Very high-throughput sequencing technologies need to be matched by high-throughput functional studies if we are to make full use of the current explosion in genome sequences. We have generated a very large bacterial mutant pool, consisting of an estimated 1.1 million transposon mutants and we have used genomic DNA from this mutant pool, and Illumina nucleotide sequencing to prime from the transposon and sequence into the adjacent target DNA. With this method, which we have called TraDIS (transposon directed insertion-site sequencing), we have been able to map 370,000 unique transposon insertion sites to the Salmonella enterica serovar Typhi chromosome. The unprecedented density and resolution of mapped insertion sites, an average of one every 13 base pairs, has allowed us to assay simultaneously every gene in the genome for essentiality and generate a genome-wide list of candidate essential genes. In addition, the semiquantitative nature of the assay allowed us to identify genes that are advantageous and those that are disadvantageous for growth under standard laboratory conditions. Comparison of the mutant pool following growth in the presence or absence of ox bile enabled every gene to be assayed for its contribution toward bile tolerance, a trait required of any enteric bacterium and for carriage of S. Typhi in the gall bladder. This screen validated our hypothesis that we can simultaneously assay every gene in the genome to identify niche-specific essential genes.
DNA transfer by bacterial conjugation requires a mating pair formation (Mpf) system that specifies functions for establishing the physical contact between the donor and the recipient cell and for DNA transport across membranes. Plasmid RP4 (IncP␣) contains two transfer regions designated Tra1 and Tra2, both of which contribute to Mpf. Twelve components are essential for Mpf, TraF of Tra1 and 11 Tra2 proteins, TrbB, -C, -D, -E, -F, -G, -H, -I, -J, -K, and -L. The phenotype of defined mutants in each of the Tra2 genes was determined. Each of the genes, except trbK, was found to be essential for RP4-specific plasmid transfer and for mobilization of the IncQ plasmid RSF1010. The latter process did not absolutely require trbF, but a severe reduction of the mobilization frequency occurred in its absence. Transfer proficiency of the mutants was restored by complementation with defined Tra2 segments containing single trb genes. Donor-specific phage propagation showed that traF and each of the genes encoded by Tra2 are involved. Phage PRD1, however, still adsorbed to the trbK mutant strain but not to any of the other mutant strains, suggesting the existence of a plasmid-encoded receptor complex. Strains containing the Tra2 plasmid in concert with traF were found to overexpress trb products as well as extracellular filaments visualized by electron microscopy. Each trb gene and traF are needed for the formation of the pilus-like structures. The trbK gene, which is required for PRD1 propagation and for pilus production but not for DNA transfer on solid media, encodes the RP4 entry-exclusion function. The components of the RP4 Mpf system are discussed in the context of related macromolecule export systems.
The serotonin transporter (SERT) is an integral membrane protein responsible for the clearance of serotonin from the synaptic cleft following the release of the neurotransmitter. SERT plays a prominent role in the regulation of serotoninergic neurotransmission and is a molecular target for multiple antidepressants as well as substances of abuse. Here we show that SERT associates with lipid rafts in both heterologous expression systems and rat brain and that the inclusion of the transporter into lipid microdomains is critical for serotonin uptake activity. SERT is present in a subpopulation of lipid rafts, which is soluble in Triton X-100 but insoluble in other non-ionic detergents such as Brij 58. Disaggregation of lipid rafts upon depletion of cellular cholesterol results in a decrease of serotonin transport capacity (V max ), due to the reduction of turnover number of serotonin transport. Our data suggest that the association of SERT with lipid rafts may represent a mechanism for regulating the transporter activity and, consequently, serotoninergic signaling in the central nervous system, through the modulation of the cholesterol content in the cell membrane. Furthermore, SERT-containing rafts are detected in both intracellular and cell surface fractions, suggesting that raft association may be important for trafficking and targeting of SERT. The serotonin transporter (SERT)1 is a member of a Na ϩ / Cl Ϫ -dependent family of integral membrane proteins that includes carriers for neurotransmitters, osmolytes, and nutrients (1-3). SERT, the norepinephrine transporter, and the dopamine transporter are most closely related, defining a subgroup characterized by a high degree of similarity both in sequence and pharmacological properties (4). SERT is responsible for the clearance of serotonin (5-hydroxytryptamine, 5HT) from the synaptic cleft following the release of the neurotransmitter (2).5HT is believed to accumulate inside the cell through cotransport with Na ϩ and Cl Ϫ and countertransport with K ϩ (4). SERT is an important pharmacological target for substances of abuse, such as cocaine, 3,4-methylenedioxymethamphetamine (Ecstasy), and p-chloramphetamine, and a variety of therapeutic antidepressants (1, 5, 6).Acute changes in SERT endogenous activity are likely to originate from local variations in 5HT concentration, cell surface distribution of SERT, interaction with regulatory proteins, or reversible post-translational modifications. To date SERT expression on the plasma membrane has been shown to be down-regulated by protein kinase C activation, following elevation of intracellular levels of Ca 2ϩ (7,8), or by phorbol 12-myristate 13-acetate treatment (9 -12). The SNARE protein syntaxin 1A (Syn 1A) is one of the few proteins known to modulate SERT function via protein-protein interaction by regulating the number of SERT molecules on the plasma membrane (13,14).To carry out clearance of extracellular 5HT, SERT must be inserted into the plasma membrane in an active form. This may require targeting the transport...
Listeria monocytogenes is ubiquitously prevalent in natural environments and is transmitted via the food chain to animals and humans, in whom it can cause life-threatening diseases. We used Multilocus Sequence Typing (MLST) of ∼2000 isolates of L. monocytogenes to investigate whether specific associations existed between clonal complexes (CCs) and the environment versus diseased hosts. Most CCs (72%) were not specific for any single source, and many have been isolated from the environment, food products, animals as well as from humans. Our results confirm that the population structure of L. monocytogenes is largely clonal and consists of four lineages (I-IV), three of which contain multiple CCs. Most CCs have remained stable for decades, but one epidemic clone (CC101) was common in the mid-1950s and very rare until recently when it may have begun to re-emerge. The historical perspective used here indicates that the central sequence types of CCs were not ancestral founders but have rather simply increased in frequency over decades.
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