The production of recombinant proteins plays an important role in the application of modern biotechnology. Microbial submerged fermentation is often used to produce the recombinant proteins using computer-controlled fermenter and appropriate induction strategy. The effective fermentation processes depend on real-time parameter monitoring, especially the production of target proteins. However, the production of the target proteins would not be detected until sampling and assay in most cases. Thus, it is important to have a real-time parameter to monitor the target protein production. In this study, a method for on-line monitoring of the target protein production in the methylotrophic yeast Pichia pastoris was developed by measuring the fluorescence intensity which was highly related to the heterologous gene expression. Three different polycistronic vectors were constructed. The vectors contain the AOX promoter, a signal peptide gene, the genes of GMI-X (an immunomodulatory protein from Ganoderma microsporum), a 2A peptides and EGFP, mutant EGFP (a point mutation A206K) or destabilized mEGFP, respectively. The high-yield transformats were sorted according to their fluorescence intensity using fluorescent-activated cell sorter (FACS). After methanol induction, the GMI-X extracellular supernatant was analyzed by ELISA and the intracellular EGFPs fluorescence intensity was measured by fluorescence spectrometry. The results showed that transformants of EGFP with the dimerization tendency fluoresced had less intensity than transformants of mutant EGFP, which tends to form monomer and soluble green fluorescent protein in cells. There was positive correlation between the fluorescence intensity and target gene expression in both EGFP and mEGFP transformants. Surprisingly, destabilized mEGFP was degraded quickly after translation due to the PEST sequence, and the fluorescence intensity of dmEGFP transformant remained at a low level, whereas the production of GMI-X still increased with the time of methanol induction. The highest yield of GMI-X was found in the dmEGFP transformant among three different EGFP forms. Also, the data from fermenter showed dmEGFP transformant had higher methanol utilization efficiency and GMI-X expression than mEGFP counterpart. Furthermore, all transformants sorted by FACS contained high copy numbers. In conclusion, the EGFP and mEGFP constructions provide a real-time parameter to monitor the target protein production, while the dmEGFP construction minimizes the EGFP burden and is feasible for elongated induction.