Scientific Brief

MaxCyte Enables Rapid Stable Cell Line Development for Enhanced HIV Vaccine Efficacy

Abstract

Experimental Design

The MaxCyte STX electroporated MGAT1- CHO cells with a linearized plasmid encoding a modified rgp120 (A244-N332) and G418 resistance. Cells were resuspended in a semisolid matrix containing G418 and fluorophore-labeled rgp120 antibodies

The MaxCyte STX electroporated MGAT1- CHO cells with a linearized plasmid encoding a modified rgp120 (A244-N332) and G418 resistance. Cells were resuspended in a semisolid matrix containing G418 and fluorophore-labeled rgp120 antibodies. The ClonePix2 screened 45,000 colonies under fluorescent light and picked the 44 brightest clones for rounds of expansion and screening. The top 6 clones were cultured for protein production. Purified protein from the lead clone was tested for binding to a panel of bN-mAbs via fluorescent immunoassay.

Results

Sixteen days after electroporation, a fraction of cells exhibited bright “halos” when viewed under fluorescent light, indicating high expression of rgp120.
  1. Sixteen days after electroporation, a fraction of cells exhibited bright “halos” when viewed under fluorescent light, indicating high expression of rgp120.
  2. Yields from the top 6 clones ranged from 125-400 mg/L with unoptimized culture conditions.
  3. rgp120 (A244-N332) expressed by stable clone 5F, identical to rgp120 produced by transient expression in MGAT1- CHO cells, demonstrated stronger binding to several bN-mAbs than rgp120 (A244) produced in parental CHO-S cells.

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References

  1. Byrne G, O’Rourke SM, Alexander DL, Yu B, Doran RC, Wright M, et al. (2018) CRISPR/Cas9 gene editing for the creation of an MGAT1-deficient CHO cell line to control HIV-1 vaccine glycosylation. PLoS Biol 16(8): e2005817.
  2. O’Rourke SM, Byrne G, Tatsuno G, Wright M, Yu B, Mesa KA, et al. (2018) Robotic selection for the rapid development of stable CHO cell lines for HIV vaccine production. PLoS ONE 13 (8): e0197656.