Describing ancient horizontal gene transfers at the nucleotide and gene levels by comparative pathogenicity island genometrics.

MOTIVATION: Lateral gene transfer is a major mechanism contributing to bacterial genome dynamics and pathovar emergence via pathogenicity island (PAI) spreading. However, since few of these genomic exchanges are experimentally reproducible, it is difficult to establish evolutionary scenarios for the successive PAI transmissions between bacterial genera. Methods initially developed at the gene and/or nucleotide level for genomics, i.e. comparisons of concatenated sequences, ortholog frequency, gene order or dinucleotide usage, were combined and applied here to homologous PAIs: we call this approach comparative PAI genometrics. RESULTS: YAPI, a Yersinia PAI, and related islands were compared with measure evolutionary relationships between related modules. Through use of our genometric approach designed for tracking codon usage adaptation and gene phylogeny, an ancient inter-genus PAI transfer was oriented for the first time by characterizing the genomic environment in which the ancestral island emerged and its subsequent transfers to other bacterial genera.

Chromatographic method for diaminopimelic acid detection in calcareous rocks. Presence of a bacterial biomarker in stromatolites.

The presence in the environment of diaminopimelic acid (DAP), a specific eubacterial marker, can be attributed to that of bacteria. We report a reliable and highly sensitive method for the quantification of DAP in calcareous rocks. It consists of acid hydrolysis of rock powder, purification of DAP by chromatography on Dowex 50W and Spherogel AA-NA+ columns, and quantitative analysis by high-performance liquid chromatography. Addition of tritiated DAP, the internal standard, allows one to follow the relevant fractions throughout the purification procedure and to determine their yield. The analytical step consists in pre-column derivatization with ortho-phthaldialdehyde of purified samples, and separation through a reversed-phase C18 column. Chemical controls, i.e., oxidation of samples to rule out the presence of co-eluting lanthionine and cystathionine, as well as mass spectrometry, confirm the presence of DAP in analyzed samples. Our method allows the separation of meso- from L- and/or D-stereoisomers of DAP, and reveals their presence in the examined rocks, two stromatolites of different age and geographic origin.

A high-performance liquid chromatography method for the detection of diaminopimelic acid in urine.

We describe a quantitative assay for diaminopimelic acid (DAP) in urine. It involves (i) hydrolysis of urine samples, (ii) purification by several different liquid chromatography steps, and (iii) analysis by high-performance liquid chromatography on a reversed-phase C18 column. Tritiated-DAP, the internal standard, allows one to precisely follow the DAP-containing fractions and to determine the yield during purification. Sensitive and relatively accurate quantification of DAP, with a threshold of 50 fmol, is based on ion-pairing properties of eluants and ortho-phthaldialdehyde derivatization. The presence of DAP in relevant fractions was confirmed by combined gas chromatography and mass spectrometry. The DAP concentration in adult human urine pooled over 24 h ranges from 0.69 to 2.01 microM, a result in fair agreement with previously published values obtained by ninhydrin derivatization or gas chromatography.

Specific labeling of diaminopimelate: a radioassay for the determination of the peptidoglycan cross-linking index.

A radioassay for the determination of the peptidoglycan cross-linking index (CLI) was devised. It is based on specific radioactive labeling of diaminopimelic acid (DAP) by diverting [14C]aspartate into the DAP pathway, while inhibiting incorporation of label into other cell wall components. Purified [14C]DAP-labeled cell walls were treated with fluorodinitrobenzene, hydrolyzed, and chromatographed by TLC. The radioactivity in well-separated mono dinitrophenyl-diaminopimelate (DNP-DAP) and DAP spots was counted and the CLI was determined from the ratio of DAP to the total of mono DNP-DAP and DAP counts. The method, suitable for bacteria such as Bacillus subtilis unable to incorporate exogenous DAP, can be applied to other systems. A CLI of 50.8 +/- 1.3% and 55.5 +/- 0.9% was obtained for B. subtilis 168 cells growing exponentially in rich and minimal medium, respectively. Comparison of these to results previously obtained on B. subtilis suggested the existence of a hitherto unreported peptidoglycan endopeptidase activity.

Endogenous synthesis of peptidoglycan in eukaryotic cells; a novel concept involving its essential role in cell division, tumor formation and the biological clock.

Degradation products of peptidoglycan, the universal bacterial cell wall constituent, were previously found in animal tissues and urine. Reassessment and quantitative analysis of available data lead to an original concept, i.e. that eukaryotic cells synthesize peptidoglycan. We present a model in which this endogenously synthesized peptidoglycan is essential for the processes of eukaryotic cell division and sleep induction in animals. Genes for peptidoglycan metabolism, like those for lysine biosynthesis in plants, are probably inherited from endosymbiotic bacteria, the ancestors of mitochondria and chloroplasts. Corollaries of this concept, i.e. roles for peptidoglycan metabolism in tumor formation and in the biological clock, are supported by abundant evidence. We propose that many interactions between bacteria and eukaryotes are conditioned by their common genetic heritage.

N-acetylmuramoyl-L-alanine amidase assay based on specific radioactive labeling of muropeptide L-alanine: quantitation of the enzyme activity in the autolysin deficient Bacillus subtilis 168, flaD strain.

A sensitive and highly reproducible assay for N-acetylmuramoyl-L-alanine amidase (EC 3.5.1.28) was devised, based on specific and homogeneous L-[14C]alanine labeling of the substrate, the peptidoglycan. The method involves partial purification of both the enzyme and the substrate and monitoring the muropeptide cleavage by coupling fluorodinitrobenzene to freed L-alanine NH2 groups. After acid hydrolysis of the substrate, the resulting DNP-L-alanine and L-alanine are separated by TLC, and radioactive counts in relevant spots are determined. Application of the method to the autolysin-endowed strain and an autolysis-deficient flaD-bearing mutant has revealed (i) that the N-acetylmuramoyl-L-alanine amidase behaves like an endoenzyme with an apparent Kcat(s-1) of 40, and (ii) that the residual enzyme activity in the flaD bearing strain amounts to 2.5 (+/- 0.1)% of that of the parent strain.

Genes involved in meso-diaminopimelate synthesis in Bacillus subtilis: identification of the gene encoding aspartokinase I.

Thermosensitive mutants of Bacillus subtilis deficient in peptidoglycan synthesis were screened for mutations in the meso-diaminopimelate (LD-A2pm) metabolic pathway. Mutations in two out of five relevant linkage groups, lssB and lssD, were shown to induce, at the restrictive temperature, a deficiency in LD-A2pm synthesis and accumulation of UDP-MurNAc-dipeptide. Group lssB is heterogeneous; it encompasses mutations that confer deficiency in the deacylation of N-acetyl-LL-A2pm and accumulation of this precursor. Accordingly, these mutations are assigned to the previously identified locus dapE. Mutations in linkage group lssD entail a thermosensitive aspartokinase 1. Therefore, they are most likely to affect the structural gene of this enzyme, which we propose to designate dapG. Mutation pyc-1476, previously reported to affect the pyruvate carboxylase, was shown to confer a deficiency in aspartokinase 1, not in the carboxylase, and to belong to the dapG locus, dapG is closely linked to spoVF, the putative gene of dipicolinate synthase. In conclusion, mutations affecting only two out of eight steps known to be involved in LD-A2pm synthesis were uncovered in a large collection of thermosensitive mutants obtained by indirect selection. We propose that this surprisingly restricted distribution of the thermosensitive dap mutations isolated so far is due to the existence, in each step of the pathway, of isoenzymes encoded by separate genes. The biological role of different aspartokinases was investigated with mutants deficient in dapE and dapG genes. Growth characteristics of these mutants in the presence of various combinations of aspartate family amino acids allow a reassessment of a metabolic channel hypothesis, i.e. the proposed existence of multienzyme complexes, each specific for a given end product.