Indolent multicentric chordoma - A previously undescribed entity: A Case report and literature review.

Background: Chordomas are rare neuraxial tumors arising from remnants of primitive notochord. They are generally slow-growing malignant neoplasms. Only four adult cases of multicentric chordomas have been reported, all with aggressive and rapid growth. Here, we present an unusual case of indolent multicentric chordomas involving cervical and thoracic spine, sacrum, and calvarium. Case Description: A 60-year-old male was found to have multiple lesions throughout his neuroaxis incidentally on workup for colitis. A needle biopsy documented the diagnosis of chordoma. This has been followed for more than 4 years with no progression. Conclusion: We present the first reported case of indolent multicentric chordomas. Due to the extreme rarity of indolent multicentric chordomas, close follow-up is needed and recommended.

Targeting cellular heterogeneity with CXCR2 blockade for the treatment of therapy-resistant prostate cancer.

Hormonal therapy targeting androgen receptor (AR) is initially effective to treat prostate cancer (PCa), but it eventually fails. It has been hypothesized that cellular heterogeneity of PCa, consisting of AR+ luminal tumor cells and AR- neuroendocrine (NE) tumor cells, may contribute to therapy failure. Here, we describe the successful purification of NE cells from primary fresh human prostate adenocarcinoma based on the cell surface receptor C-X-C motif chemokine receptor 2 (CXCR2). Functional studies revealed CXCR2 to be a driver of the NE phenotype, including loss of AR expression, lineage plasticity, and resistance to hormonal therapy. CXCR2-driven NE cells were critical for the tumor microenvironment by providing a survival niche for the AR+ luminal cells. We demonstrate that the combination of CXCR2 inhibition and AR targeting is an effective treatment strategy in mouse xenograft models. Such a strategy has the potential to overcome therapy resistance caused by tumor cell heterogeneity.

Alternative polyadenylation factors link cell cycle to migration.

BACKGROUND: In response to a wound, fibroblasts are activated to migrate toward the wound, to proliferate and to contribute to the wound healing process. We hypothesize that changes in pre-mRNA processing occurring as fibroblasts enter the proliferative cell cycle are also important for promoting their migration. RESULTS: RNA sequencing of fibroblasts induced into quiescence by contact inhibition reveals downregulation of genes involved in mRNA processing, including splicing and cleavage and polyadenylation factors. These genes also show differential exon use, especially increased intron retention in quiescent fibroblasts compared to proliferating fibroblasts. Mapping the 3' ends of transcripts reveals that longer transcripts from distal polyadenylation sites are more prevalent in quiescent fibroblasts and are associated with increased expression and transcript stabilization based on genome-wide transcript decay analysis. Analysis of dermal excisional wounds in mice reveals that proliferating cells adjacent to wounds express higher levels of cleavage and polyadenylation factors than quiescent fibroblasts in unwounded skin. Quiescent fibroblasts contain reduced levels of the cleavage and polyadenylation factor CstF-64. CstF-64 knockdown recapitulates changes in isoform selection and gene expression associated with quiescence, and results in slower migration. CONCLUSIONS: Our findings support cleavage and polyadenylation factors as a link between cellular proliferation state and migration.