SummaryTo address the need for new approaches to antibiotic drug development, we have identified a large number of essential genes for the bacterial pathogen, Staphylococcus aureus, using a rapid shotgun antisense RNA method. Staphylococcus aureus chromosomal DNA fragments were cloned into a xylose-inducible expression plasmid and transformed into S. aureus. Homology comparisons between 658 S. aureus genes identified in this particular antisense screen and the Mycoplasma genitalium genome, which contains 517 genes in total, yielded 168 conserved genes, many of which appear to be essential in M. genitalium and other bacteria. Examples are presented in which expression of an antisense RNA specifically reduces its cognate mRNA. A cell-based, drug-screening assay is also described, wherein expression of an antisense RNA confers specific sensitivity to compounds targeting that gene product. This approach enables facile assay development for high throughput screening for any essential gene, independent of its biochemical function, thereby greatly facilitating the search for new antibiotics.
Type IV pili (Tfp) mediate the movement of bacteria over surfaces without the use of flagella. These movements are known as social gliding in Myxococcus xanthus and twitching in organisms such as Pseudomonas aeruginosa and Neisseria gonorrhoeae. Tfp are localized polarly. Type IV pilins have a signature N‐terminal domain, which forms a coiled‐coil with other monomer units to polymerize a pilus fibre. At least 10 more proteins at the base of the fibre are conserved; they are related to the type II secretion system. Movements produced by Tfp range from short, jerky displacements to lengthy, smooth ones. Tfp also participate in cell–cell interactions, pathogenesis, biofilm formation, natural DNA uptake, auto‐aggregation of cells and development. What is the means by which Tfp bring about the movement of cells?
Biofilms are dense microbial communities. Although widely distributed and medically important, how biofilm cells interact with one another is poorly understood. Recently, we described a novel process whereby myxobacterial biofilm cells exchange their outer membrane (OM) lipoproteins. For the first time we report here the identification of two host proteins, TraAB, required for transfer. These proteins are predicted to localize in the cell envelope; and TraA encodes a distant PA14 lectin-like domain, a cysteine-rich tandem repeat region, and a putative C-terminal protein sorting tag named MYXO-CTERM, while TraB encodes an OmpA-like domain. Importantly, TraAB are required in donors and recipients, suggesting bidirectional transfer. By use of a lipophilic fluorescent dye, we also discovered that OM lipids are exchanged. Similar to lipoproteins, dye transfer requires TraAB function, gliding motility and a structured biofilm. Importantly, OM exchange was found to regulate swarming and development behaviors, suggesting a new role in cell–cell communication. A working model proposes TraA is a cell surface receptor that mediates cell–cell adhesion for OM fusion, in which lipoproteins/lipids are transferred by lateral diffusion. We further hypothesize that cell contact–dependent exchange helps myxobacteria to coordinate their social behaviors.
We describe a novel LCMS approach to the relative quantitation and simultaneous identification of proteins within the complex milieu of unfractionated Escherichia coli. This label-free, LCMS acquisition method observes all detectable, eluting peptides and their corresponding fragment ions. Postacquisition data analysis methods extract both the chromatographic and the mass spectrometric information on the tryptic peptides to provide time-resolved, accurate mass measurements, which are subsequently used for quantitation and identification of constituent proteins. The response of E. coli to carbon source variation is well understood, and it is thus commonly used as a model biological system when validating an analytical method. Using this LCMS approach, we characterized proteins isolated from E. coli grown in glucose, lactose, and acetate. The change in relative abundance of the corresponding proteins was measured from peptides common to both conditions. Protein identities were also determined for those peptides that were unique to each condition, and these identities were found to be consistent with the underlying biochemical restrictions imposed by the growth conditions. The relative change in abundance of the characterized proteins ranged from 0.1-to 90-fold among the three binary comparisons. The overall coverage of the characterized proteins ranged from 10 to Escherichia coli is a microbial symbiote found in the colon and large intestine of most warm blooded animals that plays a critical role in vertebrate anabolism and catabolism. The environment in which E. coli lives is subject to rapid changes in the availability of the carbon and nitrogen compounds necessary to provide its energy and primary building blocks. E. coli survival hinges on the ability to successfully control the expression of genes coding for enzymes and proteins required for growth in response to environmental changes. Because of its simple cellular structure and its relative ease of maintenance and manipulation in the laboratory, E. coli has become the "workhorse host" for most research in molecular biology and microbiology. As a result, it is regarded as one of the most completely characterized organisms in all biology. The ease with which recombinant proteins can be expressed in E. coli has made this bacterium useful in the study of many basic biological processes as well as in the production of heterologous proteins for research and therapeutic purposes. For these reasons, E. coli has become a model system for testing new analytical technologies. For example, the relatively small genome size and prevalent laboratory use made E. coli genome one of the first to be completely sequenced (1). Likewise E. coli genome microarrays were among the first to be commercially available with sequences for the complete set of open reading frames as well as intergenic regions (2). The origins of proteomics can also be traced back to E. coli when pioneering two-dimensional gel electrophoresis experiments enabled the investigation of proteins on an organism...
The protein methyltransferase Set7/9 was recently shown to regulate p53 activity in cancer cells. However, the impact of Set7/9 on p53 function in vivo is unclear. To explore these issues, we created a null allele of Set7/9 in mice. Cells from Set7/9 mutant mice fail to methylate p53 K369, are unable to induce p53 downstream targets upon DNA damage, and are predisposed to oncogenic transformation. Importantly, we find that methylation of p53 by Set7/9 is required for the binding of the acetyltransferase Tip60 to p53 and for the subsequent acetylation of p53. We provide the first genetic evidence demonstrating that lysine methylation of p53 by Set7/9 is important for p53 activation in vivo and suggest a mechanistic link between methylation and acetylation of p53 through Tip60.
The universally conserved DnaK and DnaJ molecular chaperone proteins bind in a coordinate manner to protein substrates to prevent aggregation, to disaggregate proteins, or to regulate proper protein function. To further examine their synergistic mechanism of action, we constructed and characterized two DnaJ deletion proteins. One has an 11-amino-acid internal deletion that spans amino acid residues 77-87 (DnaJ delta 77-87) and the other amino acids 77-107 (DnaJ delta 77-107). The DnaJ delta 77-87 mutant protein, was normal in all respects analyzed. The DnaJ delta 77-107 mutant protein has its entire G/F (Gly/Phe) motif deleted. This motif is found in most, but not all DnaJ family members. In vivo, DnaJ delta 77-107 supported bacteriophage lambda growth, albeit at reduced levels, demonstrating that at least some protein function was retained. However, DnaJ delta 77-107 did not exhibit other wild type properties, such as proper down-regulation of the heat-shock response, and had an overall poisoning effect of cell growth. The purified DnaJ delta 77-107 protein was shown to physically interact and stimulate DnaK's ATPase activity at wild type levels, unlike the previously characterized DnaJ259 point mutant (DnaJH33Q). Moreover, both DnaJ delta 77-107 and DnaJ259 bound to substrate proteins, such as sigma 32, at similar affinities as DnaJ+. However, DnaJ delta 77-107 was found to be largely defective in activating the ATP-dependent substrate binding mode of DnaK. In vivo, the ability of the mutant DnaJ proteins to down-regulate the heat-shock response was correlated only with their in vitro ability to activate DnaK to bind sigma 32, in an ATP-dependent manner, and not with their ability to bind sigma 32. We conclude, that although the G/F motif of DnaJ does not directly participate in the stimulation of DnaK's ATPase activity, nevertheless, it is involved in an important manner in modulating DnaK's substrate binding activity.
Myxococcus xanthus cells can glide forward by retracting type IV pili. Tgl, an outer membrane lipoprotein, is necessary to assemble pili. Tgl mutants can be transiently "stimulated" if brought into end-to-end contact with tgl+ donor cells. By separating the stimulated recipient cells from donor cells, we found that Tgl protein was transferred from the donors to the rescued recipient cells. Mutants lacking CglB lipoprotein, which is part of a second gliding engine, could also be stimulated, and CglB protein was transferred from donor to recipient cells. The high transfer efficiency of Tgl and CglB proteins suggests that donor and recipient cells briefly fuse their outer membranes.
DnaJ is a molecular chaperone, which not only binds to its various protein substrates, but can also activate the DnaK cochaperone to bind to its various protein substrates as well. DnaJ is a modular protein, which contains a putative zinc finger motif of unknown function. Quantitation of the released Zn(II) ions, upon challenge with p-hydroxymercuriphenylsulfonic acid, and by atomic absorption showed that two Zn(II) ions interact with each monomer of DnaJ. Following the release of Zn(II) ions, the free cysteine residues probably form disulfide bridge(s), which contribute to overcoming the destabilizing effect of losing Zn(II). Supporting this view, infrared and circular dichroism studies show that the DnaJ secondary structure is largely unaffected by the release of Zn(II). Moreover, infrared spectra recorded at different temperatures, as well as scanning calorimetry, show that the Zn(II) ions help to stabilize DnaJ's tertiary structure. An internal 57-amino acid deletion of the cysteine-reach region did not noticeably affect the affinity of this mutant protein, DnaJDelta144-200, to bind DnaK nor its ability to stimulate DnaK's ATPase activity. However, the DnaJDelta144-200 was unable to induce DnaK to a conformation required for the stabilization of the DnaK-substrate complex. Additionally, the DnaJDelta144-200 mutant protein alone was unimpaired in its ability to interact with its final sigma32 transcription factor substrate, but exhibited reduced affinity toward its P1 RepA and lambdaP substrates. Finally, these in vitro results correlate well with the in vivo observed partial inhibition of bacteriophage lambda growth in a DnaJDelta144-200 mutant background.
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