Location effects of a reporter gene on expression levels and on native protein synthesis in Lactococcus lactis and Saccharomyces cerevisiae.

The engineering of industrially important genetically modified organisms by the integration of heterologous genes into the chromosome is often the method of choice for several reasons concerned with long-term stability, homogeneous population distribution, and the enabling of selection without the addition of antibiotics. However, integration may disrupt endogenous gene expression, giving rise to increased levels of toxic metabolic byproducts or activating otherwise silent genes. The position of integration of a foreign gene in the chromosome can also influence its expression levels, and this effect will be of relevance in terms of optimizing protein production parameters. In this study, we determine how the random integration of a foreign reporter gene might affect expression levels and assess the use of proteome analysis to investigate possible effects on synthesis of endogenous proteins in two important food-relevant microorganisms, Saccharomyces cerevisiae and Lactococcus lactis. Eleven L. lactis integrants carrying the gusA gene were analyzed, and expression levels were found to vary by a factor of threefold in contrast to expression levels of lacZ in 18 S. cerevisiae integrants, which showed a 14-fold variation. Of relevance to industry is whether any changes in expression levels might occur as a consequence of storage of the modified strains. Here it is also shown that the above differences in expression levels were not significantly affected by storage of frozen cultures over a period of several months. Analysis of the protein composition of the yeast and lactococcal integrant strains by separation on one-dimensional (1D) and 2D gels showed no significant variations in position beyond those observed in control samples.