초록
<P>The annotation of full genomes of amylolytic lactic acid bacteria (ALAB) leads to conviction that many of them contain a basic pool of chromosomal genes, responsible for starch hydrolysis. However, only the strains that are forced to survive in starchy environment are able to display these genetically determined properties. The aim of the present work is to investigate the genes actually engaged in starch utilization by ALAB using gene transcription assay. Twenty five new ALAB strains, belonging to 11 distinct species of four genera were isolated and analyzed. Among them, the first amylolytic <I>Lactobacillus sakei</I>, <I>Enterococcus</I> <I>faecium</I>, and <I>E. durans</I> were reported. The presence and expression of the genes <I>amy1</I>, <I>glgP</I>, <I>glgB</I>, <I>agl</I>, <I>malL</I>, <I>treC</I>, and <I>dexC</I> were examined. Although all strains possessed extracellular and cell‐bound amylase activity and produced lactic acid from starch, high genus and species specificity in the gene expression was observed. ALAB strains of genus <I>Lactobacillus</I> (except <I>L. sakei</I>) and <I>P. acidilactici</I> own and express all the tested genes, while <I>E. faecium</I> and <I>E. durans</I> strains expressed predominantly the gene, encoding amylase. The co‐transcription of <I>glgP</I> and <I>glgB</I> genes indicates that glycogen synthesis and starch degradation occur in parallel, which is another example for dual metabolic role of biochemical paths.</P>