Geometric tumor embolic budding characterizes inflammatory breast cancer.

PURPOSE: Inflammatory breast cancer (IBC) is characterized by numerous tumor emboli especially within dermal lymphatics. The explanation remains a mystery. METHODS: This study combines experimental studies with two different IBC xenografts with image algorithmic studies utilizing human tissue microarrays (TMAs) of IBC vs non-IBC cases to support a novel hypothesis to explain IBC's sina qua non signature of florid lymphovascular emboli. RESULTS: In the human TMAs, compared to tumor features like nuclear grade (size), mitosis and Ki-67 immunoreactivity which show that IBC is only modestly more proliferative with larger nuclei than non-IBC, what really sets IBC apart is the markedly greater number of tumor emboli and distinctly smaller emboli whose numbers indicate geometric or exponential differences between IBC and non-IBC. In the experimental xenograft studies, Mary-X gives rise to tight spheroids in vitro which exhibit dynamic budding into smaller daughter spheroids whereas Karen-X exhibits only loose non-budding aggregates. Furthermore Mary-X emboli also bud dramatically into smaller daughter emboli in vivo. The mechanism that regulates this involves the generation of E-cad/NTF1, a calpain-mediated cleavage 100 kDa product of 120 kDa full length membrane E-cadherin. Inhibiting this calpain-mediated cleavage of E-cadherin by blocking either the calpain site of cleavage (SC) or the site of binding (SB) with specific decapeptides that both penetrate the cell membrane and mimic either the cleavage site or the binding site on E-cadherin, inhibits the generation of E-cad/NTF1 in a dose-dependent manner, reduces spheroid compactness and decreases budding. CONCLUSION: Since E-cad/NFT1 retains the p120ctn binding site but loses the α-and ß-catenin sites, promoting its 360° distribution around the cell's membrane, the vacilating levels of this molecule trigger budding of both the spheroids as well as the emboli. Recurrent and geometric budding of parental emboli into daughter emboli then would account for the plethora of emboli seen in IBC.

Programmed Death-Ligand 1 Expression in Lymphovascular Tumor Emboli in Lung Cancer.

Introduction: Programmed death-ligand 1 (PD-L1) expression determined by immunohistochemistry is the most widely used biomarker for predicting response to immune checkpoint inhibitors. The characteristics of PD-L1 expression in tumor cells inside lymphovascular spaces are largely unknown. Although PD-L1 expression in circulating tumor cells within vascular spaces had been studied, results were conflicting due to lack of standardized PD-L1 expression assessment. Methods: We investigated PD-L1 expression in lung cancer primary tumor tissue, lymphovascular tumor emboli, and lymph node metastasis using the standard PD-L1 immunohistochemistry 22C3 pharmDx assay. PD-L1 expression was scored in the primary tumor, lymphovascular emboli, and lymph node metastasis by a pathologist using the tumor proportion score (TPS). Results: We collected and analyzed surgical specimens from 36 patients with lung cancer with lymph node metastasis. In the primary tumor, 64% of cases were PD-L1 negative (TPS < 1%), 25% were PD-L1 low (TPS 1%-49%), and 11% were PD-L1 high (TPS ≥ 50%). In contrast, in lymphovascular tumor emboli, 89% of cases were PD-L1 negative, 11% were PD-L1 low, and none were PD-L1 high. In lymph node metastases, 72% of cases were PD-L1 negative, 17% were PD-L1 low, and 11% were PD-L1 high. Conclusions: We observed a significant decrease of PD-L1 expression in lymphovascular tumor emboli compared with that in primary tumors (p = 0.002). Whether such differences are related to intrinsic tumor cell heterogeneity or extrinsic factors such as the microenvironment warrants further investigation.