Androgen drives melanoma invasiveness and metastatic spread by inducing tumorigenic fucosylation.

Melanoma incidence and mortality rates are historically higher for men than women. Although emerging studies have highlighted tumorigenic roles for the male sex hormone androgen and its receptor (AR) in melanoma, cellular and molecular mechanisms underlying these sex-associated discrepancies are poorly defined. Here, we delineate a previously undisclosed mechanism by which androgen-activated AR transcriptionally upregulates fucosyltransferase 4 (FUT4) expression, which drives melanoma invasiveness by interfering with adherens junctions (AJs). Global phosphoproteomic and fucoproteomic profiling, coupled with in vitro and in vivo functional validation, further reveal that AR-induced FUT4 fucosylates L1 cell adhesion molecule (L1CAM), which is required for FUT4-increased metastatic capacity. Tumor microarray and gene expression analyses demonstrate that AR-FUT4-L1CAM-AJs signaling correlates with pathological staging in melanoma patients. By delineating key androgen-triggered signaling that enhances metastatic aggressiveness, our findings help explain sex-associated clinical outcome disparities and highlight AR/FUT4 and its effectors as potential prognostic biomarkers and therapeutic targets in melanoma.

Brain metastasis-associated fibroblasts secrete fucosylated PVR/CD155 that induces breast cancer invasion.

Brain metastasis cancer-associated fibroblasts (bmCAFs) are emerging as crucial players in the development of breast cancer brain metastasis (BCBM), but our understanding of the underlying molecular mechanisms is limited. In this study, we aim to elucidate the pathological contributions of fucosylation (the post-translational modification of proteins by the dietary sugar L-fucose) to tumor-stromal interactions that drive the development of BCBM. Here, we report that patient-derived bmCAFs secrete high levels of polio virus receptor (PVR), which enhance the invasive capacity of BC cells. Mechanistically, we find that HIF1α transcriptionally upregulates fucosyltransferase 11, which fucosylates PVR, triggering its secretion from bmCAFs. Global phosphoproteomic analysis of BC cells followed by functional verification identifies cell-cell junction and actin cytoskeletal signaling as modulated by bmCAF-secreted, -fucosylated PVR. Our findings delineate a hypoxia- and fucosylation-regulated mechanism by which bmCAFs contribute to the invasiveness of BCBM in the brain.

Conditional depletion of Fus in oligodendrocytes leads to motor hyperactivity and increased myelin deposition associated with Akt and cholesterol activation.

Fused in sarcoma (FUS) is a predominantly nuclear multifunctional RNA/DNA-binding protein that regulates multiple aspects of gene expression. FUS mutations are associated with familial amyotrophic lateral sclerosis (fALS) and frontotemporal lobe degeneration (FTLD) in humans. At the molecular level, the mutated FUS protein is reduced in the nucleus but accumulates in cytoplasmic granules. Oligodendrocytes (OL) carrying clinically relevant FUS mutations contribute to non-cell autonomous motor neuron disease progression, consistent with an extrinsic mechanism of disease mediated by OL. Knocking out FUS globally or in neurons lead to behavioral abnormalities that are similar to those present in FTLD. In this study, we sought to investigate whether an extrinsic mechanism mediated by loss of FUS function in OL contributes to the behavioral phenotype. We have generated a novel conditional knockout (cKO) in which Fus is selectively depleted in OL (FusOL cKO). The FusOL cKO mice show increased novelty-induced motor activity and enhanced exploratory behavior, which are reminiscent of some manifestations of FTLD. The phenotypes are associated with greater myelin thickness, higher number of myelinated small diameter axons without an increase in the number of mature OL. The expression of the rate-limiting enzyme of cholesterol biosynthesis (HMGCR) is increased in white matter tracts of the FusOL cKO and results in higher cholesterol content. In addition, phosphorylation of Akt, an important regulator of myelination is increased in the FusOL cKO. Collectively, this work has uncovered a novel role of oligodendrocytic Fus in regulating myelin deposition through activation of Akt and cholesterol biosynthesis.

Cuprizone-induced oligodendrocyte loss and demyelination impairs recording performance of chronically implanted neural interfaces.

Biological inflammation induced during penetrating cortical injury can disrupt functional neuronal and glial activity within the cortex, resulting in potential recording failure of chronically implanted neural interfaces. Oligodendrocytes provide critical support for neuronal health and function through direct contact with neuronal soma and axons within the cortex. Given their fundamental role to regulate neuronal activity via myelin, coupled with their heightened vulnerability to metabolic brain injury due to high energetic demands, oligodendrocytes are hypothesized as a possible source of biological failure in declining recording performances of intracortical microelectrode devices. To determine the extent of their contribution to neuronal activity and function, a cuprizone-inducible model of oligodendrocyte depletion and demyelination in mice was performed prior to microelectrode implantation. At 5 weeks of cuprizone exposure, mice demonstrated significantly reduced cortical oligodendrocyte density and myelin expression. Mice were then implanted with functional recording microelectrodes in the visual cortex and neuronal activity was evaluated up to 7 weeks alongside continued cuprizone administration. Cuprizone-induced oligodendrocyte loss and demyelination was associated with significantly reduced recording performances at the onset of implantation, which remained relatively stable over time. In contast, recording performances for mice on a normal diet were intially elevated before decreasing over time to the recording level of tcuprizone-treated mice. Further electrophysiological analysis revealed deficits in multi-unit firing rates, frequency-dependent disruptions in neuronal oscillations, and altered laminar communication within the cortex of cuprizone-treated mice. Post-mortem immunohistochemistry revealed robust depletion of oligodendrocytes around implanted microelectrode arrays alongside comparable neuronal densities to control mice, suggesting that oligodendrocyte loss was a possible contributor to chronically impaired device performances. This study highlights potentially significant contributions from the oligodendrocyte lineage population concerning the biological integration and long-term functional performance of neural interfacing technology.

Using Interdisciplinary Dress Rehearsal Events to Ensure Staff Readiness When Opening a New Healthcare Facility.

OBJECTIVE: This nonresearch article describes best practices of using the simulation-based Dress Rehearsal method to prepare staff to move into a new hospital or a new space in an existing facility and to ensure the new facility is ready for use. The authors introduce a modified version of the interactive sociotechnical analysis (ISTA) model to serve as the academic foundation for the Dress Rehearsal concept. BACKGROUND: Healthcare organizations that build new medical facilities must ensure the space is ready to use and that all staff, who will deliver and support patient care, are sufficiently trained. Currently, no standardized approach exists to prepare staff on an interdisciplinary level, to work in their new environment. There are multiple articles highlighting a single hospital or department using simulations before opening, but there is a lack of literature from an aggregate perspective. METHOD: The Dress Rehearsal method is examined by drawing from the author's combined experience of conducting and evaluating hundreds of Dress Rehearsals across North America. Best practices to plan, prepare, and execute events will be reviewed. RESULTS: Evaluations collected after each event present a positive impact related to staff feeling prepared to provide safe care in the new environment, with increased satisfaction after subsequent Dress Rehearsals. CONCLUSIONS: A standardized approach to ensure staff feel confident and safe to move into their new healthcare environment should be a top priority for healthcare leadership. The Dress Rehearsal method is a substantive strategy that supports building and staff readiness for opening day and beyond.

Improving Latino Health Equity Through Spanish Language Interpreter Advocacy in Kansas.

INTRODUCTION: Federal law requires any agency receiving federal aid to take "reasonable steps" to provide meaningful access to qualified limited English proficient (LEP) individuals. However, policies for the provision of language access services, including medical interpretation, vary substantially by state. The Latino population and the number of LEP individuals in the U.S. state of Kansas have grown substantially over the past 20 years, necessitating increased attention to the state's language access policies. METHOD: Though a review of previous research, we present health disparities affecting Latinos in Kansas, examine the state's language access policies for health care, and argue that health disparities could be reduced through improved language access. FINDINGS: While Kansas reimburses health care entities for interpreter services associated with Medicaid, the state has no health care interpreter competency requirements. As a result, LEP persons, primarily Spanish speakers, may be left to navigate through complex hospital systems with inadequate guidance in their language and may be at an increased risk for medical errors due to language barriers. CONCLUSION: We suggest changes that could be implemented to improve access and reduce health disparities affecting Latinos in Kansas and across the United States, and we describe work that is currently underway to support these changes.