IL-27 Facilitates Skin Wound Healing through Induction of Epidermal Proliferation and Host Defense.
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2017-05
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Skin wound repair requires a coordinated program of epithelial cell proliferation and differentiation as well as resistance to invading microbes. However, the factors that trigger epithelial cell proliferation in this inflammatory process are incompletely understood. In this study, we demonstrate that IL-27 is rapidly and transiently produced by CD301b+ cells in the skin after injury. The functional role of IL-27 and CD301b+ cells is demonstrated by the finding that CD301b-depleted mice exhibit delayed wound closure in vivo, which could be rescued by topical IL-27 treatment. Furthermore, genetic ablation of the IL-27 receptor (Il27Ra-/-) attenuates wound healing, suggesting an essential role for IL-27 signaling in skin regeneration in vivo. Mechanistically, IL-27 feeds back on keratinocytes to stimulate cell proliferation and re-epithelialization in the skin, whereas IL-27 leads to suppression of keratinocyte terminal differentiation. Finally, we identify that IL-27 potently increases expression of the antiviral oligoadenylate synthetase 2, but does not affect expression of antibacterial human beta defensin 2 or regenerating islet-derived protein 3-alpha. Together, our data suggest a previously unrecognized role for IL-27 in regulating epithelial cell proliferation and antiviral host defense during the normal wound healing response.
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Scholars@Duke

Soman Ninan Abraham
The Abraham laboratory is interested in developing innovative approaches for curbing microbial infections through the study of the molecular interactions occurring between pathogenic bacteria and prominent immune and epithelial cells. We believe that there is a significant amount of crosstalk occurring between bacteria and host cells during infection and that the outcome of this interaction dictates both how quickly the infection is cleared and the severity of the pathology associated with the infection. We also believe that through deciphering this crosstalk we should be able to selectively promote certain beneficial interactions while abrogating the harmful ones.
There are two major research areas being pursued in this laboratory. The first involves elucidating the role of mast cells in modulating immune responses to microbes. Our studies have revealed that mast cells play a key sentinel role and upon bacterial or viral infection, modulate both innate and adaptive immune responses through the release of immunomodulatory molecules borne in granules. Our current investigations are centered on elucidating the molecular and cellular aspects of how mast cells mediate their immunomodulatory role. We are also examining several mast cell-targeted strategies to boost immunity to infections as well as reduce any pathological consequences of infection.
The second area of research investigates cross-talk between distinct infectious agents such as Uropathogenic E. coli, Salmonella typhimurium and Yersinia pestis and the immune system. We have recognized that different pathogens possess distinct mechanisms to evade or coopt one or more immune cells to establish infection. We have also unraveled novel intracellular innate host defense activities including expulsion of whole bacteria from infected epithelial cells, a feat mediated by immune recognition molecules and the cellular trafficking system.
Cumulatively, our studies should facilitate the design of innovative strategies to combat pathogens that selectively potentiate the host’s immune response without evoking some of its harmful side effects.

Amanda S MacLeod
The MacLeod Lab investigates the dynamic regulation of innate immunity, with specific focus on host-microbial interactions, antimicrobial host defense, antiviral proteins, and repair functions.
Skin is an active immune organ and comprises not only epithelial keratinocytes, but also harbors dendritic cells, macrophages, nerve cells, and other immune cells. Furthermore, the skin is inhabited by a multitude of microbes, including bacteria, viruses and fungi and even parasites. The healthy and controlled immune interactions of the skin barrier cells with microbes and environmental factors are critical to maintain homeostasis and to prevent overt immune responses resulting in disease. The dynamic regulation of innate host defense factors allows for critical protection against microbial pathogens in situations of barrier defects and injury.
We use interdisciplinary approaches, combining various disease mouse models, human skin tissues and cells, and techniques from immunology, stem cell biology, microbiology and pharmacology to ultimately reveal strategies that coordinate, regulate or co-opt innate immunity in the skin. This allows us to identify mechanisms that fundamentally control skin immunity and will help in the development of new immune-modulatory therapeutics and a better understanding of health and disease.
We study the interplay of innate immune cells with microbial and additional environmental factors. Our interest is to decipher the mechanisms that facilitate antimicrobial immune surveillance and repair functions in the skin under homeostatic and challenged conditions.
I. Innate immune regulation and modulation during skin injury and microbial infection
Damage to the skin through physical injury and microbes initiates release of multiple pro-inflammatory cytokines and mediators including IL-27, IL-17, extracellular ATP, nucleic acids, NO, as well as antimicrobial peptides and proteins. Upon skin injury, inflammatory immune responses are aimed at clearing microbial contamination before a repair program can subsequently facilitate wound closure. However, prolonged inflammation is detrimental and mediates tissue damage and is considered a major pathogenic factor for the development of chronic non-healing wounds and may be a trigger for auto-inflammatory skin diseases such as psoriasis. The focus of our laboratory is on identifying and characterizing such key factors that regulate innate immunity in the skin. Fine regulation of the cutaneous innate immune response is critical to maintain skin barrier function and protection upon injury and infection. Our studies on innate antimicrobial peptides and proteins (AMPs), including antiviral proteins, have fundamentally advanced our knowledge of how the innate immune system works in the skin. We further aim to understand the dynamic regulation of innate antimicrobial host immunity during aging and in early life, in response to diverse microbial stimuli, and in various complex dermatological diseases, including eczema, psoriasis, hidradenitis suppurativa, wounds etc. Decoding the microbial-epithelial-immune dialogue in the skin may offer insights into novel strategies of treatment.
II. Role of IL-27 in cutaneous immunity
IL-27, a member of the IL-12 family of heterodimeric cytokines, consists of p28 and Epstein-Barr virus gene 3 (EBI3) and signals through its receptor composed of IL-27RA and gp130. Previous studies indicated that IL-27 can play pro-inflammatory and anti-inflammatory roles depending on the cell type and context. In the context of infectious inflammation, a recent study reported that IL-27 is produced by CD103+ dermal dendritic cells (DC) in the skin , whereas other studies identified that IL-27 is produced by mesenteric lymph node CD103- DC, splenic CD4+ DC and macrophages. Our work identified IL-27 production in dermal CD301b+ monocyte-derived DC following injury. Here, IL-27 promotes the wound healing response by promoting keratinocyte proliferation. Furthermore, we have identified multiple new and unprecedented roles for IL-27 in cutaneous immunity in response to contact allergens, microbes and in psoriasis. Our lab recently described and published that IL-27 signaling provides a novel path of antiviral protein activation in the skin and that IL-27 signaling is critical in activating host defenses against cutaneous Zika virus infections.
III. Antiviral Proteins
A large part of our laboratory's efforts are focused to better understanding the constitutive and inducible antiviral proteins and their mode of regulation in the skin. Antiviral proteins comprise Oligoadenylate Synthases (OAS), Protein Kinase R (PKR), Interferon-stimulated Gene (ISG) 15 and 20, and multiple Interferon Induced proteins with Tetratricopeptide repeats (IFIT) and Interferon-induced transmembrane proteins (IFITM) and others. Antiviral proteins provide a natural defense mechanism against viruses. Their expression and regulation in the skin are still poorly understood and our lab is providing some new and exciting insights into cutaneous innate antiviral immunity and the regulation of expression of antiviral proteins.
Complete List of Published Work can be found here:
http://www.ncbi.nlm.nih.gov/myncbi/browse/collection/47851812/?sort=date&direction=descending
Her maiden name Büchau was used prior to MacLeod.
Our lab website can be found here: https://sites.duke.edu/macleodlab/
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