Provided is a composition for inducing tumor cell senescence and a method for inducing tumor cell senescence using the same. The composition can inhibit a PAPSS2 gene in a tumor cell to thereby induce senescence of the tumor cell, and if the composition is used concurrently with irradiation of the tumor cell, the composition can improve the sensitivity of the tumor cell to radiation.

The invention provides a method for producing a sulfated polysaccharide by generating a sulfated polysaccharide by incorporating, in a reaction solution in the presence of ATP or an ATP source, a sulfate ion source, and N-sulfoheparosan, a transformant (a) of a bacterium of the genus Corynebacterium, comprising at least a gene encoding an ATP sulfurylase and a gene encoding an APS kinase, and at least one selected from a transformant (b) of a microorganism belonging to prokaryotes, comprising at least a gene encoding a C5-epimerase, a transformant (c) of a microorganism belonging to prokaryotes, comprising at least a gene encoding a 2-O-sulfotransferase, a transformant (d) of a microorganism belonging to prokaryotes, comprising at least a gene encoding a 6-O-sulfotransferase, and a transformant (e) of a microorganism belonging to prokaryotes, comprising at least a gene encoding a 3-O-sulfotransferase.

The present disclosure discloses a method for efficient catalytic synthesis of PAPS based on constructing an ATP regeneration system, and belongs to the technical field of bioengineering. Efficient production of PAPS is realized through microbial recombination expression and artificial construction of PAPS bifunctional synthetase. On the basis, an ATP regeneration system coupling with polyphosphate kinase from Corynebacterium glutamicum and Mycobacterium tuberculosis can be used for recovering two byproducts: pyrophosphoric acid and ADP at the same time, the equivalent conversion of a substrate and a product is realized, the PAPS generated in a catalysis system has high purity, and the sulfonic acid group donation in most sulfonic acid transfer reactions can be realized.

Disclosed is a method for constructing a synthesis and regeneration system based on APS as an active sulfonate donor, belonging to the technical field of biology. The present disclosure provides a new purpose of APS as an active sulfonate donor, and greatly improves the synthesis efficiency of the APS by screening different ATP sulfurylases and adding a pyrophosphatase into a reaction system to eliminate pyrophosphate as a byproduct. Further, the construction of a sulfonation modification system is realized by constructing an APS circulation regeneration system. Compared with a PAPS regeneration system, the APS circulation regeneration system has the advantages of short path and high efficiency, the sulfonation modification efficiency is significantly improved, and the synthesis cost is successfully reduced.