In this review, we highlight recent discoveries regarding mechanisms contributing to nerve-cancer crosstalk and the effects of nerve-cancer crosstalk on tumor progression and dissemination. High intratumoral nerve density correlates with poor prognosis and high recurrence across multiple solid tumor types. Recent research has shown that cancer cells express neurotrophic markers such as nerve growth factor, brain-derived neurotrophic factor, and glial cell-derived neurotrophic factor and release axon guidance molecules such as Ephrin B1 to promote axonogenesis. Tumor cells recruit new neural progenitors to the tumor milieu and facilitate their maturation into adrenergic infiltrating nerves. Tumors also rewire established nerves to adrenergic phenotypes via exosomeinduced neural reprogramming by p53-deficient tumors. In turn, infiltrating sympathetic nerves facilitate cancer progression. Intratumoral adrenergic nerves release noradrenaline to stimulate angiogenesis via vascular endothelial growth factor signaling and enhance the rate of tumor growth. Intratumoral parasympathetic nerves may have a dichotomous role in cancer progression and may induce Wnt-β-catenin signals that expand cancer stem cells. Importantly, infiltrating nerves not only influence the tumor cells themselves but also impact other cells of the tumor stroma. This leads to enhanced sympathetic signaling and glucocorticoid production, which influences neutrophil and macrophage differentiation, lymphocyte phenotype, and potentially lymphocyte function. Although much remains unexplored within this field, fundamental discoveries underscore the importance of nerve-cancer crosstalk to tumor progression and may provide the foundation for developing effective targets for the inhibition of tumor-induced neurogenesis and tumor progression.
Respiratory chemosensory circuits are implicated in several physiological and behavioral disorders ranging from sudden infant death syndrome to panic disorder. Thus, a comprehensive map of the chemosensory network would be of significant value. To delineate chemosensory neuronal populations, we have utilized pharmacogenetic Designer Receptors Exclusively Activated by Designer Drugs (DREADD) perturbations for acute neuronal perturbations in respiratory circuit mapping. Recent studies show that the biologically inert DREADD ligand clozapine-N-oxide (CNO) is back-metabolized into the bioactive compound clozapine in rodents, emphasizing the need for CNO-only DREADD-free controls, which have been carried out in several studies. However, we show that high CNO doses used in several chemosensory circuit mapping studies nonetheless affect the chemosensory ventilatory reflexes in control mice, which is unmasked by extensive habituation. Here, unhabituated control animals showed no differences in respiratory parameters after CNO administration, whereas habituated animals receiving the commonly used dose of 10 mg/kg of CNO show a deficit in the hypercapnic (high CO 2 ) chemosensory reflex, which is not present in 1 mg/kg CNO treated or saline control groups. Our findings indicate that even in appropriately controlled studies, additional masked CNO off-target effects may exist and underscore the importance of using minimal doses of activating ligand in combination with high levels of habituation.
Background The functional understanding of genetic interaction networks and cellular mechanisms governing health and disease requires the dissection, and multifaceted study, of discrete cell subtypes in developing and adult animal models. Recombinase-driven expression of transgenic effector alleles represents a significant and powerful approach to delineate cell populations for functional, molecular, and anatomical studies. In addition to single recombinase systems, the expression of two recombinases in distinct, but partially overlapping, populations allows for more defined target expression. Although the application of this method is becoming increasingly popular, its experimental implementation has been broadly restricted to manipulations of a limited set of common alleles that are often commercially produced at great expense, with costs and technical challenges associated with production of intersectional mouse lines hindering customized approaches to many researchers. Here, we present a simplified CRISPR toolkit for rapid, inexpensive, and facile intersectional allele production. Results Briefly, we produced 7 intersectional mouse lines using a dual recombinase system, one mouse line with a single recombinase system, and three embryonic stem (ES) cell lines that are designed to study the way functional, molecular, and anatomical features relate to each other in building circuits that underlie physiology and behavior. As a proof-of-principle, we applied three of these lines to different neuronal populations for anatomical mapping and functional in vivo investigation of respiratory control. We also generated a mouse line with a single recombinase-responsive allele that controls the expression of the calcium sensor Twitch-2B. This mouse line was applied globally to study the effects of follicle-stimulating hormone (FSH) and luteinizing hormone (LH) on calcium release in the ovarian follicle. Conclusions The lines presented here are representative examples of outcomes possible with the successful application of our genetic toolkit for the facile development of diverse, modifiable animal models. This toolkit will allow labs to create single or dual recombinase effector lines easily for any cell population or subpopulation of interest when paired with the appropriate Cre and FLP recombinase mouse lines or viral vectors. We have made our tools and derivative intersectional mouse and ES cell lines openly available for non-commercial use through publicly curated repositories for plasmid DNA, ES cells, and transgenic mouse lines.
The goal of this project is to build and distribute a community library of more than 100 mouse intersectional genetic alleles to facilitate the developmental, anatomical, molecular, and functional characterization of neural circuit organization in behavior and physiology based on public input. Even within narrowly defined cell types, significant diversity is found at multiple levels including genetic and molecular signatures, activity patterns, and synaptic connectivity. Current challenges now center on tools to identify, access, and study cell populations with increasing precision. Intersectional genetics offers exceptionally high resolution to consistently delineate distinct cell types in the embryo and adult mouse for functional, molecular and anatomical studies. Intersectional genetics utilizes a ubiquitously expressed conditional allele that is activated by Cre and Flp site specific recombinases. Upon activation, the intersectional genetic alleles may express any number of Genetically Encodable Effector Molecules (GEEMS), such as channelrhodopsins for neural activity perturbations or an L10‐GFP ribotrap fusion to affinity purify translating mRNAs. The intersectional allele is activated by overlapping expression of both Flp and Cre recombinases in the same cell. Traditionally, these recombinases have been deployed as gene knock‐in or transgenic alleles that are designed to express in a cell or gene specific fashion. The use of two selectors (Cre and Flp) to define a cellular population enables high specificity and modularity in combining any set of Cre, Flp and intersectional alleles to fit an experiment. The number of Cre and Flp recombinase mouse lines are constantly growing, giving greater access to increasing numbers of cell types. Additionally, these recombinases are the focus of multiple efforts to deploy them in ways that select cells based on other unique properties such as neuronal activity and synaptic connectivity. To make this powerful genetic approach more accessible to as many research laboratories as possible, we are building a production pipeline to create a suite of resources for anyone to easily make their own intersectional mouse line, to produce over 100 targeted ES cell lines that can be developed into mouse lines, as well as 10–15 high demand mouse lines all for public distribution. Priority for the GEEMS to be intersectionally deployed will be based on a public input collected at mouseintersectionalgenetics.org. All plasmids, cell lines and mouse lines developed under this effort will be distributed without restriction to non‐profit research organizations.Support or Funding InformationMcNair Medical InstituteR01HL130249R01HL130249‐02S1This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.
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