The aim of this work was to design and study biological properties of the recombinant human granulocyte colony stimulating factor (G-CSF), «linked» to apolipoprotein A-I (apoA-I) by a peptide linker, for obtaining in perspective a prolong form of the drug based on this cytokine. Material and methods . The nucleotide sequences of the genes encoding G-CSF and apoA-I were designed and optimized for expression in Pichia pastoris yeast using several computer programs. The assembly of the gene coding for the G-CSF-apoA-I chimeric cytokine, its cloning in the pPICZa-A vector, and expression in P. pastoris cells were performed using standard genetic engineering methods. Purification of the chimeric cytokine was carried out by two-stage ion-exchange chromatography. The biological activity of the chimera was determined in vitro on rat and human bone marrow cells (BMC) using flow cytometry, cell cycle analysis and myelograms. Results. A recombinant P pastoris X-33 yeast strain producing a chimeric cytokine containing the amino acid sequence G-CSF from the N-terminus, and mature human apoA-I from the C-terminus was constructed. In experiments on BMC of rat, it was shown that G-CSF-apoA-I increases the number of granulocytes in 1.8-2 times less compared with G-CSF. At the same time, the chimeric cytokine maintained the viability of monocytic and lymphocytic cells. Unlike G-CSF, the chimera increased the number of blast cells and normalized neutrophil segmentation, reducing the number of anomalies 1.5 times more efficiently. Conclusion . A new chimeric cytokine G-CSF-apoA-I was constructed, exhibiting the properties of not only a colony-stimulating factor, but also a growth factor, supporting the viability of other types of BMC.