Protein genes Ag85A, Esat-6, and Cfp10 of Mycobacterium tuberculosis were sequenced using the database GenBank to implement selection and synthesis of primer pairs of given genes. PCR was used to obtain target amplicons of the genes. Chromosome DNA of M. tuberculosis H37Rv was used as the DNA amplification matrix. The PCR products were obtained using the plasmid pQE6, cloned, and amplified in the Escherichia coli M15 strain. Chimere products containing mycobacterial genes and cellulose binding protein domain (CBD), were obtained using the plasmid treated with restriction endonucleases. CBD fragment obtained using similar treatment of the ptt10 plasmid. The plasmids containing merged sequences of mycobacterial genes-antigenes and CBD were selected. The 3 mycobacterial genes were expressed in the E. coli M15 cells resulting in biosynthesis of corresponding recombinant proteins of expected molecular weight. Concentration of CBD, Cfp10-CBD, Ag85A-CBD, and ESAT6-CBD was 20%, 15%, and 15% total protein, respectively. The resulting chimere proteins provide high affinity for cellulose and high stability. Immobilization of CBD-containing recombinant proteins proceeds as one-stage process providing target protein purification and adsorption on cellulose. The vaccines produced using this technology are inexpensive because of low cost of cellulose sorbents as well as simultaneous use of cellulose for purification and immobilization of protein. Many cellulose preparations are not toxic, biocompatible, and widely used in medicine.