Mark A. Sellmyer

Chemical control of protein stability and function in living mice

Conditional control of protein function in vivo offers great potential for deconvoluting the roles of individual proteins in complicated systems. We recently developed a method in which a small protein domain, termed a destabilizing domain, confers instability to fusion protein partners in cultured cells. Instability is reversed when a cell-permeable small molecule binds this domain. Here we describe the use of this system to regulate protein function in living mammals. We show regulation of secreted proteins and their biological activity with conditional secretion of an immunomodulatory cytokine, resulting in tumor burden reduction in mouse models. Additionally, we use this approach to control the function of a specific protein after systemic delivery of the gene that encodes it to a tumor, suggesting uses for enhancing the specificity and efficacy of targeted gene-based therapies. This method represents a new strategy to regulate protein function in living organisms with a high level of control.

Physiologic, Histologic, and Imaging Features of Retained Products of Conception

Retained products of conception (RPOC) are a common and treatable complication after delivery or termination of pregnancy. The pathologic diagnosis of RPOC is made based on the presence of chorionic villi, which indicates persistent placental or trophoblastic tissue. In the setting of postpartum hemorrhage, however, distinguishing RPOC from bleeding related to normal postpartum lochia or uterine atony can be clinically challenging. Ultrasonographic (US) evaluation can be particularly helpful in these patients, and a thickened endometrial echo complex (EEC) or a discrete mass in the uterine cavity is a helpful gray-scale US finding that suggests RPOC. However, gray-scale US findings alone are inadequate for accurate diagnosis. Detection of vascularity in a thickened EEC or an endometrial mass at color or power Doppler US increases the positive predictive value for the diagnosis of RPOC. Computed tomography or magnetic resonance imaging may be helpful when US findings are equivocal and typically demonstrates an enhancing intracavitary mass in patients with RPOC. Diagnostic pitfalls are rare but may include highly vascular RPOC, which can be mistaken for a uterine arteriovenous malformation; true arteriovenous malformations of the uterus; invasive moles; blood clot; and subinvolution of the placental implantation site.

Chemical Control of FGF-2 Release for Promoting Calvarial Healing with Adipose Stem Cells

Chemical control of protein secretion using a small molecule approach provides a powerful tool to optimize tissue engineering strategies by regulating the spatial and temporal dimensions that are exposed to a specific protein. We placed fibroblast growth factor 2 (FGF-2) under conditional control of a small molecule and demonstrated greater than 50-fold regulation of FGF-2 release as well as tunability, reversibility, and functionality in vitro. We then applied conditional control of FGF-2 secretion to a cell-based, skeletal tissue engineering construct consisting of adipose stem cells (ASCs) on a biomimetic scaffold to promote bone formation in a murine critical-sized calvarial defect model. ASCs are an easily harvested and abundant source of postnatal multipotent cells and have previously been demonstrated to regenerate bone in critical-sized defects. These results suggest that chemically controlled FGF-2 secretion can significantly increase bone formation by ASCs in vivo. This study represents a novel approach toward refining protein delivery for tissue engineering applications.

Visualizing cellular interactions with a generalized proximity reporter

Interactions among neighboring cells underpin many physiological processes ranging from early development to immune responses. When these interactions do not function properly, numerous pathologies, including infection and cancer, can result. Molecular imaging technologies, especially optical imaging, are uniquely suited to illuminate complex cellular interactions within the context of living tissues in the body. However, no tools yet exist that allow the detection of microscopic events, such as two cells coming into close proximity, on a global, whole-animal scale. We report here a broadly applicable, longitudinal strategy for probing interactions among cells in living subjects. This approach relies on the generation of bioluminescent light when two distinct cell populations come into close proximity, with the intensity of the optical signal correlating with relative cellular location. We demonstrate the ability of this reporter strategy to gauge cell–cell proximity in culture models in vitro and then evaluate this approach for imaging tumor–immune cell interactions using a murine breast cancer model. In these studies, our imaging strategy enabled the facile visualization of features that are otherwise difficult to observe with conventional imaging techniques, including detection of micrometastatic lesions and potential sites of tumor immunosurveillance. This proximity reporter will facilitate probing of numerous types of cell–cell interactions and will stimulate the development of similar techniques to detect rare events and pathological processes in live animals.

Intracellular Context Affects Levels of a Chemically Dependent Destabilizing Domain

The ability to regulate protein levels in live cells is crucial to understanding protein function. In the interest of advancing the tool set for protein perturbation, we developed a protein destabilizing domain (DD) that can confer its instability to a fused protein of interest. This destabilization and consequent degradation can be rescued in a reversible and dose-dependent manner with the addition of a small molecule that is specific for the DD, Shield-1. Proteins encounter different local protein quality control (QC) machinery when targeted to cellular compartments such as the mitochondrial matrix or endoplasmic reticulum (ER). These varied environments could have profound effects on the levels and regulation of the cytoplasmically derived DD. Here we show that DD fusions in the cytoplasm or nucleus can be efficiently degraded in mammalian cells; however, targeting fusions to the mitochondrial matrix or ER lumen leads to accumulation even in the absence of Shield-1. Additionally, we characterize the behavior of the DD with perturbants that modulate protein production, degradation, and local protein QC machinery. Chemical induction of the unfolded protein response in the ER results in decreased levels of an ER-targeted DD indicating the sensitivity of the DD to the degradation environment. These data reinforce that DD is an effective tool for protein perturbation, show that the local QC machinery affects levels of the DD, and suggest that the DD may be a useful probe for monitoring protein quality control machinery.

A General Method for Conditional Regulation of Protein Stability in Living Animals

The ability to rapidly and reversibly perturb protein levels in living animals is a powerful tool for researchersto determine protein function in complex systems. We recently designed a small protein domain based onthe 12-kDa FKBP (FK506 binding protein) that can be fused at either the carboxyl or amino terminus of aprotein of interest. This destabilization domain (DD) confers instability to fusion protein partners, allowingtargeted degradation of the protein of interest. A small molecule called Shield-1 binds to the DD and protectsthe fusion protein from degradation. Small-molecule-mediated post-translational regulation of proteinstability affords this system rapid, reversible, and tunable control of protein levels and functions in a varietyof model systems. Theoretically, a number of transgene delivery methods (e.g., viral, liposomal, or stem cell)can be used for the analysis of a DD fusion protein in an animal model. This protocol uses tumor xenograftsin mice as one such mechanism for delivering the fusion protein and presents a method for deliveringShield-1 to regulate the fusion proteins in vivo.

Bacterial infection imaging with [18F]fluoropropyl-trimethoprim

Significance The ability to distinguish bacterial infection from other pathologies in humans can be challenging. An imaging agent with great sensitivity and spatial resolution that would allow noninvasive identification of sites of bacterial infection could increase our understanding of the natural history of bacterial infection in patients and potentially be used to support clinical decision making. Here, we report the first synthesis of a fluorine-18–labeled derivative of the antibiotic trimethoprim for positron emission tomography imaging and show that it can identify bacterial infection in rodents. Importantly, this radiotracer does not accumulate at sites of sterile inflammation or cancer, pathologies that often have overlapping imaging features with bacterial infection. There is often overlap in the diagnostic features of common pathologic processes such as infection, sterile inflammation, and cancer both clinically and using conventional imaging techniques. Here, we report the development of a positron emission tomography probe for live bacterial infection based on the small-molecule antibiotic trimethoprim (TMP). [18F]fluoropropyl-trimethoprim, or [18F]FPTMP, shows a greater than 100-fold increased uptake in vitro in live bacteria (Staphylococcus aureus, Escherichia coli, and Pseudomonas aeruginosa) relative to controls. In a rodent myositis model, [18F]FPTMP identified live bacterial infection without demonstrating confounding increased signal in the same animal from other etiologies including chemical inflammation (turpentine) and cancer (breast carcinoma). Additionally, the biodistribution of [18F]FPTMP in a nonhuman primate shows low background in many important tissues that may be sites of infection such as the lungs and soft tissues. These results suggest that [18F]FPTMP could be a broadly useful agent for the sensitive and specific imaging of bacterial infection with strong translational potential.

Inflammation and DNA damage: Probing pathways to cancer and neurodegeneration

Cancer and neurodegeneration represent two opposite ends of the biological spectrum but contain many common biological mechanisms. Two such mechanisms include the elevated levels of oxidative stress and DNA damage. In this brief review, we describe current approaches for imaging these biological pathways with the molecular imaging technique, Positron Emission Tomography (PET), and the potential of PET imaging studies to measure the efficacy of anticancer drugs and strategies for delaying the progression of neurodegenerative disorders.