Recent advances in the application of electron paramagnetic resonance spectroscopy have demonstrated that it is possible to obtain structural information on bacterial outer membrane (OM) proteins in intact cells from extracellularly labeled cysteines. However, in the Escherichia coli OM B 12 transport protein, BtuB, the double labeling of many cysteine pairs is not possible in a wild-type K12-derived E. coli strain. It has also not yet been possible to selectively label single or paired cysteines that face the periplasmic space. Here, we demonstrate that the inability to produce reactive cysteine residues in pairs is a result of the disulfide bond formation system, which functions to oxidize pairs of free-cysteine residues. Mutant strains that are dsbA or dsbB null facilitate labeling pairs of cysteines. Moreover, we demonstrate that the double labeling of sites on the periplasmicfacing surface of BtuB is possible using a dsbA null strain. BtuB is found to exhibit different structures and structural changes in the cell than it does in isolated OMs or reconstituted systems, and the ability to label and perform electron paramagnetic resonance in cells is expected to be applicable to a range of other bacterial OM proteins.
Outer membrane TonB-dependent transporters facilitate the uptake of trace nutrients and carbohydrates in Gram negative bacteria and are essential for pathogenic bacteria and the health of the microbiome. Despite this, their mechanism of transport is still unknown. Here, pulse EPR measurements were made in intact cells on the Escherichia coli vitamin B12 transporter, BtuB. Substrate binding was found to alter the C-terminal region of the core and shift an extracellular substrate binding loop 2 nm towards the periplasm; moreover, this structural transition is regulated by an ionic lock that is broken upon binding of the inner membrane protein TonB. Significantly, this structural transition is not observed when BtuB is reconstituted into phospholipid bilayers. These measurements suggest an alternative to existing models of transport, and they demonstrate the importance of studying outer membrane proteins in their native environment.
In the outer membrane of Gram-negative bacteria, membrane proteins are thought to be organized into domains or islands that play a role in the segregation, movement, and turnover of membrane components. However, there is presently limited information on the structure of these domains or the molecular interactions that mediate domain formation. In the present work, the Escherichia coli outer membrane vitamin B 12 transporter, BtuB, was spin-labeled, and double electron−electron resonance was used to measure the distances between proteins in intact cells. These data together with Monte Carlo simulations provide evidence for the presence of specific intermolecular contacts between BtuB monomers that could drive the formation of string-like oligomers. Moreover, the EPR data provide evidence for the location of the interacting interfaces and indicate that lipopolysaccharide mediates the contacts between BtuB monomers.
The extracellular loops of bacterial outer membrane (OM) transporters are thought to sample a range of conformations in the apo state but to undergo a gating motion and assume a more defined conformation upon the binding of substrate. Here, we use pulse electron paramagnetic resonance to examine the conformations of the extracellular loops of BtuB, the Escherichia coli TonB-dependent vitamin B 12 transporter, in whole cells. Unlike previous measurements carried out in vitro, the loops assume well-defined configurations in situ that closely match the in surfo crystal structures. Moreover, there is no evidence that the loops undergo significant gating motions upon the binding of substrate. The results demonstrate that the structure of BtuB is dependent upon an intact native OM environment, in which a critical component is likely to be the extracellular lipopolysaccharide. In general, this work indicates that measurements on OM proteins in reconstituted membrane systems may not reflect the native state of the protein in vivo.
Development of cancer-specific probes for imaging by positron emission tomography (PET) is gaining impetus in cancer research and clinical oncology. One of the hallmarks of most cancer cell is incessant DNA replication, requiring continuous synthesis of nucleotides. Thymidylate synthase (TSase) is unique in this context, since it is the only enzyme in humans that is responsible for the de novo biosynthesis of the DNA building block 2’-deoxy-thymidylate (dTMP). TSase catalyzes the reductive methylation of 2’-deoxy-uridylate (dUMP) to dTMP using (R)-N(5),N(10)-methylene-5,6,7,8-tetrahydrofolate (MTHF) as a cofactor. Not surprisingly, several human cancers over-express TSase, which makes it a common target for chemotherapy (e.g., 5-fluorouracil). We envisioned that [11C]-MTHF might be specific PET probe to label cancerous cells. Using a stable radiotracer, [14C]-MTHF, we have initially found increased uptake by breast and colon cancer cell lines. In the current study, we examined the uptake of this radiotracer in human pancreatic cancer cell lines, MiaPaCa-2 and PANC-1, and found predominant radiolabeling of cancerous versus normal pancreatic cells. Furthermore, the uptake of the radiotracer is dependent on the intracellular level of the folate pool, cell cycle phase, expression of folate receptors on cell membrane, and co-treatment with the common chemotherapeutic drug methotrexate (MTX, blocking the biosynthesis of endogenous MTHF). These results point toward the potential for broad specificity of [11C]-MTHF as PET probe, and the ability to control its signal using MTX co-administration.
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