# RNA-based Mechanisms of Mechanical Homeostasis

> **NIH NIH F32** · YALE UNIVERSITY · 2021 · $68,562

## Abstract

PROPOSAL SUMMARY (ABSTRACT)
 Many pathologies in numerous organ systems are associated with fibrosis. Fibrosis, characterized by
tissue stiffening, occurs when cells are unable to maintain the mechanical properties of tissues, determined
primarily by their extracellular matrix (ECM). In healthy tissues, cells maintain ECM composition and organization
through feedback signaling that can sense the stiffness of the physical microenvironment and maintain the
mechanical steady state. Dysfunction of this feedback signaling in cells can lead to an imbalance between
synthesis and degradation of matrix resulting in tissue stiffening, fibrosis, and tissue malfunction. Unfortunately,
the molecular mechanisms that control mechanical homeostasis remain largely unknown. This lack of knowledge
constitutes a major limitation for understanding fibrosis and developing possible treatments. The proposed study
will address this gap in knowledge by investigating novel mechanisms of mechanical homeostasis in vitro and in
vivo.
 One key process in the maintenance of mechanical homeostasis is the cells ability to sense and respond
appropriately to the stiffness of the surrounding ECM. Cells bind directly to the ECM through focal adhesions
(FAs). FAs are intracellular protein complexes at the cell membrane-ECM interface that mediate ECM-dependent
signaling pathways. FAs mediate cell response to the ECM by changing composition and organization of over
200 proteins. However, it is currently unknown what mechanism(s) enable this dynamic regulation of proteins at
FA complexes in response ECM stiffness. My preliminary data identified local translation of FA proteins occurring
directly at the FAs. Additionally, I identified mRNA regulatory factors including miRNAs and RNA binding proteins
localized at FAs. Thus, the goal of this proposal is to determine if regulation of local translation mediates cell-
ECM stiffness interactions. Using a cell culture system (in vitro), I will pinpoint the specific regulatory factors that
mediate local translation and determine their role in the response to changes in substrate stiffness (Aim 1).
Fibrosis occurs in 3D tissues which harbor a complex physical microenvironment. Therefore, I will use the
zebrafish fin-fold regeneration model (in vivo) to visualize and disrupt mRNA localization to FAs during tissue
regeneration (Aim 2). Together, these proposed experiments will fill a critical gap in knowledge for the study of
cell-ECM interactions and, therefore, mechanical homeostasis. Discovering the mechanism(s) of physiological
matrix homeostasis are critical for overcoming current barriers in understanding fibrosis and developing effective
treatments.

## Key facts

- **NIH application ID:** 10145488
- **Project number:** 5F32GM133176-02
- **Recipient organization:** YALE UNIVERSITY
- **Principal Investigator:** Liana Boraas
- **Activity code:** F32 (R01, R21, SBIR, etc.)
- **Funding institute:** NIH
- **Fiscal year:** 2021
- **Award amount:** $68,562
- **Award type:** 5
- **Project period:** 2020-07-01 → 2022-06-30

## Primary source

NIH RePORTER: https://reporter.nih.gov/project-details/10145488

## Citation

> US National Institutes of Health, RePORTER application 10145488, RNA-based Mechanisms of Mechanical Homeostasis (5F32GM133176-02). Retrieved via AI Analytics 2026-05-21 from https://api.ai-analytics.org/grant/nih/10145488. Licensed CC0.

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