Your search keyword '"Griffin, Timothy M."' showing total 6 results

1. Sexually dimorphic metabolic effects of a high fat diet on knee osteoarthritis in mice

Author

Griffin, Timothy M., Lopes, Erika Barboza Prado, Cortassa, Dominic, Batushansky, Albert, Jeffries, Matlock A., Makosa, Dawid, Jopkiewicz, Anita, Mehta-D’souza, Padmaja, Komaravolu, Ravi K., and Kinter, Michael T.

Published

2024

2. Fundamentals of OA An initiative of Osteoarthritis and Cartilage Chapter 9: Obesity and metabolic factors in OA

Author

Batushansky, Albert, Zhu, Shouan, Komaravolu, Ravi K., South, Sanique, Mehta-D’souza, Padmaja, and Griffin, Timothy M.

Subjects

Inflammation, Metabolic Syndrome, Cartilage, Disease Progression, Humans, Female, Obesity, Osteoarthritis, Knee, Article, Biomarkers

Abstract

OBJECTIVE: Obesity was once considered a risk factor for knee osteoarthritis (OA) primarily for biomechanical reasons. Here we provide an additional perspective by discussing how obesity also increases OA risk by altering metabolism and inflammation. DESIGN: This narrative review is presented in four sections: 1) metabolic syndrome and OA, 2) metabolic biomarkers of OA, 3) evidence for dysregulated chondrocyte metabolism in OA, and 4) metabolic inflammation: joint tissue mediators and mechanisms. RESULTS: Metabolic syndrome and its components are strongly associated with OA. However, evidence for a causal relationship is context dependent, varying by joint, gender, diagnostic criteria, and demographics, with additional environmental and genetic interactions yet to be fully defined. Importantly, some aspects of the etiology of obesity-induced OA appear to be distinct between men and women, especially regarding the role of adipose tissue. Metabolomic analyses of serum and synovial fluid have identified potential diagnostic biomarkers of knee OA and prognostic biomarkers of disease progression. Connecting these biomarkers to cellular pathophysiology will require future in vivo studies of joint tissue metabolism. Such studies will help reveal when a metabolic process or a metabolite itself is a causal factor in disease progression. Current evidence points towards impaired chondrocyte metabolic homeostasis and metabolic-immune dysregulation as likely factors connecting obesity to the increased risk of OA. CONCLUSIONS: A deeper understanding of how obesity alters metabolic and inflammatory pathways in synovial joint tissues is expected to provide new therapeutic targets and an improved definition of “metabolic” and “obesity” OA phenotypes.

Published

2021

3. In Vivo Stable Isotope Labeling Method to Investigate Individual Matrix Protein Synthesis, Ribosomal Biogenesis, and Cellular Proliferation in Murine Articular Cartilage.

Author

Kobak, Kamil A, Batushansky, Albert, Borowik, Agnieszka K, Lopes, Erika Prado Barboza, Peelor III, Frederick F, Donovan, Elise L, Kinter, Michael T, Miller, Benjamin F, and Griffin, Timothy M

Subjects

EXTRACELLULAR matrix proteins, ARTICULAR cartilage, PROTEIN synthesis, CELL proliferation, DEUTERIUM oxide, RIBOSOMAL proteins, KNEE, CARTILAGE

Abstract

Targeting chondrocyte dynamics is a strategy for slowing osteoarthritis progression during aging. We describe a stable-isotope method using in vivo deuterium oxide labeling and mass spectrometry to measure protein concentration, protein half-life, cell proliferation, and ribosomal biogenesis in a single sample of murine articular cartilage. We hypothesized that a 60-d labeling period would capture age-related declines in cartilage matrix protein content, protein synthesis rates, and cellular proliferation. Knee cartilage was harvested to the subchondral bone from 25- to 90-wk-old female C57BL/6J mice treated with deuterium oxide for 15, 30, 45, and 60 d. We measured protein concentration and half-lives using targeted high resolution accurate mass spectrometry and d2ome data processing software. Deuterium enrichment was quantified in isolated DNA and RNA to measure cell proliferation and ribosomal biogenesis, respectively. Most collagen isoforms were less abundant in aged animals, with negligible collagen synthesis at either age. In contrast, age altered the concentration and half-lives of many proteoglycans and other matrix proteins, including several with greater concentration and half-lives in older mice such as proteoglycan 4, clusterin, and fibronectin-1. Cellular proteins were less abundant in older animals, consistent with reduced cellularity. Nevertheless, deuterium was maximally incorporated into 60% of DNA and RNA by 15 d of labeling in both age groups, suggesting the presence of two large pools of either rapidly (<15 d) or slowly (>60 d) proliferating cells. Our findings indicate that age-associated changes in cartilage matrix protein content and synthesis occur without detectable changes in the relative number of proliferating cells. [ABSTRACT FROM AUTHOR]

Published

2022

4. Glutathione as a mediator of cartilage oxidative stress resistance and resilience during aging and osteoarthritis.

Author

Zhu, Shouan, Makosa, Dawid, Miller, Benjamin, and Griffin, Timothy M.

Subjects

CARTILAGE, PATELLA, GLUTATHIONE, OXIDANT status, OXIDATIVE stress, COMPRESSION loads, CYCLIC loads

Abstract

Purpose: An underlying cause of osteoarthritis (OA) is the inability of chondrocytes to maintain homeostasis in response to changing stress conditions. The purpose of this article was to review and experimentally evaluate oxidative stress resistance and resilience concepts in cartilage using glutathione redox homeostasis as an example. This framework may help identify novel approaches for promoting chondrocyte homeostasis during aging and obesity. Materials and Methods: Changes in glutathione content and redox ratio were evaluated in three models of chondrocyte stress: (1) age- and tissue-specific changes in joint tissues of 10 and 30-month old F344BN rats, including ex vivo patella culture experiments to evaluate N-acetylcysteine dependent resistance to interleukin-1beta; (2) effect of different durations and patterns of cyclic compressive loading in bovine cartilage on glutathione stress resistance and resilience pathways; (3) time-dependent changes in GSH:GSSG in primary chondrocytes from wild-type and Sirt3 deficient mice challenged with the pro-oxidant menadione. Results: Glutathione was more abundant in cartilage than meniscus or infrapatellar fat pad, although cartilage was also more susceptible to age-related glutathione oxidation. Glutathione redox homeostasis was sensitive to the duration of compressive loading such that load-induced oxidation required unloaded periods to recover and increase total antioxidant capacity. Exposure to a pro-oxidant stress enhanced stress resistance by increasing glutathione content and GSH:GSSG ratio, especially in Sirt3 deficient cells. However, the rate of recovery, a marker of resilience, was delayed without Sirt3. Conclusions: OA-related models of cartilage stress reveal multiple mechanisms by which glutathione provides oxidative stress resistance and resilience. [ABSTRACT FROM AUTHOR]

Published

2020

5. Profibrotic Infrapatellar Fat Pad Remodeling Without M1 Macrophage Polarization Precedes Knee Osteoarthritis in Mice With Diet-Induced Obesity.

Author

Barboza, Erika, Hudson, Joanna, Chang, Wan‐Pin, Kovats, Susan, Towner, Rheal A., Silasi‐Mansat, Robert, Lupu, Florea, Kent, Collin, and Griffin, Timothy M.

Subjects

ANIMAL experimentation, CARTILAGE, CYTOKINES, FAT cells, GENE expression, IMMUNOHISTOCHEMISTRY, INFLAMMATION, KNEE diseases, MAGNETIC resonance imaging, MICE, OBESITY, OSTEOARTHRITIS

Abstract

Objective To test the hypothesis that high-fat (HF) diet-induced obesity increases proinflammatory cytokine expression, macrophage infiltration, and M1 polarization in the infrapatellar fat pad (IFP) prior to knee cartilage degeneration. Methods We characterized the effect of HF feeding on knee OA pathology, body adiposity, and glucose intolerance in male C57BL/6J mice and identified a diet duration that induces metabolic dysfunction prior to cartilage degeneration. Magnetic resonance imaging and histomorphology were used to quantify changes in the epididymal, subcutaneous, and infrapatellar fat pads and in adipocyte sizes. Finally, we used targeted gene expression and protein arrays, immunohistochemistry, and flow cytometry to quantify differences in fat pad markers of inflammation and immune cell populations. Results Twenty weeks of feeding with an HF diet induced marked obesity, glucose intolerance, and early osteoarthritis (OA), including osteophytes and cartilage tidemark duplication. This duration of HF feeding increased the IFP volume. However, it did not increase IFP inflammation, macrophage infiltration, or M1 macrophage polarization as observed in epididymal fat. Furthermore, leptin protein levels were reduced. This protection from obesity-induced inflammation corresponded to increased IFP fibrosis and the absence of adipocyte hypertrophy. Conclusion The IFP does not recapitulate classic abdominal adipose tissue inflammation during the early stages of knee OA in an HF diet-induced model of obesity. Consequently, these findings do not support the hypothesis that IFP inflammation is an initiating factor of obesity-induced knee OA. Furthermore, the profibrotic and antihypertrophic responses of IFP adipocytes to HF feeding suggest that intraarticular adipocytes are subject to distinct spatiotemporal structural and metabolic regulation among fat pads. [ABSTRACT FROM AUTHOR]

Published

2017

6. Emerging role of metabolic signaling in synovial joint remodeling and osteoarthritis.

Author

June, Ronald K., Liu‐Bryan, Ru, Long, Fanxing, and Griffin, Timothy M.

Subjects

JOINTS (Anatomy), OSTEOARTHRITIS, METABOLIC syndrome, OBESITY, CARTILAGE, PHYSIOLOGY

Abstract

ABSTRACT Obesity and associated metabolic diseases collectively referred to as the metabolic syndrome increase the risk of skeletal and synovial joint diseases, including osteoarthritis (OA). The relationship between obesity and musculoskeletal diseases is complex, involving biomechanical, dietary, genetic, inflammatory, and metabolic factors. Recent findings illustrate how changes in cellular metabolism and metabolic signaling pathways alter skeletal development, remodeling, and homeostasis, especially in response to biomechanical and inflammatory stressors. Consequently, a better understanding of the energy metabolism of diarthrodial joint cells and tissues, including bone, cartilage, and synovium, may lead to new strategies to treat or prevent synovial joint diseases such as OA. This rationale was the basis of a workshop presented at the 2016 Annual ORS Meeting in Orlando, FL on the emerging role of metabolic signaling in synovial joint remodeling and OA. The topics we covered included (i) the relationship between metabolic syndrome and OA in clinical and pre-clinical studies; (ii) the effect of biomechanical loading on chondrocyte metabolism; (iii) the effect of Wnt signaling on osteoblast carbohydrate and amino acid metabolism with respect to bone anabolism; and (iv) the role of AMP-activated protein kinase in chondrocyte energetic and biomechanical stress responses in the context of cartilage injury, aging, and OA. Although challenges exist for measuring in vivo changes in synovial joint tissue metabolism, the findings presented herein provide multiple lines of evidence to support a central role for disrupted cellular energy metabolism in the pathogenesis of OA. © 2016 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 34:2048-2058, 2016. [ABSTRACT FROM AUTHOR]

Published

2016