Systems biology for industrial strains and fermentation processes--example: amino acids.

Systems biology is attracting significant interest finding applications not only in pharmaceutical development but also for basic studies on microbial systems. The latter often concentrate on the quantitative understanding of global regulation phenomena. So far, these activities are dominated by academic groups basically mirroring the necessity to prepare the sound scientific understanding first, before industrial applications can be derived later. However, this short-term view may not be sufficient because systems biology already offers numerous benefits for industrial applications, provided that special constraints are considered. This contribution indicates some of the constraints worth noticing when industrial systems biology projects are carried out. Consequently, differences in project structure and goals between purely academic and industrial systems biology projects are outlined.

Expression of genes of lipid synthesis and altered lipid composition modulates L-glutamate efflux of Corynebacterium glutamicum.

L-Glutamate is made with Corynebacterium glutamicum on a scale of more than 106 tons/year. Nevertheless, formation of this amino acid is enigmatic and there is very limited molecular information available to unravel the apparently complex conditions leading to L-glutamate efflux. Here, we report the isolation and overexpression of the genes involved in lipid synthesis: acp, fadD 15, cma, cls, pgsA2, cdsA, gpsA, and plsC, and the inactivation of cma and cls. In addition, the consequences for phospholipid content, temperature sensitivity, as well as detergent-independent and detergent-dependent L-glutamate efflux were quantified. An in part strong alteration of the phospholipid composition was achieved; for instance, overexpression offadD15 encoding an acyl-CoA ligase resulted in an increase of phosphatidyl inositol from 12.6 to 30.2%. All strains, except that overexpressing acp (acyl carrier protein), exhibited increased temperature sensitivity, with the strongest sensitivity present upon cls (cardiolipin synthetase) inactivation. As a consequence of the genetically modified lipid synthesis, L-glutamate efflux changed quite dramatically; for instance, overexpression of plsC (acylglycerolacyl transferase) resulted in a detergent-triggered increase of L-glutamate accumulation from 92 mM to 108 mM, whereas acp overexpression reduced the accumulation to 24 mM. With some of the overexpressed genes, substantial L-glutamate excretion even without detergent addition was obtained when the fermentation temperature was elevated. These data show that the chemical and physical properties of the cytoplasmic membrane are altered and suggest that this is a necessary precondition to achieve L-glutamate efflux.

The Corynebacterium glutamicum insertion sequence ISCg2 prefers conserved target sequences located adjacent to genes involved in aspartate and glutamate metabolism.

An IS element, termed ISCg2, was identified in the chromosome of Corynebacterium glutamicum ATCC 13032. After screening a cosmid library of the C. glutamicum ATCC 13032 genome, six copies of ISCg2 including their flanking regions were sequenced and analyzed. ISCg2 is 1636 bp in length and has 26-bp imperfect inverted repeats flanked by 3-bp direct repeats. By comparisons with other IS elements, ISCg2 was classified as a member of the IS30 family of insertion sequences. The six copies of ISCg2 were identical at the nucleotide level and were located in intergenic, AT-rich regions of the chromosome. The regions in which the six copies of ISCg2 were inserted displayed significant similarities. This similarity extends over a region of 65 bp, which was assumed to be the target region for ISCg2. Interestingly, five of the six copies of ISCg2 were located adjacent to genes that may be involved in aspartate and glutamate metabolism or its regulation. Investigation of the distribution of ISCg2 showed that the IS element is restricted to certain C. glutamicum strains. Analysis of various integration regions indicates active transposition of ISCg2 in C. glutamicum.

A physical and genetic map of the Corynebacterium glutamicum ATCC 13032 chromosome.

A combined physical and genetic map of the Corynebacterium glutamicum ATCC 13032 chromosome was constructed using pulsed-field gel electrophoresis (PFGE) and hybridizations with cloned gene probes. Total genomic DNA was digested with the meganucleases SwaI (5'-ATTTAAAT-3'), PacI (5'-TTAATTAA-3'), and PmeI (5'-GTTTAAAC-3') yielding 26,27, and 23 fragments, respectively. The chromosomal restriction fragments were then separated by PFGE. By summing up the lengths of the fragments generated with each of the three enzymes, a genome size of 3082 +/- 20 kb was determined. To identify adjacent SwaI fragments, a genomic cosmid library of C.glutamicum was screened for chromosomal inserts containing SwaI sites. Southern blots of the PFGE gels were hybridized with these linking clones to connect the SwaI fragments in their natural order. By this method, about 90% of the genome could be ordered into three contigs. Two of the remaining gaps were closed by cross-hybridization of blotted SwaI digests using as probes PacI and PmeI fragments isolated from PFGE gels. The last gap in the chromosomal map was closed by hybridization experiments using partial SwaI digestions, thereby proving the circularity of the chromosome. By hybridization of gene probes to SwaI fragments separated by PFGE about 30 genes, including rRNA operons, IS element and transposon insertions were localized on the physical map.