Innovative approaches to establish and characterize primary cultures: an ex vivo 3D system and the zebrafish model.

Chiara Liverani,Federico La Manna,Toni Ibrahim,Laura Mercatali,Federica Recine,Federica Pieri,Davide Cavaliere,Gabri Van Der Pluijm,Giacomo Miserocchi,Ennio Tasciotti,Arwin Groenewoud,Chiara Spadazzi,Alessandro De Vita,Dino Amadori,Alberto Bongiovanni,Nada Riva,Ewa Snaar-Jagalska

doi:10.1242/bio.022483

Abstract

ABSTRACTPatient-derived specimens are an invaluable resource to investigate tumor biology. However, in vivo studies on primary cultures are often limited by the small amount of material available, while conventional in vitro systems might alter the features and behavior that characterize cancer cells. We present our data obtained on primary dedifferentiated liposarcoma cells cultured in a 3D scaffold-based system and injected into a zebrafish model. Primary cells were characterized in vitro for their morphological features, sensitivity to drugs and biomarker expression, and in vivo for their engraftment and invasiveness abilities. The 3D culture showed a higher enrichment in cancer cells than the standard monolayer culture and a better preservation of liposarcoma-associated markers. We also successfully grafted primary cells into zebrafish, showing their local migratory and invasive abilities. Our work provides proof of concept of the ability of 3D cultures to maintain the original phenotype of ex vivo cells, and highlights the potential of the zebrafish model to provide a versatile in vivo system for studies with limited biological material. Such models could be used in translational research studies for biomolecular analyses, drug screenings and tumor aggressiveness assays.

Highlights

Tissue specimens from patients provide the ideal experimental material to study the heterogeneous biology and behavior of cancer cells
Hematoxylin and eosin (HE) staining of the surgical specimen showed a tumor with high cellularity and mostly spindle-shaped cells arranged in storiform patterns
The biomimetic properties of the collagen scaffold induced primary cells to strongly interact with the surrounding matrix

Summary

Introduction

Tissue specimens from patients provide the ideal experimental material to study the heterogeneous biology and behavior of cancer cells. These systems mimic the composition and signaling cues of the tumor extracellular matrix, which may influence the genotype, phenotype and behavior of cancer cells (Lamhamedi-Cherradi et al, 2014; Yamada et al, 2007) For this reason the use of 3D culture has been extensively explored for the study of cancer cell lines (Florczyk et al, 2013; Hirt et al, 2015; Fitzgerald et al, 2015) and has been reported for patient-derived primary material (Reagan et al, 2014; Lv et al, 2016). It is divided into three different subtypes on the basis of histological characteristics: well differentiated/ dedifferentiated (WDLPS/DDLPS), myxoid (MLPS) and pleomorphic (PLS)

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