein interactions are completely different. The most conserved region of the protein is at the surface, which, in MS2, is involved in RNA binding.

Fitness‐compensatory mutations in rifampicin‐resistant RNA polymerase

Mutations in rpoB (RNA polymerase β‐subunit) can cause high‐level resistance to rifampicin, an important first‐line drug against tuberculosis. Most rifampicin‐resistant (RifR) mutants selected in vitro have reduced fitness, and resistant clinical isolates of M. tuberculosis frequently carry multiple mutations in RNA polymerase genes. This supports a role for compensatory evolution in global epidemics of drug‐resistant tuberculosis but the significance of secondary mutations outside rpoB has not been demonstrated or quantified. Using Salmonella as a model organism, and a previously characterized RifR mutation (rpoB R529C) as a starting point, independent lineages were evolved with selection for improved growth in the presence and absence of rifampicin. Compensatory mutations were identified in every lineage and were distributed between rpoA, rpoB and rpoC. Resistance was maintained in all strains showing that increased fitness by compensatory mutation was more likely than reversion. Genetic reconstructions demonstrated that the secondary mutations were responsible for increasing growth rate. Many of the compensatory mutations in rpoA and rpoC individually caused small but significant reductions in susceptibility to rifampicin, and some compensatory mutations in rpoB individually caused high‐level resistance. These findings show that mutations in different components of RNA polymerase are responsible for fitness compensation of a RifR mutant.

Structural comparisons of some small spherical plant viruses

The structures of tomato bushy stunt virus, southern bean mosaic virus and satellite tobacco necrosis virus have been compared quantitatively. The organization of the shell domains of tomato bushy stunt virus and southern bean mosaic virus within the icosahedral envelope is identical. The wedge-shaped end of the subunit is closer to the fivefold or quasi-sixfold axes in all three viruses but the packing about the three- and twofold axes is quite different in satellite tobacco necrosis virus as compared to tomato bushy stunt virus or southern bean mosaic virus. The polypeptide folds of these viruses have greatest similarity in the beta-sheet region of the eight-stranded anti-parallel beta-barrel. The largest differences occur in the connecting segments. There is no clear indication of homologous amino acid sequences between southern bean mosaic virus and satellite tobacco necrosis virus. However, there is some conservation of the following functional groups. (1) Threonines and serines at the hexagonal-pentagonal wedge-shaped end of the subunit. (2) Lysines and arginines at the protein-RNA interface. (3) Hydrophobic residues in the cavity within the anti-parallel beta-barrel. (4) An aspartic acid near a site which binds Ca in tomato bushy stunt virus. (5) Ionic interactions in the contacts between fivefold-related subunits. These virus coat protein structures are not as similar to each other as the alpha and beta chains of hemoglobin but have greater likeness to one another than the NAD-binding domains of dehydrogenases or lysozymes from hen egg-white and T4 phage. The surface domains of tomato bushy stunt virus and southern bean mosaic virus are more like each other than like satellite tobacco necrosis virus. A divergent evolutionary tree is proposed on the basis of these observations.

3D Domain Swapping Modulates the Stability of Members of an Icosahedral Virus Group

BACKGROUND Rice yellow mottle virus (RYMV) is a major pathogen that dramatically reduces rice production in many African countries. RYMV belongs to the genus sobemovirus, one group of plant viruses with icosahedral capsids and single-stranded, positive-sense RNA genomes. RESULTS The structure of RYMV was determined and refined to 2.8 A resolution by X-ray crystallography. The capsid contains 180 copies of the coat protein subunit arranged with T = 3 icosahedral symmetry. Each subunit adopts a jelly-roll beta sandwich fold. The RYMV capsid structure is similar to those of other sobemoviruses. When compared with these viruses, however, the betaA arm of the RYMV C subunit, which is a molecular switch that regulates quasi-equivalent subunit interactions, is swapped with the 2-fold-related betaA arm to a similar, noncovalent bonding environment. This exchange of identical structural elements across a symmetry axis is categorized as 3D domain swapping and produces long-range interactions throughout the icosahedral surface lattice. Biochemical analysis supports the notion that 3D domain swapping increases the stability of RYMV. CONCLUSIONS The quasi-equivalent interactions between the RYMV proteins are regulated by the N-terminal ordered residues of the betaA arm, which functions as a molecular switch. Comparative analysis suggests that this molecular switch can also modulate the stability of the viral capsids.

Probing sequence-specific RNA recognition by the bacteriophage MS2 coat protein.

We present the results of in vitro binding studies aimed at defining the key recognition elements on the MS2 RNA translational operator (TR) essential for complex formation with coat protein. We have used chemically synthesized operators carrying modified functional groups at defined nucleotide positions, which are essential for recognition by the phage coat protein. These experiments have been complemented with modification-binding interference assays. The results confirm that the complexes which form between TR and RNA-free phage capsids, the X-ray structure of which has recently been reported at 3.0 A, are identical to those which form in solution between TR and a single coat protein dimer. There are also effects on operator affinity which cannot be explained simply by the alteration of direct RNA-protein contacts and may reflect changes in the conformational equilibrium of the unliganded operator. The results also provide support for the approach of using modified oligoribonucleotides to investigate the details of RNA-ligand interactions.

Mutations to kirromycin resistance occur in the interface of domains I and III of EF-Tu·GTP

The antibiotic kirromycin inhibits protein synthesis by binding to EF‐Tu and preventing its release from the ribosome after GTP hydrolysis. We have isolated and sequenced a collection of kirromycin resistant tuf mutations and identified thirteen single amino acid substitutions at seven different sites in EF‐Tu. These have been mapped onto the 3D structures of EF‐Tu·GTP and EF‐Tu·GDP. In the active GTP form of EF‐Tu the mutations cluster on each side of the interface between domains I and III. We propose that this domain interface is the binding site for kirromycin.

Evolutionary and taxonomic implications of conserved structural motifs between picornaviruses and insect picorna-like viruses

Summary. A comparison of the recently determined structure of an insect picorna-like virus, Cricket paralysis virus (CrPV), with that of the mammalian picornaviruses shows that several structural features are highly conserved between these viruses. These conserved features include the topology of the coat proteins, the conformation of most loops, and the general arrangement of the internally located N-terminal arms of the coat proteins. The conformational conservation of the N-termini of the three major coat proteins between CrPV and the picornaviruses suggests a putative ancestral T = 3 virus. Comparisons of the genome structure and amino-acid sequence of the coat proteins of CrPV with a number of other insect picorna-like viruses show that most of them belong to a novel group, recently given the interim name Cricket paralysis-like viruses. Two other insect picorna-like viruses, Infectious flacherie virus (IFV) and Sacbrood virus (SBV), for which the genome sequences have recently been determined, have very different coat protein sequences and a genome organization more like the picornaviruses. However, the position of the small VP4 protein in the structural protein polyprotein as well as the mechanism for its cleavage from VP3 upon assembly strongly suggests an evolutionary link to the “Cricket paralysis-like viruses”. We propose that the picornaviruses, Cricket paralysis-like viruses and IFV/SBV group are a natural assemblage. The ancestor for this assemblage had a structure based upon the CrPV/picornavirus paradigm and a genome encoding a single major coat protein; gene duplication and rearrangements have subsequently to produced the viruses that we observe today. We also discuss the possible relatives of the proposed assemblage and the likely implications of future structural studies that may be carried out on the putative relatives.

Crystallographic studies of RNA hairpins in complexes with recombinant MS2 capsids: implications for binding requirements.

The coat protein of bacteriophage MS2 is known to bind specifically to an RNA hairpin formed within the MS2 genome. Structurally this hairpin is built up by an RNA double helix interrupted by one unpaired nucleotide and closed by a four-nucleotide loop. We have performed crystallographic studies of complexes between MS2 coat protein capsids and four RNA hairpin variants in order to evaluate the minimal requirements for tight binding to the coat protein and to obtain more information about the three-dimensional structure of these hairpins. An RNA fragment including the four loop nucleotides and a two-base-pair stem but without the unpaired nucleotide is sufficient for binding to the coat protein shell under the conditions used in this study. In contrast, an RNA fragment containing a stem with the unpaired nucleotide but missing the loop nucleotides does not bind to the protein shell.