Evaluation and comparison of the GUS, LUC and GFP reporter system for gene expression studies in plants

The detailed analysis of the expression pattern of a plant gene can give important clues about its function in plant development, cell differentiation and defence reactions. Gene expression studies have been greatly facilitated by the employment of proteins like beta-glucuronidase (GUS), green fluorescent protein (GFP), and firefly luciferase (LUC) as reporters of gene activity. The application of reporter genes in plants, specifically in the field of gene expression studies, has expanded over the years from a mere tool to quantify (trans) gene expression in tissue samples, to real-time imaging of in planta promoter dynamics. To correctly interpret the activity that is given by each reporter, it is important to have a good understanding of the intrinsic properties of the different reporter proteins. Here we discuss those properties of GUS, LUC and GFP that are of interest in gene expression studies

Evaluation and comparison of the GUS, LUC and GFP reporter system for gene expression studies in plants

The detailed analysis of the expression pattern of a plant gene can give important clues about its function in plant development, cell differentiation and defence reactions. Gene expression studies have been greatly facilitated by the employment of proteins like beta-glucuronidase (GUS), green fluorescent protein (GFP), and firefly luciferase (LUC) as reporters of gene activity. The application of reporter genes in plants, specifically in the field of gene expression studies, has expanded over the years from a mere tool to quantify (trans) gene expression in tissue samples, to real-time imaging of in planta promoter dynamics. To correctly interpret the activity that is given by each reporter, it is important to have a good understanding of the intrinsic properties of the different reporter proteins. Here we discuss those properties of GUS, LUC and GFP that are of interest in gene expression studies

Evaluation and comparison of the GUS, LUC and GFP reporter system for gene expression studies in plants

The detailed analysis of the expression pattern of a plant gene can give important clues about its function in plant development, cell differentiation and defence reactions. Gene expression studies have been greatly facilitated by the employment of proteins like beta-glucuronidase (GUS), green fluorescent protein (GFP), and firefly luciferase (LUC) as reporters of gene activity. The application of reporter genes in plants, specifically in the field of gene expression studies, has expanded over the years from a mere tool to quantify (trans) gene expression in tissue samples, to real-time imaging of in planta promoter dynamics. To correctly interpret the activity that is given by each reporter, it is important to have a good understanding of the intrinsic properties of the different reporter proteins. Here we discuss those properties of GUS, LUC and GFP that are of interest in gene expression studies

Ethanol breaks dormancy of the potato tuber apical bud

Growing potato tubers or freshly harvested mature tubers have a dormant apical bud. Normally, this dormancy is spontaneously broken after a period of maturation of the tuber, resulting in the growth of a new sprout. Here it is shown that in in vitro-cultured growing and maturing tubers, ethanol can rapidly break this dormancy and re-induce growth of the apical bud. The in vivo promoter activity of selected genes during this secondary growth of the apical bud was monitored, using luciferase as a reporter. In response to ethanol, the expression of carbohydrate-storage, protein-storage, and cell division-related genes are rapidly down-regulated in tuber tissue. It was shown that dormancy was broken by primary but not by secondary alcohols, and the effect of ethanol on sprouting and gene expression in tuber tissue was blocked by an inhibitor of alcohol dehydrogenase. By contrast, products derived from alcohol dehydrogenase activity (acetaldehyde and acetic acid) did not induce sprouting, nor did they affect luciferase reporter gene activity in the tuber tissue. Application of an inhibitor of gibberellin biosynthesis had no effect on ethanol-induced sprouting. It is suggested that ethanol-induced sprouting may be related to an alcohol dehydrogenase-mediated increase in the catabolic redox charge [NADH/(NADH+NAD+)]

Ethanol breaks dormancy of the potato tuber apical bud

Growing potato tubers or freshly harvested mature tubers have a dormant apical bud. Normally, this dormancy is spontaneously broken after a period of maturation of the tuber, resulting in the growth of a new sprout. Here it is shown that in in vitro-cultured growing and maturing tubers, ethanol can rapidly break this dormancy and re-induce growth of the apical bud. The in vivo promoter activity of selected genes during this secondary growth of the apical bud was monitored, using luciferase as a reporter. In response to ethanol, the expression of carbohydrate-storage, protein-storage, and cell division-related genes are rapidly down-regulated in tuber tissue. It was shown that dormancy was broken by primary but not by secondary alcohols, and the effect of ethanol on sprouting and gene expression in tuber tissue was blocked by an inhibitor of alcohol dehydrogenase. By contrast, products derived from alcohol dehydrogenase activity (acetaldehyde and acetic acid) did not induce sprouting, nor did they affect luciferase reporter gene activity in the tuber tissue. Application of an inhibitor of gibberellin biosynthesis had no effect on ethanol-induced sprouting. It is suggested that ethanol-induced sprouting may be related to an alcohol dehydrogenase-mediated increase in the catabolic redox charge [NADH/(NADH+NAD+)]