Different Genetic Signatures of Small-Cell Lung Cancer Characterize Anti-GABAB R and Anti-Hu Paraneoplastic Neurological Syndromes.

OBJECTIVE: Small-cell lung cancer (SCLC) is the malignancy most frequently associated with paraneoplastic neurological syndromes (PNS) and can trigger different antibody responses against intracellular (Hu) or neuronal surface (GABAB R) antigens. Our aim was to clarify whether the genomic and transcriptomic features of SCLC are different in patients with anti-GABAB R or anti-Hu PNS compared with SCLC without PNS. METHODS: A total of 76 SCLC tumor samples were collected: 34 anti-Hu, 14 anti-GABAB R, and 28 SCLC without PNS. The study consisted of 4 steps: (1) pathological confirmation; (2) next generation sequencing using a panel of 98 genes, including those encoding the autoantibodies targets ELAVL1-4, GABBR1-2, and KCTD16; (3) genome-wide copy number variation (CNV); and (4) whole-transcriptome RNA sequencing. RESULTS: CNV analysis revealed that patients with anti-GABAB R PNS commonly have a gain in chromosome 5q, which contains KCTD16, whereas anti-Hu and control patients often harbor a loss. No significantly different number of mutations regarding any onconeural genes was observed. Conversely, the transcriptomic profile of SCLC was different, and the differentially expressed genes allowed effective clustering of the samples into 3 groups, reflecting the antibody-based classification, with an overexpression of KCTD16 specific to anti-GABAB R PNS. Pathway analysis revealed that tumors of patients with anti-GABAB R encephalitis were enriched in B-cell signatures, as opposed to those of patients with anti-Hu, in which T-cell- and interferon-γ-related signatures were overexpressed. INTERPRETATION: SCLC genetic and transcriptomic features differentiate anti-GABAB R, anti-Hu, and non-PNS tumors. The role of KCTD16 appears to be pivotal in the tumor immune tolerance breakdown of anti-GABAB R PNS. ANN NEUROL 2023;94:1102-1115.

Targeted imaging of α(v)ß(3) expressing sarcoma tumor cells in vivo in pre-operative setting using near infrared: a potential tool to reduce incomplete surgical resection.

Tumor size and location along with efficacy of pre-operative imaging are limiting factors for optimal surgical excision for osteosarcoma. Our general hypothesis is that targeting αvß3 integrin-rich osteosarcoma neoangiogenesis should provide improved delivery of diagnostic compounds and assist surgeons intra operatively using near-infrared imaging techniques. We evaluated in an orthotopic metastatic osteosarcoma in rats the potential of AngioStamp™ targeting αvß3 integrins and detected intra operatively by near infrared (NIR) illumination (Fluobeam™) as a novel, intra operative imaging technique. To determine the potential of this association in improving tumor and metastasis detection, we compared the quality and sensitivity of tumor/metastasis margin delineation and tumor resection using intra-operative NIR imaging to the ones guided by pre-operative imaging (i.e., MRI subsequently confirmed by histopathological analysis). Chemotherapy being essential in osteosarcoma treatment, we evaluated the capacity of AngioStamp™ to specifically localize to the tumor after chemotherapy treatment. We showed a significantly lesser extent of healthy tissue resection after surgical excision when assessing tumor margin intra operatively using AngioStamp™/Fluobeam™ association compared to pre-operative MRI post-operatively confirmed by histopathological analysis (p<0.01). Importantly, intra-operative NIR illumination of lungs revealed more metastases than were detected by CT Scan or under intra-operative white light examination (p<0.01). Importantly, chemotherapy did not alter AngioStamp™ tumor specific targeting nor the sensitivity of tumor detection. Our preclinical data confirm the potential of intra-operative imaging for improved primary tumor and lung metastasis excision. Based on these promising results, we now propose to evaluate this approach as a mean to improve surgical excision while maintaining tumor control in other sarcoma or tumors overexpressing αvß3 integrins.

Antagonistic regulation of EMT by TIF1γ and Smad4 in mammary epithelial cells.

TGF-ß is a potent inducer of epithelial-to-mesenchymal transition (EMT), a process involved in tumour invasion. TIF1γ participates in TGF-ß signalling. To understand the role of TIF1γ in TGF-ß signalling and its requirement for EMT, we analysed the TGF-ß1 response of human mammary epithelial cell lines. A strong EMT increase was observed in TIF1γ-silenced cells after TGF-ß1 treatment, whereas Smad4 inactivation completely blocked this process. Accordingly, the functions of several TIF1γ target genes can be linked to EMT, as shown by microarray analysis. As a negative regulator of Smad4, TIF1γ could be crucial for the regulation of TGF-ß signalling. Furthermore, TIF1γ binds to and represses the plasminogen activator inhibitor 1 promoter, demonstrating a direct role of TIF1γ in TGF-ß-dependent gene expression. This study shows the molecular relationship between TIF1γ and Smad4 in TGF-ß signalling and EMT.