A simple procedure for cloning and stable insertion of foreign genes into the chromosomes of gram-negative eubacteria was developed by combining in two sets of plasmids (i) the transposition features of Tn1O and TnS; (ii) the resistances to the herbicide bialaphos, to mercuric salts and organomercurial compounds, and to arsenite, and (iii) the suicide delivery properties of the R6K-based plasmid pGP704. The resulting constructions contained unique NotI or SfiI sites internal to either the Tn1O or the TnS inverted repeats. These sites were readily used for cloning DNA fragments with the help of two additional specialized cloning plasmids, pUC18Not and pUC18Sfi. The newly derived constructions could be maintained only in donor host strains that produce the R6K-specified protein, which is an essential replication protein for R6K and plasmids derived therefrom. Donor plasmids containing hybrid transposons were transformed into a specialized Xpir lysogenic Escherichia coli strain with a chromosomally integrated RP4 that provided broad-host-range conjugal transfer functions.
The promoter region of the pColV-K30-encoded operon specifying biosynthesis and transport of the siderophore aerobactin was subjected to deletion analysis to determine the smallest DNA sequence affording iron regulation of a iucA'-'lacZ gene fusion. A 78-base-pair (bp) region containing the main (P1)
The itinerary followed by Pseudomonas putida from being a soil-dweller and plant colonizer bacterium to become a flexible and engineer-able platform for metabolic engineering stems from its natural lifestyle, which is adapted to harsh environmental conditions and all sorts of physicochemical stresses. Over the years, these properties have been capitalized biotechnologically owing to the expanding wealth of genetic tools designed for deep-editing the P. putida genome. A suite of dedicated vectors inspired in the core tenets of synthetic biology have enabled to suppress many of the naturally-occurring undesirable traits native to this species while enhancing its many appealing properties, and also to import catalytic activities and attributes from other biological systems. Much of the biotechnological interest on P. putida stems from the distinct architecture of its central carbon metabolism. The native biochemistry is naturally geared to generate reductive currency [i.e., NAD(P)H] that makes this bacterium a phenomenal host for redox-intensive reactions. In some cases, genetic editing of the indigenous biochemical network of P. putida (cis-metabolism) has sufficed to obtain target compounds of industrial interest. Yet, the main value and promise of this species (in particular, strain KT2440) resides not only in its capacity to host heterologous pathways from other microorganisms, but also altogether artificial routes (trans-metabolism) for making complex, new-to-Nature molecules. A number of examples are presented for substantiating the worth of P. putida as one of the favorite workhorses for sustainable manufacturing of fine and bulk chemicals in the current times of the 4th Industrial Revolution. The potential of P. putida to extend its rich native biochemistry beyond existing boundaries is discussed and research bottlenecks to this end are also identified. These aspects include not just the innovative genetic design of new strains but also the incorporation of novel chemical elements into the extant biochemistry, as well as genomic stability and scaling-up issues.
The iron-regulated aerobactin operon, about 8 kilobase pairs in size, of the Escherichia coli plasmid ColV-K30 was shown by deletion and subcloning analyses to consist of at least five genes for synthesis (iuc, iron uptake chelate) and transport (iut, iron uptake transport) of the siderophore. The gene order iucABCD iutA was established. The genes were mapped within restriction nuclease fragments of a cloned 16.3-kilobase-pair HindHI fragment. Stepwise deletion and subsequent minicell analysis of the resulting plasmids allowed assignment of four of the five genes to polypeptides of molecular masses 63,000, 33,000 53,000, and 74,000 daltons, respectively. The 74-kilodalton protein, the product of gene iutA, is the outer membrane receptor for ferric aerobactin, whereas the remaining three proteins are involved in biosynthesis of aerobactin. The 33-kilodalton protein, the product of gene iucB, was identified as NE-hydroxylysine:acetyl coenzyme A NE-transacetylase (acetylase) by comparison of enzyme activity in extracts from various deletion mutants. The 53-kilodalton protein, the product of gene iucD, is required for oxygenation of lysine. The 63-kilodalton protein, the product of gene iucA, is assigned to the first step of the aerobactin synthetase reaction. The product of gene iucC, so far unidentified, performs the second and final step in this reaction. This is based on the chemical characterization of two precursor hydroxamic acids (NW-acetyl-NW-hydroxylysine and Nat-citryl-NW-acetyl-NEhydroxylysine) isolated from a strain carrying a 0.3-kiobase-pair deletion in the iucC gene. The results support the existence of a biosynthetic pathway in which aerobactin arises by oxygenation of lysine, acetylation of the NE-hydroxy function, and condensation of 2 mol of the resulting aminohydroxamic acid with citric acid.
A fusion between the fur (ferric uptake regulation) gene, known to mediate negative regulation of iron absorption in Escherichia coli, and lacZ was constructed in vitro. P-Galactosidase levels of cells harboring this fusion were under the control of sequences contained in a 185-bp DNA fragment located upstream of the fur structural gene. The fusion was prepared in multicopy (pVLN102 plasmid) and low-copy-number states, the latter constructed as a I phage lysogen carrying a fur'-'lacZ insert. DNase I footprinting experiments with purified Fur protein, performed on a 250-bp restriction fragment carrying the promoter region of the fusion, showed the presence of a single Fur-protected site overlapping the -10 region of a potential promoter sequence. Examination of the DNA sequences located upstream of the fur gene revealed a possible binding site for the catabolite-activator protein (CAP). P-Galactosidase synthesis of E. coli cells harboring the fusion were measured in fur, crp and cya genetic backgrounds and compared with the corresponding levels in wild-type strains. The data obtained indicate a moderate autoregulation of fur expression by its gene product and also a significant stimulation by the CAMP-CAP system. Transcription start sites were mapped by primer-extension experiments with total RNA obtained in vivo from cells harboring pVLN102. The results show that transcription of thefur gene is initiated from at least two different sites separated by 6 bp, which appear to originate from two overlapping promoters sensitive to catabolic activation.
Transcription from promoter Pu of the upper catabolic operon of the Pseudomonas putida TOL plasmid which specifies conversion of toluene/xylenes to benzoate/toluates is activated by the TOL‐encoded regulator XylR protein in the presence of substrates of the catabolic pathway and in conjunction with the sigma 54(NtrA)‐containing form of RNA polymerase. This regulatory circuit was faithfully reproduced in Escherichia coli in single copy gene dosage by integrating the corresponding controlling determinants into the chromosomes of several K12 derivatives by means of specialized transposons. In vivo monitoring of the activity of a Pu‐lacZ fusion in E. coli strains with different genetic backgrounds demonstrated that integration host factor (IHF) is involved in Pu regulation and that hyperproduction of the XylR protein leads to a decrease of Pu activity in a manner in which deletion of the putative DNA‐binding domain of the XylR does not impair its inhibitory effect when hyperproduced. One discrete IHF binding site and two potential XylR sites (consensus sequence 5′‐TTGANCAAATC‐3′), bracketted by short stretches of DNase I‐hypersensitive bonds, were detected upstream of the transcription initiation site. A model accounting for the features found is proposed which includes the IHF‐promoted looping of upstream XylR‐DNA complexes so that they contact the sigma 54(NtrA)‐RNA polymerase bound at ‐12/‐24 positions.
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