Colonic transcriptional profiling in resistance and susceptibility to trichuriasis: phenotyping a chronic colitis and lessons for iatrogenic helminthosis.

BACKGROUND: Helminth therapy is advocated to restore and maintain control of inflammatory responses, particularly chronic colitis. However, helminths can induce chronic colitis in susceptible individuals. Susceptibility has an immunogenetic basis: defining this is essential if nematode therapy is to be successfully and safely targeted in inflammatory bowel disease (IBD). To validate a preclinical mouse model we phenotyped the response to Trichuris muris in mice. We determined colonic transcriptional activity in naïve and infected mice and linked differential gene expression to mechanistic pathways. METHODS: T. muris-infected resistant (BALB/c) and susceptible (AKR) mice were studied to a chronic colitic timepoint (day 35). Colonic genome-wide expression was performed by microarray. Significant transcriptional changes were analyzed by cluster and gene ontology filtering and KEGG pathway mapping. RESULTS: Day 35 infected AKR displayed chronic diarrhea, weight loss, and transmural colonic inflammation; BALB/c remained asymptomatic, cleared the infection, and demonstrated normal histology. Compared to BALB/c mice, infected AKR upregulated gene expression clusters were overrepresented by immune response, chemotaxis, and apoptosis pathways. Cellular/tissue homeostasis and tight junction pathways dominated downregulated AKR expression clusters. Infected AKR T-helper cell development/polarization markers demonstrated predominant T(H) 1/T(H) 17 transcriptional activity. Colitic AKR data mirrored established murine models and human colitis. CONCLUSIONS: T. muris infection in the mouse shows striking phenotypic and transcriptional similarities to widely used models of IBD and human IBD. This preclinical mouse model presents a platform to examine biological commonalities among chronic colitides. However, these data urge caution in untargeted therapeutic helminth use until risk/benefit in susceptible individuals is more fully understood.

5alpha-dihydrotestosterone (DHT) retards wound closure by inhibiting re-epithelialization.

The ongoing search for explanations as to why elderly males heal acute skin wounds more slowly than do their female counterparts (and are more strongly disposed to conditions of chronic ulceration) has identified endogenous oestrogens and androgens as being respectively enhancers and inhibitors of repair. We previously demonstrated that blocking the conversion of testosterone to 5alpha-dihydrotestosterone (DHT) limits its ability to impair healing, suggesting that DHT is a more potent inhibitor of repair than is testosterone. The present study aimed to delineate the central mechanisms by which androgens delay repair. Whilst the contractile properties of neither rat wounds in vivo nor fibroblast-impregnated collagenous discs in vitro appeared to be influenced by androgen manipulations, the global blockade of DHT biosynthesis markedly accelerated re-epithelialization of incisional and excisional wounds and reduced local expression of beta-catenin, a key inhibitor of repair. Moreover, DHT retarded the in vitro migration of epidermal keratinocytes following scratch wounding. By contrast, it failed to influence the migratory and proliferative properties of dermal fibroblasts, suggesting that its primary inhibitory effect is upon re-epithelialization. These novel findings may be of particular significance in the context of chronic ulceration, for which being male is a key risk factor.

Characterization of nutrient-induced dispersion in Pseudomonas aeruginosa PAO1 biofilm.

The processes associated with early events in biofilm formation have become a major research focus over the past several years. Events associated with dispersion of cells from late stage biofilms have, however, received little attention. We demonstrate here that dispersal of Pseudomonas aeruginosa PAO1 from biofilms is inducible by a sudden increase in carbon substrate availability. Most efficient at inducing dispersal were sudden increases in availability of succinate > glutamate > glucose that led to approximately 80% reductions in surface-associated biofilm biomass. Nutrient-induced biofilm dispersion was associated with increased expression of flagella (fliC) and correspondingly decreased expression of pilus (pilA) genes in dispersed cells. Changes in gene expression associated with dispersion of P. aeruginosa biofilms were studied by using DNA microarray technology. Results corroborated proteomic data that showed gene expression to be markedly different between biofilms and newly dispersed cells. Gene families that were upregulated in dispersed cells included those for flagellar and ribosomal proteins, kinases, and phage PF1. Within the biofilm, genes encoding a number of denitrification pathways and pilus biosynthesis were also upregulated. Interestingly, nutrient-induced dispersion was associated with an increase in the number of Ser/Thr-phosphorylated proteins within the newly dispersed cells, and inhibition of dephosphorylation reduced the extent of nutrient-induced dispersion. This study is the first to demonstrate that dispersal of P. aeruginosa from biofilms can be induced by the addition of simple carbon sources. This study is also the first to demonstrate that dispersal of P. aeruginosa correlates with a specific dispersal phenotype.

Transformation of the tropane alkaloid-producing medicinal plant Hyoscyamus muticus by particle bombardment.

We report an efficient whole plant transformation system for Hyoscyamus muticus, an important medicinal plant of the Solanaceous family. We developed a system using a plasmid carrying the nptII and gusA genes, which was delivered into leaf explants by particle bombardment. Ten percent of bombarded leaf explants formed kanamycin-resistant callus, from which putative transgenic plants were recovered. The nptII gene conferring kanamycin resistance was found to be incorporated into the genome of all transgenic plants screened. Over 50% of the kanamycin resistant plants showed strong expression of the non-selected gusA gene. The majority of transgenic plants reached maturity, could be self pollinated, and produced fertile seed. A simple and efficient whole plant transformation system for this medicinal plant is an important step in furthering our understanding of tropane alkaloid production in plants.

A growth-defective kirromycin-resistant EF-Tu Escherichia coli mutant and a spontaneously evolved suppression of the defect.

This study has investigated the cause of a growth-defect phenotype of a mutation in the elongation factor EF-Tu from Escherichia coli. An M13-based genetic retrieval system reported by Zeef and Bosch [Mol. Gen. Genet. 238 (1993) 252-260] was used to segregate and identify an extremely growth-defective kirromycin-resistant (KrR) tufA mutation, encoding Gln124-->Lys (Q124K), from a KrR parent strain. This original strain also contained mutations, 124com1 and 124com2, that appear to have evolved to suppress the Q124K tufA mutation. In this communication we present these M13-based genetic experiments together with additional genetic and protein characterization experiments to clarify the basis of this complementation. The data indicate that the serious growth defect of Q124K originates from a defective GTP/GDP interaction. The GTP/GDP binding and GTP hydrolysis characteristics of ET-Tu Q124K were different from wild-type EF-Tu and especially of another KrR EF-Tu mutant A375T. In line with this, 124com1 specifically complemented EF-Tu Q124K, whereas the growth defects of strains containing EF-Tu mutated at aa 375 were aggravated. We also show that strains containing the segregated tufA Q124K mutation formed filaments.

Antibiotic resistance mechanisms of mutant EF-Tu species in Escherichia coli.

Analysis of antibiotic-resistant EF-Tu mutants has revealed a connection between resistance and structural elements that participate in the GTPase switching mechanism. Both random and site-directed mutagenesis methods have yielded sets of purified mutant EF-Tu resistant to kirromycin (kirT) or pulvomycin (pulT). All kirT mutations cluster in the interface of domain 1 and 3 of EF-Tu in its GTP-bound conformation, not in that of EF-Tu.GDP. Other evidence also suggests that kirromycin binds to the interface of wild-type EF-Tu, thereby jamming the GTPase switch. Various functional studies reveal two subsequent resistance mechanisms. The first hinders kirromycin binding to EF-Tu.GTP and the second occurs after GTP hydrolysis by rejection of bound kirromycin. All pulT mutations cluster in the three-domain junction interface of EF-Tu. GTP (which is an open hole in EF-Tu.GDP) and destabilize a salt-bridge network. Pulvomycin may bind nearby and overlap with tRNA binding. Mutations show that a D99-R230 salt bridge is not essential for the transduction of the GTPase switch signal from domain 1. In vivo and in vitro studies reveal that pulvomycin sensitivity is dominant over resistance. This demands a revision of the current view of the mechanism of pulvomycin inhibition of protein synthesis and may support a translation model with two EF-Tus on the ribosome. Several mutant EF-Tu species display altered behaviour towards aminoacyl-tRNA with interesting effects on translational accuracy. KirT EF-Tu(A375T) is able to reverse the streptomycin-dependent phenotype of a ribosomal protein S12 mutant strain to streptomycin sensitivity.

Pulvomycin-resistant mutants of E.coli elongation factor Tu.

This paper reports the generation of Escherichia coli mutants resistant to pulvomycin. Together with targeted mutagenesis of the tufA gene, conditions were found to overcome membrane impermeability, thereby allowing the selection of three mutants harbouring elongation factor (EF)-Tu Arg230-->Cys, Arg333-->Cys or Thr334-->Ala which confer pulvomycin resistance. These mutations are clustered in the three-domain junction interface of the crystal structure of the GTP form of Thermus thermophilus EF-Tu. This result shares similarities with kirromycin resistance; kirromycin-resistant mutations cluster in the domain 1-3 interface. Since both interface regions are involved in the EF-Tu switch mechanism, we propose that pulvomycin and kirromycin both act by specifically disturbing the allosteric changes required for the switch from EF-Tu-GTP to EF-Tu-GDP. The three-domain junction changes dramatically in the switch to EF-Tu.GDP; in EF-Tu.GDP this region forms an open hole. Structural analysis of the mutation positions in EF-Tu.GTP indicated that the two most highly resistant mutants, R230C and R333C, are part of an electrostatic network involving numerous residues. All three mutations appear to destabilize the EF-Tu.GTP conformation. Genetic and protein characterizations show that sensitivity to pulvomycin is dominant over resistance. This appears to contradict the currently accepted model of protein synthesis inhibition by pulvomycin.

The structural and functional basis for the kirromycin resistance of mutant EF-Tu species in Escherichia coli.

A structural and functional understanding of resistance to the antibiotic kirromycin in Escherichia coli has been sought in order to shed new light on the functioning of the bacterial elongation factor Tu (EF-Tu), in particular its ability to act as a molecular switch. The mutant EF-Tu species G316D, A375T, A375V and Q124K, isolated by M13mp phage-mediated targeted mutagenesis, were studied. In this order the mutant EF-Tu species showed increasing resistance to the antibiotic as measured by poly(U)-directed poly(Phe) synthesis and intrinsic GTPase activities. The K'd values for kirromycin binding to mutant EF-Tu.GTP and EF-Tu.GDP increased in the same order. All mutation sites cluster in the interface of domains 1 and 3 of EF-Tu.GTP, not in that of EF-Tu.GDP. Evidence is presented that kirromycin binds to this interface of wild-type EF-Tu.GTP, thereby jamming the conformational switch of EF-Tu upon GTP hydrolysis. We conclude that the mutations result in two separate mechanisms of resistance to kirromycin. The first inhibits access of the antibiotic to its binding site on EF-Tu.GTP. A second mechanism exists on the ribosome, when mutant EF-Tu species release kirromycin and polypeptide chain elongation continues.

A technique for targeted mutagenesis of the EF-Tu chromosomal gene by M13-mediated gene replacement.

A generally applicable system for targeted mutagenesis of a chromosomal sequence is described. The Escherichia coli tufA gene was mutated using a recombinant M13mp9 phage vector carrying a tuf gene. Integration via crossing over with the chromosomal tufA target gene produced an M13 lysogen. These lysogens were screened for resistance to kirromycin. The M13 phage carrying tufA mutations were efficiently retrieved by a genetic procedure. Genetic mapping was performed with the M13 vectors. The same recombinant M13 phage was used for mutagenesis, lysogen formation, gene replacement, retrieval, mapping and sequencing of kirromycin mutants. Three different mutations yielding resistance to kirromycin were found: two of these have previously been found and characterised, while the third mutation, Gly316-->Asp, is a new mutant. We also report the identification of a fourth kirromycin-resistant mutant, Gln124-->Lys.

Elongation factors in protein synthesis.

Recent discoveries of elongation factor-related proteins have considerably complicated the simple textbook scheme of the peptide chain elongation cycle. During growth and differentiation the cycle may be regulated not only by factor modification but also factor replacement. In addition, rare tRNAs may have their own rare factor proteins. A special case is the acquisition of resistance by bacteria to elongation factor-directed antibiotics. Pertinent data from the literature and our own work with Escherichia coli and Streptomyces are discussed. The GTP-binding domain of EF-Tu has been studied extensively, but little molecular detail is available on the interactions with its other ligands or effectors, or on the way they are affected by the GTPase switch signal. A growing number of EF-Tu mutants obtained by ourselves and others are helping us in testing current ideas. We have found a synergistic effect between EF-Tu and EF-G in their uncoupled GTPase reactions on empty ribosomes. Only the EF-G reaction is perturbed by fluoroaluminates.