Explore our grantees and awardees

Grant category: Research Grants in open competition

Year: 2024

Geography: USA

Aydogan Ozcan’s project explores a potential alternative to the current diagnostic standard in allergic contact dermatitis (ACD) —patch testing —which has remained largely unchanged since its development over a century ago. It seeks to transform the diagnosis of ACD by developing a novel wearable sensor capable of remote monitoring and early detection. The sensor will be designed to measure changes in the skin’s optical properties, offering a more efficient, convenient, and comfortable alternative to the traditional method of patch testing. Aydogan Ozcan’s project includes the creation of skin phantom models’ representative of diverse skin tones to rigorously test the wearable sensor, followed by a phased human study.

The results of the project could enable more convenient, equitable, and cost-effective diagnosis in ACD, thereby improving patient outcomes. Additionally, this technology holds the potential to be adapted for the monitoring of other skin conditions, representing a significant advancement in the field of dermatology.

Grant category: Research Grants in open competition

Year: 2024

Geography: USA

Maria Teves’ project explores mechanisms behind formation of dermal fibrosis, which is a hallmark of several skin disorders, including systemic sclerosis (SSc). Despite the identification of various contributing factors, the precise molecular mechanisms underlying skin fibrosis in SSc remain poorly understood and there is no effective treatment. In order to uncover these mechanisms and develop new therapeutic strategies, the project focuses on primary cilia (PC), which are specialized solitary cellular organelles involved in molecular signaling. Recently, Maria Teves and her research group discovered links between altered PC to SSc pathophysiology, revealing significant alterations in PC and PC-associated gene expression in skin biopsies from SSc patients. Furthermore, it was found that profibrotic signaling can be triggered both in vivo and in vitro by the genetic ablation of PC-associated genes or by pharmacological agents that damage PC. Building on this critical evidence, the project will test the hypothesis that PC represent novel therapeutic targets for SSc skin fibrosis. A comprehensive approach is proposed to define molecular contributions of PC to the pathogenesis of skin fibrosis and assess the potential of PC-targeted therapies for mitigating fibrotic phenotypes.

Maria Teves’ experiments may lay the groundwork for advanced understanding and possibly treatment and future clinical advances for people suffering from fibrotic skin conditions.

Grant category: Research Grants in open competition

Year: 2024

Geography: USA

Anand Ganesan’s project explores the activation of the innate immune system in rosacea, a chronic skin condition which affects 5% of the world’s population. Rosacea skin has an increased number of blood vessels, which can be induced by the naturally occurring anti-microbial peptide cathelicidin, which is produced by keratinocytes in rosacea skin. While treatment targets and new pharmacotherapies for rosacea have been identified, this knowledge has not yet been translated into new rosacea therapies. RhoJ, a member of the CDC42 GTPase family, plays a critical role in angiogenesis (formation of new blood vessels) in skin and other organs, and RhoJ knockout mice have decreased number of blood vessels in the skin as compared to wild type animals. Anand Ganesan and the research group has discovered a new class of small molecules that inhibit CDC42 GTPase signaling, which prevents vessel accumulation in the skin and colon through a RhoJ-dependent mechanism and also blocks the vascularization of human organoids. Anand Ganesan’s project couples’ single cell and spatial transcriptomics approaches (i.e., analyses of how genes are expressed in individual cells as well as throughout a tissue) with advanced bioinformatics to identify vessel inducing signals in tissue. The research plan includes 1) coupling single cell and spatial transcriptomics with advanced bioinformatics to identify rosacea inducing signals; 2) quantifying vascular changes in rosacea in mice and human model systems; and 3) testing the efficacy of CDC42 inhibitors at blocking cathelicidin-induced angiogenesis.

The project aims to identify new drug targets and test the efficacy of new treatments for rosacea.

Grant category: Research Grants in open competition

Year: 2024

Geography: USA

Tamia Harris-Tryon’s study explores atopic dermatitis (AD) which affects seven percent of adults and twenty percent of children. AD has the highest impact on patient quality of life among skin disorders. The pathogenesis of AD is incompletely understood, and there is an increasing appreciation for the contributions of the microbiome. During AD flares, Staphylococcus aureus expands and exacerbates inflammatory responses and skin damage. While S. aureus dominates the skin microbiome in AD, the mechanisms that drive bacterial expansion during inflammation remain unclear. This question is important because skin breakdown in AD is aggravated by S. aureus toxins. S. aureus exotoxins have been shown to stimulate skin inflammation. Tamia Harris-Tryon’s project will test the central hypothesis that testosterone promotes S. aureus-induced skin damage and inflammation in AD as well as investigate how testosterone stimulates S. aureus-induced skin damage in culture and in mouse models. These experiments will also make use of genetically engineered mice with reduced testosterone production in the skin. This approach will reliably determine how testosterone regulates S. aureus-induced skin damage and inflammation.

The results of Tamia Harris-Tryon’s project may reliably determine how testosterone regulates S. aureus-induced skin damage and inflammation.

Grant category: Research Grants in open competition

Year: 2024

Geography: USA

Andrzej Dlugosz’s project explores how a skin-associated virus called TSPyV can cause a striking hair follicle disorder called trichodysplasia spinulosa. In patients affected by this condition hair follicles on the face and ears are enlarged, structurally abnormal, filled with TSPyV viral particles, and produce spikes instead of hairs. To understand how TSPyV disrupts hair follicle biology Andrzej Dlugosz and his group created genetically engineered mice that express TSPyV viral proteins in skin. These mice produced enlarged and abnormal-appearing follicles and developed follicle-like structures in hairless areas, suggesting that TSPyV can somehow reprogram skin to drive growth of hair follicles which are needed for large-scale virus production. In keeping with this concept, one of the TSPyV viral proteins triggers abnormal activation of an important molecular signal that regulates formation and maturation of hair follicles. The studies will examine hair follicles in trichodysplasia spinulosa using powerful new molecular technologies to better understand the alterations in behavior and maturation of follicle cell types in this disease. They will also investigate how a specific TSPyV protein hijacks an important hair follicle signaling pathway, contributing to the profound changes seen in the skin of trichodysplasia spinulosa patients.

The results of the project have the potential to yield new insights into the regulation of molecular signals controlling formation and growth of hair follicles, based on findings from studying this rare condition.

Grant category: Research Grants in open competition

Year: 2024

Geography: USA

Beth McLellan’s project, in collaboration with co-PI and Kosaku Shinoda, explores the functional interactions of live or viable bacteria within the skin microbial community, and their implications in skin disease. The project aims to develop a robust ex vivo model, Skin Microbiome in a Test tube (SMT), to study the dynamic biochemical activity of the viable skin microbiome. Preliminary data indicate that the prototype version of the SMT system (v1) is capable of preserving the diversity of skin bacteria ex vivo. The aims are to (1) refine SMT using Propidium Monoazide (PMA) sequencing to exclusively replicate the viable microbiome and (2) investigate the impact of skin microenvironmental factors (e.g., moisture, sebum levels, and skin breakdown) on the composition and biochemical activity of the viable microbiome, using data from non-invasive sensors at multiple skin sites.

With the generation of the improved version of the SMT (v2), the project hopes to create an innovative platform for functional skin microbiome studies, drug screening and pharmacokinetic modeling with an emphasis on microbial viability leading to individualized treatment strategies based on microbiome community profiles. SMT will serve as a foundation for identifying biomarkers, developing microbiome-based therapies, and improving pharmacokinetic predictions.

Grant category: Research Grants in open competition

Year: 2024

Geography: USA

Erin Chen’s project aims to address the fundamental question: how do we translate the composition of our body’s colonizing microbes (our microbiome) into insight about immune function? Commensal bacteria (commonly known as just “commensals”) colonize our skin, over our entire lives, and generate the vast majority of microbe-host encounters, with largely unknown consequences. Erin Chen’s project focuses on commensals’ interactions with T cells because these cells critically impact many aspects of health and disease. Unlike infections, where a single pathogen invades into the tissue, commensals colonize within complex communities and communicate to the host immune system across an intact skin barrier. How the immune system decodes signals from each member of this community is unknown. Erin Chen and her team will address this by colonizing mice with defined communities of commensals and tracking the commensal-derived antigens along with the strain-specific T cells. To do this, they will develop novel methods to detect commensal-derived antigens within the host tissue, at high resolution. By varying the abundance and composition of community members, they aim to discover novel antagonistic, synergistic, and emergent properties of commensal-specific T cells. This work will provide visibility into a currently invisible process: how a lifetime of commensals on our skin are constantly sculpting our T cell function, which ultimately impacts our susceptibility to infections, autoimmunity, and cancer.

Grant category: Research Grants in open competition

Year: 2024

Geography: USA

Xiaoyang Wu’s project aims to engineer self-amplifying RNA vector as a platform for gene therapy of recessive X-linked ichthyosis, with potential for treatment of other skin diseases.

Skin ichthyoses are a group of heterogeneous genetic diseases that are characterized by hyperkeratosis, localized or generalized scaling, and often associated with xerosis, hypohidrosis, erythroderma, and recurrent infections. So far, mutations in more than 50 genes have been shown to cause ichthyosis, which affect a variety of different cellular processes, ranging from DNA repair, lipid biosynthesis, cell adhesion, and skin differentiation. Recessive X-linked ichthyosis (RXLI) is the second most common form of inherited ichthyosis. RXLI is caused by mutations in the STS gene on the X chromosome, which encodes microsomal steroid sulfatase. The skin abnormalities of RXLI are caused by the impact of excess cholesterol sulfate, which affects lipid synthesis, organization of the lamellar lipids that provides the skin permeability barrier, corneodesmosome proteolysis, and epidermal differentiation.

As a genetic disorder, RXLI is a life-long condition that can significantly affect domestic life and cause psychological problems for the patients. More effective treatment beyond current symptomatic management is urgently needed. Xiaoyang Wu’s project will explore the possibility that engineered self-amplifying RNA vector can serve as a novel platform for gene therapy of RXLI.

Xiaoyang Wu’s project may serve as proof-of-concept for a novel paradigm for the treatment of patients with genetic skin disorders.

Grant category: Research Grants in open competition

Year: 2024

Geography: USA

Jeffrey Rasmussen’s project investigates the mechanisms governing Langerhans cells’ immune response in wound healing, particularly the role of the microtubule cytoskeleton.

Skin provides a robust and durable physical barrier essential for regulating hydration and repelling pathogens. Damage to skin must be rapidly resolved to maintain organ homeostasis. Epidermal-resident immune cells known as Langerhans cells use dendritic protrusions to dynamically surveil the skin microenvironment, which contains epithelial keratinocytes and somatosensory peripheral axons.

The mechanisms governing Langerhans cell dendrite dynamics and responses to tissue damage are not well understood. Jeffrey Rasmussen and his lab have developed a tractable system using adult zebrafish to study Langerhans cell dynamics. Initial studies using this system revealed several new discoveries, including: 1) that Langerhans cells are the primary phagocyte for degenerating somatosensory axons; 2) Langerhans cells undergo stereotyped responses to local and tissue-scale keratinocyte wounds; and 3) the actin regulator ROCK regulates key aspects of Langerhans cell wound responses. Despite advances in identifying mechanisms of actin function in Langerhans cells, roles for the microtubule cytoskeleton in Langerhans cell biology remain essentially unknown. In preliminary studies, Jeffrey Rasmussen has developed a novel transgenic reporter for microtubules in Langerhans cells and found that the microtubule cytoskeleton dynamically reorganizes during wound responses. His project aims to determine how the microtubule cytoskeleton contributes to the intracellular trafficking and dynamic wound responses of Langerhans cells.

The results of Jeffrey Rasmussen’s project could lead to new fundamental understandings of Langerhans cell biology and dynamics.

Grant category: Research Grants in open competition

Year: 2024

Geography: USA

Wei Tao’s project explores the biological mechanisms to improve wound healing in adults by mimicking the scarless fetal wound healing process. This project aims to engineer a system that replicates the fetal extracellular matrix and immune responses, using mRNA techniques to produce specific proteins and inhibit biological processes leading to scar formation. This system employs lipid nanoparticles for mRNA delivery and hydrogel for controlled release, enabling spatiotemporal control of key components like collagen type III and interleukin-10, thereby reconstituting fetal-like extracellular matrix organization and modulating over-activated immune responses.

The project’s goals include establishing a foundation for future scarless wound healing studies, developing a hybrid mRNA therapeutic platform for skin defects and diseases, and correlating extracellular matrix and immune modulation with subsequent biological processes and outcomes. This research has promising potential for clinical applications in wound care and other dermatological diseases.