The role of macrophages in skin homeostasis.

The skin and its appendages comprise the largest and fastest growing organ in the body. It performs multiple tasks and maintains homeostatic control, including the regulation of body temperature and protection from desiccation and from pathogen invasion. The skin can perform its functions with the assistance of different immune cell populations. Monocyte-derived cells are imperative for the completion of these tasks. The comprehensive role of macrophages and Langerhans cells in establishing and maintaining skin homeostasis remains incompletely defined. However, over the past decade, innovations in mouse genetics have allowed for advancements in the field. In this review, we explore different homeostatic roles of macrophages and Langerhans cells, including wound repair, follicle regeneration, salt balance, and cancer regression and progression in the skin. The understanding of the precise functions of myeloid-derived cells in the skin under basal conditions can help develop specific therapies that aid in skin and hair follicle regeneration and cutaneous cancer prevention.

Early-Life Stress Perturbs Key Cellular Programs in the Developing Mouse Hippocampus.

Conflicting reports are available with regard to the effects of childhood abuse and neglect on hippocampal function in children. While earlier imaging studies and some animal work have suggested that the effects of early-life stress (ELS) manifest only in adulthood, more recent studies have documented impaired hippocampal function in maltreated children and adolescents. Additional work using animal modes is needed to clarify the effects of ELS on hippocampal development. In this regard, genomic, proteomic, and molecular tools uniquely available in the mouse make it a particularly attractive model system to study this issue. However, very little work has been done so far to characterize the effects of ELS on hippocampal development in the mouse. To address this issue, we examined the effects of brief daily separation (BDS), a mouse model of ELS that impairs hippocampal-dependent memory in adulthood, on hippocampal development in 28-day-old juvenile mice. This age was chosen because it corresponds to the developmental period in which human imaging studies have revealed abnormal hippocampal development in maltreated children. Exposure to BDS caused a significant decrease in the total protein content of synaptosomes harvested from the hippocampus of 28-day-old male and female mice, suggesting that BDS impairs normal synaptic development in the juvenile hippocampus. Using a novel liquid chromatography multiple reaction monitoring mass spectrometry (LC-MRM) assay, we found decreased expression of many synaptic proteins, as well as proteins involved in axonal growth, myelination, and mitochondrial activity. Golgi staining in 28-day-old BDS mice showed an increase in the number of immature and abnormally shaped spines and a decrease in the number of mature spines in CA1 neurons, consistent with defects in synaptic maturation and synaptic pruning at this age. In 14-day-old pups, BDS deceased the expression of proteins involved in axonal growth and myelination, but did not affect the total protein content of synaptosomes harvested from the hippocampus, or protein levels of other synaptic markers. These results add two important findings to previous work in the field. First, our findings demonstrate that in 28-day-old juvenile mice, BDS impairs synaptic maturation and reduces the expression of proteins that are necessary for axonal growth, myelination, and mitochondrial function. Second, the results suggest a sequential model in which BDS impairs normal axonal growth and myelination before it disrupts synaptic maturation in the juvenile hippocampus.

Human keratinocyte carcinomas have distinct differences in their tumor-associated macrophages.

Cutaneous squamous cell carcinomas (SCCs) and basal cell carcinomas (BCCs) have different clinical behaviors, despite both being keratinocyte carcinomas mainly caused by ultraviolet radiation. Whether these distinct features are associated with tumor-associated macrophages (TAMs) is largely unknown. The main goal of this study was to conduct a comprehensive analysis of density and polarization states of TAMs in SCCs versus BCCs. The role of lactic acid in TAM polarization in SCC versus BCC was examined. We found that SCCs have a higher density of CD68 + TAMs compared to BCCs. TAMs in SCCs express higher levels of TAM-associated markers (arginase-1, MMP9, CD40 and CD127) than those in BCCs. Interestingly, differential expression of TAM-associated markers between SCCs and BCCs was reproduced in human monocytic THP-1 cells stimulated with SCC- or BCC-conditioned media. Analysis of soluble factor(s) in these tumors further revealed that SCCs have a significantly higher concentration of lactic acid than BCCs, and lactic acid was sufficient to upregulate TAM markers. Our results demonstrate that TAMs in SCCs versus BCCs differ in density and polarization states, which can be determined by soluble factors including tumor-derived lactic acid. These differences in TAMs may contribute to the distinct clinical behaviors of SCCs versus BCCs. This work was supported by grants from the National Institutes of Health and the Doris Duke Charitable Foundation. RESEARCH IN CONTEXT: Few studies have studied tumor-associated macrophages in the context of SCC versus BCC. It has been demonstrated that macrophages mobilize to the epidermis after being exposed to ultraviolet-B radiation and produce interleukin-10 (IL-10). It has also been shown that the production of IL-10 results in the evasion of T cell-mediated immunity in BCCs and SCCs. However, the relationship between TAMs and the clinical behaviors of SCCs and BCCs remains largely unclear. Our study shows that despite their similar origins, human cutaneous SCCs and BCCs are considerably different in their TAMs. To our knowledge, these results provide the first evidence of differential TAM density and polarization in SCCs versus BCCs, which may contribute to their characteristic clinical behaviors. Future studies are necessary to elucidate the mechanisms by which TAMs influence these cancers with the goal of developing therapies tailored to each type of malignancy.