Erythropoietin (EPO) is glycoprotein hormone influencing the red blood cell production in bone marrow. It is most widely used for treatment of anemia – a lack of red blood cells in bloodstream. EPO molecule is composed of protein backbone with four glycosylation sites. Isoforms with different glycosylation patterns exist and show different in vivo bioactivity. Thus it is crucial to regulate such isoform ratios in drug substance. An ion exchange chromatographic step (IEC) is employed to set the specified net charge isoform ratio. Net charge isoforms in the context are defined as isoforms with the same net charge. In this work the chromatographic step is investigated by mechanistic modeling approach. The mechanistic model simulates the elution of net charge isoforms at different elution gradient slopes. The mechanistic model combines the standard displacement model for binding and general rate model for transport phenomena. The model is implemented within the CADET software framework. The binding parameters are obtained by Yamamoto method. Among transport parameters, the axial dispersion and film diffusion are taken into account. Their value is obtained by fitting the simulated peak shapes to the experimental ones. The model successfully describes the retention times of net charge isoforms. However it underperforms in describing the peak broadening across different gradient slopes. Further investigation reveals that the separation is essentially independent of gradient length. This phenomena implies many subspecies with different binding properties within the single net charge isoform.