Signature-tagged transposon mutagenesis studies demonstrate the dynamic nature of cecal colonization of 2-week-old chickens by Campylobacter jejuni

We have constructed plasmids to be used for in vitro signature-tagged mutagenesis (STM) of Campylobacter jejuni and used these to generate STM libraries in three different strains. Statistical analysis of the transposon insertion sites in the C. jejuni NCTC 11168 chromosome and the plasmids of strain 81-176 indicated that their distribution was not uniform. Visual inspection of the distribution suggested that deviation from uniformity was not due to preferential integration of the transposon into a limited number of hot spots but rather that there was a bias towards insertions around the origin. We screened pools of mutants from the STM libraries for their ability to colonize the ceca of 2-week-old chickens harboring a standardized gut flora. We observed high-frequency random loss of colonization proficient mutants. When cohoused birds were individually inoculated with different tagged mutants, random loss of colonization-proficient mutants was similarly observed, as was extensive bird-to-bird transmission of mutants. This indicates that the nature of campylobacter colonization in chickens is complex and dynamic, and we hypothesize that bottlenecks in the colonization process and between-bird transmission account for these observations.     

Signature-Tagged Transposon Mutagenesis Studies Demonstrate the Dynamic Nature of Cecal Colonization of 2-Week-Old Chickens by Campylobacter jejuni

We have constructed plasmids to be used for in vitro signature-tagged mutagenesis (STM) of Campylobacter jejuni and used these to generate STM libraries in three different strains. Statistical analysis of the transposon insertion sites in the C. jejuni NCTC 11168 chromosome and the plasmids of strain 81-176 indicated that their distribution was not uniform. Visual inspection of the distribution suggested that deviation from uniformity was not due to preferential integration of the transposon into a limited number of hot spots but rather that there was a bias towards insertions around the origin. We screened pools of mutants from the STM libraries for their ability to colonize the ceca of 2-week-old chickens harboring a standardized gut flora. We observed high-frequency random loss of colonization proficient mutants. When cohoused birds were individually inoculated with different tagged mutants, random loss of colonization-proficient mutants was similarly observed, as was extensive bird-to-bird transmission of mutants. This indicates that the nature of campylobacter colonization in chickens is complex and dynamic, and we hypothesize that bottlenecks in the colonization process and between-bird transmission account for these observations.     

Identification of Aeromonas veronii genes required for colonization of the medicinal leech, Hirudo verbana

Most digestive tracts contain a complex consortium of beneficial microorganisms, making it challenging to tease apart the molecular interactions between symbiont and host. The digestive tract of Hirudo verbana, the medicinal leech, is an ideal model system because it harbors a simple microbial community in the crop, comprising the genetically amenable Aeromonas veronii and a Rikenella-like bacterium. Signature-tagged mutagenesis (STM) was used to identify genes required for digestive tract colonization. Of 3,850 transposon (Tn) mutants screened, 46 were identified as colonization mutants. Previously we determined that the complement system of the ingested blood remained active inside the crop and prevented serum-sensitive mutants from colonizing. The identification of 26 serum-sensitive mutants indicated a successful screen. The remaining 20 serum-resistant mutants are described in this study and revealed new insights into symbiont-host interactions. An in vivo competition assay compared the colonization levels of the mutants to that of a wild-type competitor. Attenuated colonization mutants were grouped into five classes: surface modification, regulatory, nutritional, host interaction, and unknown function. One STM mutant, JG736, with a Tn insertion in lpp, encoding Braun's lipoprotein, was characterized in detail. This mutant had a >25,000-fold colonization defect relative to colonization by the wild-type strain at 72 h and, in vitro, an increased sensitivity to sodium dodecyl sulfate, suggesting the presence of an additional antimicrobial property in the crop. The classes of genes identified in this study are consistent with findings from previous STM studies involving pathogenic bacteria, suggesting parallel molecular requirements for beneficial and pathogenic host colonization.     

Use of signature-tagged transposon mutagenesis to identify Vibrio cholerae genes critical for colonization

The pathogenesis of cholera begins with colonization of the host intestine by Vibrio cholerae . The toxin co-regulated pilus (TCP), a fimbrial structure produced by V . cholerae , is absolutely required for colonization (i.e. the persistence, survival and growth of V . cholerae in the upper intestinal milieu), but many other aspects of the colonization process are not well understood. In this study, we use signature-tagged transposon mutagenesis (STM) to conduct a screen for random insertion mutations that affect colonization in the suckling mouse model for cholera. Of approximately 1100 mutants screened, five mutants (approximately 0.5%) with transposon insertions in TCP biogenesis genes were isolated, validating the use of STM to identify attenuated mutants. Insertions in lipopolysaccharide, biotin and purine biosynthetic genes were also found to cause colonization defects. Similar results were observed for mutations in homologues of pta and ptfA , two genes involved in phosphate transfer. Finally, our screen identified several novel genes, disruption of which also caused colonization defects in the mouse model. These results demonstrate that STM is a powerful method for isolating colonization-defective mutants of V . cholerae .     

Identification of in vivo essential genes from Pseudomonas aeruginosa by PCR-based signature-tagged mutagenesis

We adapted PCR-based signature-tagged mutagenesis (STM) to Pseudomonas aeruginosa. A collection of 1056 mutants was screened in a chronic lung infection rat model. Thirteen mutants were confirmed to be attenuated. Analysis revealed that these STM mutants represented transposon insertions into eight genes previously described in databases, three genes encoding proteins sharing identity with hypothetical proteins and two genes that shared no significant identity with sequences in databases. Five strains mutated in genes involved in protein degradation, stress tolerance, cation transport, ABC transporter, and an unknown protein were shown to be highly attenuated when tested individually in the rat chronic lung infection model.     

Defined oligonucleotide tag pools and PCR screening in signature-tagged mutagenesis of essential genes from bacteria

We describe a fast and simple method for signature-tagged mutagenesis (STM) using defined oligonucleotides for tag construction into mini-Tn5 and PCR instead of hybridization for rapid screening of bacterial mutants in vivo. A collection of 12 unique 21-mers were synthesized as complementary DNA strands to tag bacterial mutants constructed by insertional mutagenesis using pUTmini-Tn5Km2 plasmids. Tags were tested in a combination of assays by PCR and compared to hybridization for specificity and for large-scale screening. Each defined tag has the same melting temperature, an invariable region to optimize PCRs and a variable region for specific amplification by PCR. A series of "suicide" plasmids carrying mini-Tn5s, each with a specific tag, were transferred into Pseudomonas aeruginosa, giving 12 libraries of mutants; groups of 12 mutants were pooled and arrayed into 96-well microplates, representing approximately one-sixth of the P. aeruginosa 5.9-Mb genome. This simple STM method can be adapted to any bacterial system and used for genome scanning in various growth conditions.     

The EAL domain containing protein STM2215 (rtn) is needed during Salmonella infection and has cyclic di‐GMP phosphodiesterase activity

Salmonella Typhimurium gene STM2215 (rtn) is conserved among many enterobacteriaceae. Mutants lacking STM2215 poorly colonized the liver and spleen in intraperitoneal infection of mice and poorly colonized the intestine and deeper tissues in oral infection. These phenotypes were complemented by a wild‐type copy of STM2215 provided in trans. STM2215 deletion mutants grew normally in J774A.1 murine macrophages but were unable to invade Caco‐2 colonic epithelial cells. Consistent with this finding, mutants in STM2215 produced lower levels of effectors of the TTSS‐1. STM2215 is a predicted c‐di‐GMP phosphodiesterase, but lacks identifiable sensor domains. Biochemical analysis of STM2215 determined that it is located in the inner membrane and has c‐di‐GMP phosphodiesterase activity in vitro dependent on an intact EAL motif. Unlike some previously identified members of this family, STM2215 did not affect motility, was expressed on plates, and in liquid media at late exponential and early stationary phase during growth. Defined mutations in STM2215 revealed that neither the predicted periplasmic domain nor the anchoring of the protein to the inner membrane is necessary for the activity of this protein during infection. However, the EAL domain of STM2215 is required during infection, suggesting that its phosphodiesterase activity is necessary during infection.     

Retrospective application of transposon-directed insertion site sequencing to a library of signature-tagged mini-Tn5Km2 mutants of Escherichia coli O157:H7 screened in cattle

Massively parallel sequencing of transposon-flanking regions assigned the genotype and fitness score to 91% of Escherichia coli O157:H7 mutants previously screened in cattle by signature-tagged mutagenesis (STM). The method obviates the limitations of STM and markedly extended the functional annotation of the prototype E. coli O157:H7 genome without further animal use.     

CUC1 gene activates the expression of SAM-related genes to induce adventitious shoot formation

CUP-SHAPED COTYLEDON (CUC)1 encodes members of the NAC family. These are functionally redundant genes that are involved in shoot apical meristem (SAM) formation and cotyledon separation during embryogenesis in Arabidopsis. We analyzed transgenic plants overexpressing CUC1 (35S::CUC1). The cotyledons of these transgenic seedlings regularly had two basal lobes, small and round epidermal cells between the sinuses, and adventitious SAMs on the adaxial surface of this region. This suggests that CUC1 promotes adventitious SAM formation by maintaining epidermal cells in an undifferentiated state. In 35S::CUC1 cotyledons, the class I knotted-like homeobox (KNOX) genes, including SHOOT MERISTEMLESS (STM) and BREVIPEDICELLUS (BP), which are involved in SAM formation and/or maintenance, were ectopically expressed before adventitious SAM formation. In stm mutants, ectopic expression of CUC1 could not induce adventitious SAMs, whereas they continued to be observed in bp mutants. These results suggest that STM, but not BP, is necessary for the formation of adventitious SAMs in 35S::CUC1 cotyledons. Furthermore, we examined the relationship between CUC1 and ASYMMETRIC LEAVES (AS)1 and AS2. The as1 and as2 mutations genetically enhance 35S::CUC1 phenotypes even in the absence of STM function. Interestingly, the as1 mutation can partially rescue the mutant vegetative development phenotypes in the cuc1 cuc2 double mutant. Our results suggest that CUC1 positively regulates SAM formation not only through STM but also through an STM-independent pathway that is negatively regulated by AS1 and AS2.     

The induction of pigmentation change in a non-acid-fast strain ofMycobacterium phlei by ultraviolet radiation

Five scotochromogenic mutants and 11 achromogenic mutants were induced by UV irradiation of the non-acid-fast photochromogenic PN strain ofMycobacterium phlei. Spontaneous scotochromogenic and achromogenic mutants were not obtained. Colonies of the scotochromogenic mutants are orange, except for one mutant which is ochre. Three mutants are resistant to STM. Out of 11 achromogenic mutants 3 were induced by UV treatment of the original photochromogenic strain, 8 were prepared from the scotochromogenic mutant. No significant differences in the sensitivity to UV rays were found among the scotochromogenic mutant, achromogenic mutant and the photochromogenic PN strain ofMycobacterium phlei under the given experimental conditions. Scotochromogenic mutants and most achromogenic mutants are stable and suitable for further genetic investigation. Pigmentation changes can be used as genetic marker in mutation studies.     

Dissociation of rugose‐dependent short‐term memory component from memory consolidation in Drosophila

Extensive investigations show several molecular and neuroanatomical mechanisms underlying short‐lived and long‐lasting memory in Drosophila. At the molecular level, the genetic pathway of memory formation, which was obtained through mutant research, seems to occur sequentially. So far, studies of Drosophila mutants appear to support the idea that mutants defective in short‐term memory (STM) are always associated with long‐term memory (LTM) impairment. At the neuroanatomical level, distinct memory traces are partially independently distributed. However, whether memory phase dissociation also exists at the molecular level remains unclear. Here, we report on molecular separation of STM and consolidated memory through genetic dissection of rugose mutants. Mutants in the rugose gene, which encodes an evolutionarily conserved A‐kinase anchor protein, show immediate memory defects as assayed through aversive olfactory conditioning. Intriguingly, two well‐defined consolidated memory components, anesthesia‐resistant memory and protein synthesis‐dependent LTM, are both normal in spite of the defective immediate memory after 10‐session massed and spaced training. Moreover, rugose genetically interacts with cyclic AMP‐protein kinase A signaling during STM formation. Considering our previous study that AKAP Yu specifically participates in LTM formation, these results suggest that there exists a molecular level of memory phase dissociation with distinct AKAPs in Drosophila.     

Identifying the genetic basis of ecologically and biotechnologically useful functions of the bacterium Burkholderia vietnamiensis

Signature-tagged mutagenesis (STM) was used to identify genetic determinants of fitness associated with two key ecological processes mediated by bacteria. Burkholderia vietnamiensis strain G4 was used as a model bacterium to investigate: phenol degradation as a model of bioremediation, and pea rhizosphere colonization as a prerequisite to biological control and phytoremediation. A total of 1900 mutants were screened and 196 putative fitness mutants identified; the genetic basis of 137 of these mutations was determined by correlation to the G4 genome. The phenol-STM screen was more successful at identifying phenol degradation mutations (83 mutants; 4.4% hit rate) than a conventional agar-based phenol screen (49 mutants, 5319 screened, 0.92% hit rate). The combination of both screens completely defined the components of the TOM pathway in strain G4 and also identified novel accessory genes not previously implicated in phenol utilization. The rhizosphere-STM screen identified 113 mutants (5.9% hit rate); 107 had reduced tag signals indicative of poor rhizosphere colonization (Rhiz-), while six mutants produced high hybridization signals suggesting increased rhizosphere competence (Rhiz+). Competition assays confirmed that 69% of Rhiz- mutants tested (24/35) were severely compromised in their rhizosphere fitness. Seventy Rhiz- mutations mapped to genes with the following putative functions: amino acid biosynthesis (25; 36%), general metabolism (18; 26%), hypothetical (9; 13%), regulatory genes (4; 5.7%), transport and stress (2 each; 2.8% respectively). One of the most interesting discoveries mediated by the rhizosphere-STM screen was the identification of three Rhiz+ mutants inactivated within a single virulence-associated autotransporter adhesin gene; this mutation consistently produced a hyper-colonization phenotype suggesting a highly novel role for this surface adhesin during plant interactions. Our study has shown that STM can be successfully applied to ecologically important microbial interactions, defining the underlying genetic systems important for biotechnological fitness of environmental bacteria such those from the Burkholderia cepacia complex.     

Adaptation of signature-tagged mutagenesis to Escherichia coli K1 and the infant-rat model of invasive disease

With the exception of the polysialic acid capsule (K1 antigen), little is known about other virulence factors needed for systemic infection by Escherichia coli K1, the leading cause of Gram-negative neonatal meningitis in humans. In this work, the functional genomics method of signature-tagged mutagenesis (STM) was adapted to E. coli K1 and the infant-rat model to identify non-capsule virulence genes. Validation of the method was demonstrated by the failure to recover a reconstructed acapsular mutant from bacterial pools used to systemically infect 5-day-old rats. Three new genes required for systemic disease were identified from a total of 192 mutants screened by STM (1.56% hit rate). Gut colonization, Southern blot hybridization, mixed-challenge infection, and DNA sequence analyses showed that the attenuating defects in the mutants were associated with transposon insertions in rfaL (O antigen ligase), dsbA (thiol:disulfide oxidoreductase), and a new gene, puvA (previously unidentified virulence gene A), with no known homologues. The results indicate the ability of STM to identify novel systemic virulence factors in E. coli K1.     

Identification of novel meristem factors involved in shoot regeneration through the analysis of temperature-sensitive mutants of Arabidopsis

Adventitious organogenesis in plant tissue culture involves de novo formation of apical meristems and should therefore provide important information about the fundamentals of meristem gene networks. We identified novel factors required for neoformation of the shoot apical meristem (SAM) through an analysis of shoot regeneration in root initiation defective3 ( rid3 ) and root growth defective3 ( rgd3 ) temperature-sensitive mutants of Arabidopsis. After induction of callus to regenerate shoots, cell division soon ceased and was then reactivated locally in the surface region, resulting in formation of mounds of dense cells in which adventitious-bud SAMs were eventually constructed. The rgd3 mutation inhibited reactivation of cell division and suppressed expression of CUP-SHAPED COTYLEDON1 ( CUC1 ), CUC2 and SHOOT MERISTEMLESS ( STM ). In contrast, the rid3 mutation caused excess ill-controlled cell division on the callus surface. This was intimately related to enhanced and broadened expression of CUC1 . Positional cloning revealed that the RGD3 and RID3 genes encode BTAF1 (a kind of TATA-binding protein-associated factor) and an uncharacterized WD-40 repeat protein, respectively. In the early stages of shoot regeneration, RGD3 was expressed (as was CUC1 ) in the developing cell mounds, whereas RID3 was expressed outside the cell mounds. When RID3 was over-expressed artificially, the expression levels of CUC1 and STM were significantly reduced. Taken together, these findings show that both negative regulation by RID3 and positive regulation by RGD3 of the CUC–STM pathway participate in proper control of cell division as a prerequisite for SAM neoformation.     

Operant visual learning and memory in Drosophila mutants dunce,amnesiac and radish

Learning and memory of Drosophila mutants dunce, amnesiac and radish which were isolated originally from the classical olfactory learning paradigm are analyzed in an operant visual learning paradigm. Dunce appears to show normal ability to learn during training, but its memory is significantly affected. Though the learning index during the first minute after training is normal, its short-term memory (STM), anesthesia-resistant memory (ARM) and long-term memory (LTM) are all significantly damaged. Amnesiac displays disrupted middle-term memory (MTM), while its STM and LTM remain unchanged. Learning and memory in radish mutants seem to be unaffected. These results lend support to the argument that there are certain common molecular mechanisms underlying learning and memory through different tasks and the previous multi-phase model of visual memory is modified in a genetic way.     

Identification of Brucella melitensis 16M genes required for bacterial survival in the caprine host

Brucella species are gram-negative bacteria which belong to alpha-Proteobacteria family. These organisms are zoonotic pathogens that induce abortion and sterility in domestic mammals and chronic infections in humans known as Malta fever. The virulence of Brucella is dependent upon its ability to enter and colonize the cells in which it multiplies. The genetic basis of this aspect is poorly understood. Signature-tagged mutagenesis (STM) was used to identify potential Brucella virulence factors. PCR amplification has been used in place of DNA hybridization to identify the STM-generated attenuated mutants. A library of 288 Brucella melitensis 16M tagged mini-Tn5 Km2 mutants, in 24 pools, was screened for its ability to colonize spleen, lymph nodes and liver of goats at three weeks post-i.v. infection. This comparative screening identified 7 mutants (approximately 5%) which were not recovered from the output pool in goats. Some genes were known virulence genes involved in biosynthesis of LPS (lpsA gene) or in intracellular survival (the virB operon). Other mutants included ones which had a disrupted gene homologous to flgF, a gene coding for the basal-body rod of the flagellar apparatus, and another with a disruption in a gene homologous to ppk which is involved in the biosynthesis of inorganic polyphosphate (PolyP) from ATP. Other genes identified encoded factors involved in DNA metabolism and oxidoreduction metabolism. Using STM and the caprine host for screening, potential virulence determinants in B. melitensis have been identified.