The Escherichia coli beta-glucuronidase gene (gus) has been developed as a reporter gene for plants, and has been widely used for over a decade. Both chromogenic and fluorogenic GUS substrates have been synthesized, allowing rapid nonradioactive assays. The use of the Escherichia coli enzyme beta-glucuronidase (GUS) as a reporter in gene expression studies is limited by some plants and plant-associated bacteria express endogenous glucuronidase activities. The use of the enzyme as a reporter in transgenic plants is limited by high false positive. Laboratory evolution methods were used to enhance the thermostability and activity of the beta-glucuronidase. Using plasmid pBI121 as template, a 1.8 kb specific product was amplified and cloned into the vector pBluescript SK. The result of nucleotide sequence analysis was the same as reported. In vitro recombination (DNA shuffling), which involves DNase I digestion, primerless PCR, and primer PCR was used to generate mutant libraries. The mutant GUS3-3 gene was isolated after three rounds of mutation, DNA shuffling, and screening. The GUS3-3 enzyme can resistant high temperature up to 80 degrees C for 30 min. The nucleotide sequence analysis showed 99.2% homology between the GUS-ck gene from pBI121 and GUS3-3 gene. The deduced amino acid sequence demonstrated that 11 amino acid was changed. The Tm value of GUS3-3 is 80 degrees C and increased by 25 degrees C above GUS-ck (55 degrees C). The researches indicated the feasibility of the molecular evolution of beta-glucuronidase in vitro to improve enzymatic thermostability.