Acinetobacter sp. strain ADP1 is a naturally transformable gram-negative bacterium with simple culture requirements, a prototrophic metabolism and a compact genome of 3.7 Mb which has recently been sequenced. Wild-type ADP1 can be genetically manipulated by the direct addition of linear DNA constructs to log-phase cultures. This makes it an ideal organism for the automation of complex strain construction. Here, we demonstrate the flexibility and versatility of ADP1 as a genetic model through the construction of a broad variety of mutants. These include marked and unmarked insertions and deletions, complementary replacements, chromosomal expression tags and complex combinations thereof. In the process of these constructions, we demonstrate that ADP1 can effectively express a wide variety of foreign genes including antibiotic resistance cassettes, essential metabolic genes, negatively selectable catabolic genes and even intact operons from highly divergent bacteria. All of the described mutations were achieved by the same process of splicing PCR, direct transformation of growing cultures and plating on selective media. The simplicity of these tools make genetic analysis and engineering with Acinetobacter ADP1 accessible to laboratories with minimal microbial genetics expertise and very little equipment. They are also compatible with complete automation of genetic analysis and engineering protocols.
The enzyme YkvM from Bacillus subtilis was identified previously along with three other enzymes (YkvJKL) in a bioinformatics search for enzymes involved in the biosynthesis of queuosine, a 7-deazaguanine modified nucleoside found in tRNA GUN of Bacteria and Eukarya. Genetic analysis of ykvJKLM mutants in Acinetobacter confirmed that each was essential for queuosine biosynthesis, and the genes were renamed queCDEF. QueF exhibits significant homology to the type I GTP cyclohydrolases characterized by FolE. Given that GTP is the precursor to queuosine and that a cyclohydrolase-like reaction was postulated as the initial step in queuosine biosynthesis, QueF was proposed to be the putative cyclohydrolase-like enzyme responsible for this reaction. We have cloned the queF genes from B. subtilis and Escherichia coli and characterized the recombinant enzymes. Contrary to the predictions based on sequence analysis, we discovered that the enzymes, in fact, catalyze a mechanistically unrelated reaction, the NADPHdependentreductionof7-cyano-7-deazaguanineto7-aminomethyl-7-deazaguanine, a late step in the biosynthesis of queuosine. We report here in vitro and in vivo studies that demonstrate this catalytic activity, as well as preliminary biochemical and bioinformatics analysis that provide insight into the structure of this family of enzymes.tRNA ͉ modified base T he avalanche of new protein structures that have been reported over the last decade (see summary at www.rcsb. org͞pdb͞holdings.html) has made it clear that the number of scaffolds that are used to produce all of the proteins in a cell is surprisingly limited, with Ϸ80% of the proteins using one of the 400 structural folds identified to date (1, 2). Specific functions evolve by duplication, recombination, and divergence of this core repertoire (3). Analysis of the functions of the different members of a protein structural family reveal that, in general, catalytic mechanisms and chemistries are conserved in a given family whereas substrate specificity changes (4). Much rarer are the cases in which the reactions catalyzed differ among members of the family (3); the best characterized examples being the TIM barrel superfamilies (5) and the enolase superfamily (6). Understanding the molecular paths that lead to the evolution of one function from another in a given superfamily is one of the next challenges of structural biology, impacting not only our understanding of how proteins evolve, but also the task of correctly annotating the genes identified by whole-genome sequencing (7,8).We recently used comparative genomic techniques (9) to discover four previously uncharacterized bacterial genes families (queCDEF) involved in the biosynthesis of the modified nucleoside queuosine (10). Three of these families (queCDE) have homologs in Archaea and are therefore implicated in the biosynthesis of the related modified nucleoside archaeosine (Fig. 1). Both nucleosides share an unusual 7-deazaguanosine core structure but diverge in their phylogenetic distribution, location in the ...
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