Matricellular protein SPARCL1 regulates tumor microenvironment–dependent endothelial cell heterogeneity in colorectal carcinoma
Elisabeth Naschberger, … , Werner Hohenberger, Michael Stürzl
Elisabeth Naschberger, … , Werner Hohenberger, Michael Stürzl
Published October 10, 2016
Citation Information: J Clin Invest. 2016;126(11):4187-4204. https://doi.org/10.1172/JCI78260.
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Research Article Angiogenesis Oncology

Matricellular protein SPARCL1 regulates tumor microenvironment–dependent endothelial cell heterogeneity in colorectal carcinoma

Abstract

Different tumor microenvironments (TMEs) induce stromal cell plasticity that affects tumorigenesis. The impact of TME-dependent heterogeneity of tumor endothelial cells (TECs) on tumorigenesis is unclear. Here, we isolated pure TECs from human colorectal carcinomas (CRCs) that exhibited TMEs with either improved (Th1-TME CRCs) or worse clinical prognosis (control-TME CRCs). Transcriptome analyses identified markedly different gene clusters that reflected the tumorigenic and angiogenic activities of the respective TMEs. The gene encoding the matricellular protein SPARCL1 was most strongly upregulated in Th1-TME TECs. It was also highly expressed in ECs in healthy colon tissues and Th1-TME CRCs but low in control-TME CRCs. In vitro, SPARCL1 expression was induced in confluent, quiescent ECs and functionally contributed to EC quiescence by inhibiting proliferation, migration, and sprouting, whereas siRNA-mediated knockdown increased sprouting. In human CRC tissues and mouse models, vessels with SPARCL1 expression were larger and more densely covered by mural cells. SPARCL1 secretion from quiescent ECs inhibited mural cell migration, which likely led to stabilized mural cell coverage of mature vessels. Together, these findings demonstrate TME-dependent intertumoral TEC heterogeneity in CRC. They further indicate that TEC heterogeneity is regulated by SPARCL1, which promotes the cell quiescence and vessel homeostasis contributing to the favorable prognoses associated with Th1-TME CRCs.

Authors

Elisabeth Naschberger, Andrea Liebl, Vera S. Schellerer, Manuela Schütz, Nathalie Britzen-Laurent, Patrick Kölbel, Ute Schaal, Lisa Haep, Daniela Regensburger, Thomas Wittmann, Ludger Klein-Hitpass, Tilman T. Rau, Barbara Dietel, Valérie S. Méniel, Alan R. Clarke, Susanne Merkel, Roland S. Croner, Werner Hohenberger, Michael Stürzl

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Figure 2

TECs isolated from CRC with an angiostatic Th1-TME and control-TME are pure and show an EC phenotype.

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TECs isolated from CRC with an angiostatic Th1-TME and control-TME are p...
(A) The purity of TEC cultures was determined by CD31 immunocytochemical staining. CD31-positive control cells (pink, arrows) were primary ECs (HUVECs), monocytes (THP-1), and T cells (Jurkat); CD31-negative control cells were CRC cells (DLD-1), primary SMCs, and primary fibroblasts. Scale bar: 100 μm. (B) Expression of a panel of cell type–specific markers was analyzed in isolated TECs after CD31 staining (see A) and indicated high purity compared with control cells. All TECs showed expression of markers (purple boxes) identical to that of HUVECs (orange frame). CK-20, CD45, and desmin were continuously negative (white boxes), excluding contamination with CRC tumor cells, SMCs, fibroblasts, monocytes, and T cells. Detailed values are provided in Supplemental Table 2. (C) Dot plot shows the number of MACS cycles required to obtain pure TEC cultures. (D) Expression of SA β-gal was determined by RT-qPCR in the isolated TEC cultures. Expression levels are indicated as 40-ΔCt values. SA β-gal expression could not be determined in 3 TEC cultures due to consumption of the respective RNAs by transcriptome and purity analyses. (C and D) Statistical significance was determined by Student’s t test. Mean values are indicated by line; NS, not significant.