Application of polymers with upper critical solution temperature (UCST-type polymers) was less investigated comparing to polymers with lower critical solution temperature (LCST-type polymers), as they are generally more sensitive to environmental changes, such as pH and salt condition. However, in our view, UCST-type polymers have great potential application in the territory of biotechnology. Using UCST-type polymers as supports for immobilization of organisms and their derivatives could solves the problem of deactivation caused by the requirement of increasing temperature during the separation process of LCST-type polymers. In this study, we focused on developing the application of UCST-type polymers in protein purification and enzyme immobilization. Ureido-derivatized UCST-type polymers, Poly(allylamine)-co-poly(allylurea)s (PAUs) were chosen based on the following advantages: (1) Synthesis procedure of PAUs is simple; (2) PAUs have easily-modified functional groups, amine group; (3) Increasing phase separation temperature of PAUs under elevated salt condition makes the separation process of these polymers easier. In the metal-chelate protein purification based on UCST-type polymers, we successfully modified PAUs with iminodiacetic acid (IDA) to create PAU-IDAs, polymers simultaneously present UCST behavior and have the ability to chelate metal ion. PAU-IDA with 0.75 and 0.10 ratio of original amine groups transformed to ureido groups and IDA groups respectively (PAU-0.75-IDA-0.10) show phase separation temperature (Tp) of 14.4°C without metal ion, 14.8°C with nickel ion loaded, and 21.5°C with copper ion loaded in PBS, which is suitable operation condition for protein purification. In protein capture investigation, Cu2+ loaded PAU-0.75-IDA-0.10 (PAU-0.75-IDA-0.10-Cu) displayed a his-tagged protein A binding capacities of 396 μg/ mg polymer and captured up to 98% among 100 μg his-tagged protein A in the solution by 2.5 mg of this polymer. Besides, up to 89.7% of captured his-tag protein A was eluted by one time of elution through buffer containing 50 mM imidazole. Lastly, PAU-IDA-Cu was used to treat protein mixture and successfully separated his-tagged protein A form the mixture. In the enzyme immobilization on UCST-type polymers, cellulase was immobilized on PAU through EDC/NHS coupling. The immobilized cellulase show a Tp of 22.1°C in acetate buffer (300 mM, pH 4.8) which is desirable for cellulase reaction. The influence of pH and temperature to the hydrolysis of CMC by immobilized CMC was investigated. After hydrolysis reaction, immobilized cellulase can be recovered through cooling and centrifugation. In the recycling experiment, immobilized cellulase remained undenatured after 5 cycles of hydrolysis reaction.