In this study, the xylanase gene from the rumen fungus Neocallimastix frontalis was expressed in Pichia pastoris and Pichia methanolica. In the study of methanol induction strategy of P. methanolica, the highest xylanase activity, fewest amounts of methanol feeding, and least cell growth was made by using continuous methanol feeding strategy. Using high cell density culture with medium replacement before induction and the maintenance of the methanol induction level at 0.5%, P. pastoris was able to produce about 5400 U/ml of xylanase after 10 days of induction. For P. methanolica, about 6200 U/ml of xylanase was reached after 10 days of induction using synthetic medium as first culture medium and then direct induction by continuous methanol feed at 1.8 ml/l/h. In general, the advantages of using P. methanolica to produce the xylanase were higher protein production, the lack of medium replacement, and an ease of scale up. However, due to the culture supernatant with fewer secreted non-target proteins, xylanase purification in P. pastoris would be easier than in the P. methanolica system. The recombinant xylanases from P. pastoris and P. methanolica were glycoproteins, which were in complex O-link glycosylation and had good thermostability and pH stability. In addition, methanol pulses-chase experiment suggested that these was a corelation among base feeding, methanol consumption and xylanase activity. In addition, in order to improve the application of methyltrophic yeast by dicistronic expression plasmid, a methyltrophic yeast dicistronic expression vector was constructed based on the 5’UTR internal ribosome entry site (IRES) of the Saccharomyces cerevisiae p150, YAP1, TFIID, HAP4. Expression vector containing the Neocallimastix frontallis xylanase gene and green fluorescent protein gene flanking the yeast 5’UTR IRES can produce recombinant xylanase and fluorescence in methyltrophic yeast Hansenula polymorpha under the control of alcohol oxidase1 (AOX1) promoter. After methanol induction for three days, the green fluorescence in H. polymorpha was observed under fluorescence microscope. From Western blot analysis, the expression of green fluorescent protein was confirmed. Unfortunately, Pichia pastoris containing this dicistronic plasmid with p150 5’UTR IRES can not produce green fluorescent protein. These results suggest that the S. cerevisiae p150, YAP1, TFIID, HAP4 IRES can be used in the development of dicistronic expression vectors for production of heterologous multiprotein complexes, or can be used for selection markers to facilitate the applications of H. polymorpha.