Evaluation of Tyro3 expression, Gas6-mediated Akt phosphorylation, and the impact of anti-Tyro3 antibodies in melanoma cell lines.

Tyro3, a member of the Tyro3/Axl/Mer (TAM) family of receptor tyrosine kinases, has emerged as a potential oncogene in melanoma. Here, we confirm that Tyro3 is specifically overexpressed in primary melanoma samples and show that Tyro3 is expressed at varying levels in numerous melanoma cell lines. Short hairpin RNA-mediated knockdown of Tyro3 led to significant cell death via apoptotic mechanisms in nearly all melanoma cell lines tested, regardless of the BRAF or NRAS mutation status or co-expression of Axl and/or Mer. We generated soluble and monomeric versions of the human Tyro3 extracellular domain and human Gas6 for affinity measurements and correlated these values with the level of Gas6 required to induce Tyro3 signaling in cellular assays. Calcium was critical for the correct folding of Gas6 and its binding to Tyro3. In melanoma cell lines, Gas6 induced Tyro3 phosphorylation and downstream Akt phosphorylation without apparent effects on Erk. We generated monoclonal antibodies (mAbs) against Tyro3 to examine their effect on survival signaling in melanoma cell lines. The mAbs generated against Tyro3 included nonligand blockers, partial blockers, and competitive ligand blockers. A number of weak and partial ligand blockers (all recognizing the Tyro3 Ig domains) were the most effective at blocking ligand-mediated downstream signaling of Tyro3. Overall, these data indicate that Tyro3 may confer increased survival signals in melanoma cells and can be stymied using inhibitory mAbs. These mAbs may be useful for further investigations of the role of Tyro3 in melanoma.

Secretion from bacterial versus mammalian cells yields a recombinant scFv with variable folding properties.

Escherichia coli (E. coli) is the most commonly used organism for expressing antibody fragments such as single chain antibody Fvs (scFvs). Previously, we have utilized E. coli to express well-folded scFvs for characterization and engineering purposes with the goal of using these engineered proteins as building blocks for generating IgG-like bispecific antibodies (BsAbs). In the study, described here, we observed a significant difference in the secondary structure of an scFv produced in E. coli and the same scFv expressed and secreted from chinese hamster ovary (CHO) cells as part of a BsAb. We devised a proteolytic procedure to separate the CHO-derived scFv from its antibody-fusion partner and compared its properties with those of the E. coli-derived scFv. In comparison to the CHO-derived scFv, the E. coli-derived scFv was found trapped in a misfolded, but monomeric state that was stable for months at 4 °C. The misfolded state bound antigen in a heterogeneous fashion that included non-specific binding, which made functional characterization challenging. This odd incidence of obtaining a misfolded scFv from bacteria suggests careful characterization of the folded properties of bacterially expressed scFvs is warranted if anomalous issues with antigen-binding or non-specificity occur during an engineering campaign. Additionally, our proteolytic methodology for obtaining significant levels of intact scFvs from highly expressed IgG-like antibody proteins serves as a robust method for producing scFvs in CHO without the use of designed cleavage motifs.