Tissue inhibitors of metalloproteinases (TIMPs) are a conserved family of proteins that were originally identified as endogenous inhibitors of matrixin and adamalysin endopeptidase activity. The matrixins and adamalysins are the major mediators of extracellular matrix turnover, thus making TIMPs important regulators of ECM structure and composition. Despite their high sequence identity and relative redundancy in inhibitory profiles, each TIMP possesses unique biological characteristics that are independent of their regulation of metalloproteinase activity. As our understanding of TIMP biology has evolved, distinct roles have been assigned to individual TIMPs in cancer progression. In this respect, data regarding TIMP2’s role in cancer have borne conflicting reports of both tumor suppressor and, to a lesser extent, tumor promoter functions. TIMP2 is the most abundant TIMP family member, prevalent in normal and diseased mammalian tissues as a constitutively expressed protein. Despite its apparent stable expression, recent work highlights how TIMP2 is a cell stress-induced gene product and that its biological activity can be dictated by extracellular post-translational modifications. Hence an understanding of TIMP2 molecular targets, and how its biological functions evolve in the progressing tumor microenvironment may reveal new therapeutic opportunities. In this review, we discuss the continually evolving functions of TIMP proteins, future perspectives in TIMP research, and the therapeutic utility of this family, with a particular focus on TIMP2.
Tissue inhibitor of metalloproteinases (TIMPs/Timps) are an endogenous family of widely expressed matrisome-associated proteins that were initially identified as inhibitors of matrix metalloproteinase activity (Metzincin family proteases). Consequently, TIMPs are often considered simply as protease inhibitors by many investigators. However, an evolving list of new metalloproteinase-independent functions for TIMP family members suggests that this concept is outdated. These novel TIMP functions include direct agonism/antagonism of multiple transmembrane receptors, as well as interactions with matrisome targets. While the family was fully identified over 2 decades ago, there has yet to be an in-depth study describing the expression of TIMPs in normal tissues of adult mammals. An understanding of the tissues and cell-types that express TIMPs 1 through 4, in both normal and disease states are important to contextualize the growing functional capabilities of TIMP proteins, which are often dismissed as non-canonical. Using publicly available single cell RNA sequencing data from the Tabula Muris Consortium, we analyzed approximately 100,000 murine cells across nineteen tissues from non-diseased organs, representing seventy-three annotated cell types, to define the diversity in Timp gene expression across healthy tissues. We describe that Timp genes display unique expression profiles across tissues and organ-specific cell types. Within annotated cell-types, we identify clear and discrete cluster-specific patterns of Timp expression, particularly in cells of stromal and endothelial origins. Differential expression and gene set pathway analysis provide evidence of the biological significance of Timp expression in these identified cell sub-types, which are consistent with novel roles in normal tissue homeostasis and changing roles in disease progression. This understanding of the tissues, specific cell types and conditions of the microenvironment in which Timp genes are expressed adds important physiological context to the growing array of novel TIMP protein functions.
Tissue inhibitors of metalloproteinases (TIMPs) are a family of endogenous proteins that were initially defined by their ability to inhibit the enzymatic activity of matrix metalloproteinases (MMPs), the major mediators of ECM breakdown and turnover. TIMPs are important regulators of ECM structure, function and homeostasis. Since their original discovery, additional MMP-independent functions have been attributed to TIMP family members leading to their designation as multifunctional proteins with discrete functional domains. TIMP2 is a unique family member, with a broad expression profile that is expressed in both normal and diseased tissues, even in those with minimal metalloproteinase activity. Understanding the functional transformation of matrisome regulators, like TIMP-2, during the dynamic evolution of tissue microenvironments associated with disease progression is essential to the development of ECM targeted therapeutics. This knowledge may also garner understanding of therapeutic resistance and the failure of conventional and next-generation cancer therapies. Interactome studies are predominantly performed in non-living systems, and very rarely performed in complex culture systems such as 3D spheroids/co-cultures. To investigate the TIMP-2 interactome in complex biological systems we recently developed carboxyl- and amino-terminal fusion genes of TIMP-2 with the promiscuous biotinylating peptides BioID2 and TurboID. Packaged for retroviral delivery, this system gives us great flexibility in assessing the TIMP-2 interactome in simple versus complex 3D co-culture systems. We show, for the first time, that conditions can be optimized to support proximity labeling reactions in the extracellular milieu, representing an important technical resource for extracellular matrix biologists. Using this method, we identify novel interacting partners for TIMP-2 that provide insight into the tissue-specific actions of this protein in both healthy and diseased tissues. Citation Format: David Peeney, Sadeechya Gurung, Yueqin Liu, Carolyn Lazaroff, Christopher Richie, William G. Stetler-Stevenson. Mapping the interactome of the endogenous metalloproteinase inhibitor TIMP2 using extracellular proximity labeling (ePL) [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 3836.
Tissue inhibitors of metalloproteinases (TIMPs) are a family of four paralogous genes that modulate the activity of matrix metalloproteinases (MMPs) and are vital for tissue homeostasis. Additionally, TIMPs display activities that are independent of their MMP inhibitory activities. Dysregulation and perturbations within this system can lead to complex tissue-specific pathologies. TIMP2 is the most abundantly expressed member of the TIMP family and has been shown to display potential therapeutic uses in cancer and other diseases. We have noted the persistent presence of SDS-stable TIMP2 dimers/multimers in SDS-PAGE at a level of ~5% total protein. The goal of this study is to determine the stability and biological relevance of SDS-stable dimer formation of TIMP2 in in vitro and in vivo. We found that TIMP2 dimers display an enhanced ability to inhibit MMP2 activity in reverse zymography assays. Immunoblotting revealed gel extracted TIMP2 dimer entered an equilibrium with monomeric TIMP2, while the extracted monomer did not form new dimer. In addition, MMP2 activity assays do not corroborate the enhanced MMP2 inhibitory activity observed in reverse zymograms but are consistent with the observation that isolated TIMP2 dimers re-equilibrate with monomers. This implies that structural or sequence difference mediates the formation of dimers. Dimer/multimer formation is observed across the TIMP family. Mass spectrometry analysis of gel extracted TIMP monomers and dimers show that monomer and dimer forms of TIMPs display unique post-translation modification (PTM) profiles. We propose that understanding the interplay between TIMP multimers and PTMs will reveal new biological functions within this intriguing family of proteins. We are currently working to resolve the functional differences between monomer and dimer and reveal the underlying mechanisms at play. Citation Format: Carolyn Lazaroff, David Peeney, Sadeechya Gurung, William G. Stetler-Stevenson. The physiological relevance of TIMP dimer formation [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 3837.
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