Optical tracking of a stress-responsive gene amplifier applied to cell-based biosensing and the study of synthetic architectures.

A synthetic regulatory construct based on a two-stage amplifying promoter cascade is applied to whole-cell biosensing. Green fluorescent protein (GFP) and red fluorescent protein (RFP) enable two-component tracking of the response event, enabling the system to exhibit increased sensitivity, a lower limit of detection, and a unique optical density-free assessment mode. Specifically, the recA and tac promoters are linked by the LacI repressor in Escherichia coli, where DNA-damage activates the recA promoter and the up-regulation of GFP and LacI proteins. LacI represses the tac promoter, down-regulating the otherwise constitutive mCherry transcription. The response of the construct was compared with two singly tagged, conventional recA promoter-reporter constructs: recA::gfpmut3.1 and recA::mCherry. Using a miniature LED-based flow-through optical detector developed for remote sensing applications, limits of detection for the dual reporter construct reached as low as 0.1 nM MMC. By comparison, single-ended reporters recA::mCherry and recA::gfpmut3.1 achieved best limits of detection of 0.25 nM and 2.0 nM, respectively. An approach to three-component optical analysis, based on a system of detectors with coupled calibration equations enables accurate assessments of the red fluorescence, green fluorescence, and biomass of sensor cell suspensions. The system approach is effective at overcoming interferences caused by optically dense samples and overlapping fluorescence spectra. Such a technique may be useful in studying the biological mechanisms which underlie the synthetic regulatory device of this work and others.

Whole cell biosensing via recA::mCherry and LED-based flow-through fluorometry.

A miniature flow-through optical cell has been developed with the potential for integration into a stand-alone, potentially disposable whole-cell biosensor platform. The compact and inexpensive optical system is comprised of closely coupled light-emitting diodes (LEDs), light-to-frequency (LTF) photodiodes, and celluloid filters. The system has been optimized to measure fluorescent reporters produced by cultures of biosensor cells in liquid suspension. As demonstration subjects, Escherichia coli cells carrying medium-copy plasmids with fluorescent reporter fusions to the rec promoter were exposed to the DNA-damaging agent mitomycin C (MMC). As reporter proteins, green fluorescent protein (GFP) and red fluorescent protein (RFP) were compared for suitability in the compact instrument. The RFP mCherry outperformed GFP (GFPmut3.1) as a reporter protein in the developed system on two counts. First, measurement distortions due to high optical density suspensions are minimal using RFP compared to GFP. Second, the limit of detection for MMC is estimated at 0.25nM for recA::mCherry and 2.0nM for recA::gfpmut3.1. Finally, a measurement method is presented whereby multiple channels of optical data are calibrated in an integrated fashion to allow simultaneous measurement of fluorescence and biomass concentration. The method substantially eliminates optical distortions due to dense samples and thus obviates the conventional need for sample dilution prior to measurement.

Molecular genetics and genomic analysis of scytonemin biosynthesis in Nostoc punctiforme ATCC 29133.

The indole-alkaloid scytonemin is the most common and widespread sunscreen among cyanobacteria. Previous research has focused on its nature, distribution, ecology, physiology, and biochemistry, but its molecular genetics have not been explored. In this study, a scytonemin-deficient mutant of the cyanobacterium Nostoc punctiforme ATCC 29133 was obtained by random transposon insertion into open reading frame NpR1273. The absence of scytonemin under conditions of induction by UV irradiation was the single phenotypic difference detected in a comparative analysis of the wild type and the mutant. A cause-effect relationship between the phenotype and the mutation in NpR1273 was demonstrated by constructing a second scytoneminless mutant through directed mutagenesis of that gene. The genomic region flanking the mutation revealed an 18-gene cluster (NpR1276 to NpR1259). Four putative genes in the cluster, NpR1274 to NpR1271, with no previously known functions, are likely to be involved in the assembly of scytonemin. Also in this cluster, there is a redundant set of genes coding for shikimic acid and aromatic amino acid biosynthesis enzymes, leading to the production of tryptophan and tyrosine, which are likely to be biosynthetic precursors of the sunscreen.

Microbial growth in a steady-state model of ethylene glycol-contaminated soil.

Biodegradation of ethylene glycol was tested in a laboratory-scale, steady-state infiltration system of two arid region soil types by monitoring indigenous microbial growth after the infiltration of three concentrations of ethylene glycol. Microorganisms in the soils were able to adapt to the ethylene glycol in several cases, resulting in higher numbers of microorganisms and lower pHs in the effluents. These microorganisms were identified and were able to use ethylene glycol as a sole carbon source. The adaptation was seen best with high-moisture-content soils when the ethylene glycol concentrations were 1% or 10%. However, acclimation to 0.1% and 10% ethylene glycol did not occur in low-moisture-content clay soil, but did occur in low-moisture-content silt soil, indicating that soil type and moisture content are important factors. In all cases, microbial diversity decreased over time.

Isolation and characterization of rcsB mutations that affect colanic acid capsule synthesis in Escherichia coli K-12.

Regulation of colanic acid polysaccharide capsule synthesis in Escherichia coli requires the proteins RcsC and RcsB, in addition to several other proteins. By sequence similarity, these two proteins appear to be members of the two-component sensor-effector regulatory family found in bacteria. The present study characterizes the functional domains of RcsB. We have isolated mutations in rcsB that are able to suppress an rcsC "up" mutation (i.e., leading to increase in cps transcription) that normally results in constitutive expression of the capsule. In addition, constitutive capsule mutations in rcsB have been isolated. From the characterization of the mutants and by analogy to the three-dimensional structure of CheY, we have begun to define different domains of RcsB and to assign functions to them. A few of the constitutive capsule mutations were localized in an acidic pocket that has been proposed to play a crucial role in phosphorylation of RcsB. As seen in other two-component systems, an aspartate-to-glutamate substitution at the presumed site of phosphorylation of RcsB resulted in constitutive capsule expression. Lastly, several of our rcsB mutants were found to be allele specific (rcsC137 specific) for rcsC, suggesting a physical as well as functional interaction between RcsC and RcsB proteins.

Role of colanic acid polysaccharide in serum resistance in vivo and in adherence.

The production of an extracellular layer of polysaccharide, termed the capsule, is a common feature of many bacteria. Capsules play a vital role in permitting evasion of the host immune specific and nonspecific defenses as well as helping in adhesion for colonization of host tissue. Colanic acid capsule is usually produced in low quantities and is a common feature of several enteric bacteria. The role of the colanic acid capsule in aiding adhesion and virulence was investigated. Encapsulated and unencapsulated cells were injected into granuloma pouches that were formed on the backs of rats. During the first 50 h, the viability of the matched encapsulated and unencapsulated cells decreased. These studies showed that colanic acid capsule does not confer resistance to the bactericidal activity of serum or to phagocytosis in vivo, since there was no significant difference in the survival rates of both strains over time. Adherence studies were conducted in monolayers of human carcinoma intestinal cells (T84) with the same matched strains. After incubating radioactively labeled bacteria with the colon cells, the level of adherence was determined by measuring the radioactivity remaining in the tissue culture wells. The results of these experiments indicated that the unencapsulated cells adhered more readily to the intestinal cells, suggesting that colanic acid capsule interferes with adherence in this model system.

Identification of the promoter region for the colanic acid polysaccharide biosynthetic genes in Escherichia coli K-12.

The colanic acid polysaccharide capsule biosynthetic genes (cps genes) are primarily clustered at one site located at about 45 min on the Escherichia coli chromosome. The network of proteins involved in regulating the expression of these genes includes the two positive regulators RcsA and RcsB. This work describes the site of action of these two activator proteins and the promoter of the cps genes. It is likely that the cps genes are arranged in a single long operon that is at least 13.5 kb. The promoter region was identified with fusions to lacZ that resulted in regulated expression by the Rcs network of regulatory proteins, and the start site of transcription was identified by primer extension. The operator region was cloned from Kohara phage to multicopy plasmids and identified by titrating RcsA or RcsB. Sequence analysis of the promoter and operator region revealed homology to the JUMPstart element found in the untranslated region of many exopolysaccharide biosynthetic operons. In addition, the deduced amino acid sequence of the amino terminus of the first open reading frame of the cps operon was found to be homologous to proteins encoded by the exopolysaccharide biosynthetic operons of Klebsiella pneumoniae and Erwinia amylovora.

Regulation of capsular polysaccharide synthesis in Escherichia coli K12.

Synthesis of the capsular polysaccharide colanic acid in Escherichia coli K12 is regulated by a complex network of regulatory proteins. This regulation is expressed at the level of transcription of the cps (capsular polysaccharide synthesis) genes. Two positive regulators, RcsA and RcsB, are necessary for maximal capsule expression. The availability of RcsA is normally limited because the RcsA protein is rapidly degraded by the Lon ATP-dependent protease. Therefore Lon acts, indirectly, as a negative regulator of capsule synthesis. The sequence predicted for RcsB suggests that it is the effector component of a two-component system; a protein with homology to sensors, RcsC, also plays a role in capsule regulation. We propose a model for capsule synthesis in which RcsA interacts with RcsB to stimulate transcription of the cps genes. The mechanism of regulation of colanic acid synthesis in E. coli may apply to other capsules in a variety of Gram-negative bacteria.

RcsA, an unstable positive regulator of capsular polysaccharide synthesis.

RcsA is an unstable positive regulator required for the synthesis of colanic acid capsular polysaccharide in Escherichia coli. Degradation of the RcsA protein in vivo depends on the ATP-dependent Lon protease. DNA sequence analysis of the rcsA gene reveals a single open reading frame for a 23,500-Da highly basic protein (pI = 9.9), consistent with the observed size of the purified subunit of RcsA. The DNA and protein sequences are highly homologous to the rcsA gene and protein from Klebsiella pneumoniae and other species. The carboxy-terminal region of RcsA contains a possible helix-turn-helix DNA-binding motif that resembles sequences found at the carboxy terminus of RcsB, another positive regulator of capsule synthesis, and in several other transcriptional regulators including members of the LuxR family. rcsA62, a mutation in rcsA that leads to increased capsule synthesis, encodes a protein designated RcsA*, which differs from wild-type RcsA only in the replacement of Met-145 by valine. The RcsA* protein is subject to Lon-dependent degradation. The stability of wild-type RcsA in vivo is increased by multicopy RcsB. Conversely, RcsA is degraded more rapidly in rcsB mutant hosts than in wild-type hosts. These results suggest that RcsA and RcsB interact in vivo and are consistent with genetic experiments that indicate an interaction between RcsA and RcsB. Based on these experiments, we propose a model for capsule regulation in which RcsA interacts directly with RcsB to promote transcription of the genes for capsule synthesis.

Chromosomal gene transfer during conjugation by Staphylococcus aureus is mediated by transposon-facilitated mobilization.

A chromosomal copy of the transposon Tn551 and a copy coresident on a gentamicin-resistant conjugative plasmid of Staphylococcus aureus resulted in the mobilization of chromosomal genes during filter mating. Gene mobilization was recA dependent and was not restricted to any specific region of the chromosome. Both essential and nonessential genes were transferred.

RcsB and RcsC: a two-component regulator of capsule synthesis in Escherichia coli.

Colanic acid capsule synthesis in Escherichia coli K-12 is regulated by RcsB and RcsC. The amino acid sequences of these two proteins, deduced from the nucleotide sequence reported here, demonstrate their homology to environmentally responsive two-component regulators that have been reported in both gram-positive and gram-negative bacteria. In our model, RcsC acts as the sensor and RcsB acts as the receiver or effector to stimulate capsule synthesis from cps genes. In addition, RcsC shows limited homology to the other effectors in its C terminus. Fusions of rcsC to phoA that resulted in PhoA+ strains demonstrated that RcsC is a transmembrane protein with a periplasmic N-terminal domain and cytoplasmic C-terminal domain. Additional control of this regulatory network is provided by the dependence on the alternate sigma factor, RpoN, for the synthesis of RcsB. The rcsB and rcsC genes, which are oriented convergently with their stop codons 196 base pairs apart, are separated by a long direct repeat including two repetitive extragenic palindromic sequences.