Browsing by Author "Tune, Jonathan D."

Now showing 1 - 2 of 2
  • Thumbnail Image
    Item
    Bone Perfusion Alterations in Chronic Kidney Disease
    (2019-05) Aref, Mohammad W.; Allen, Matthew R.; Organ, Jason M.; Tune, Jonathan D.; Wallace, Joseph M.; Moe, Sharon M.
    Patients with chronic kidney disease (CKD) are at an alarming risk of fracture and cardiovascular disease-associated mortality. There is a critical need to better understand the underlying mechanism driving altered cardiovascular and skeletal homeostasis, as well as any connection between the two. CKD has been shown to have negative effects on many vascular properties including endorgan perfusion. Surprisingly, exploration of skeletal perfusion and vasculature has not been undertaken in CKD. Alterations in bone perfusion are linked to dysregulation of bone remodeling and mass in multiple conditions. An understanding of the detrimental impact of CKD on bone perfusion is a crucial step in understanding bone disease in these patients. The goal of this series of studies was to test the global hypothesis that skeletal perfusion is altered in CKD and that alterations can be modulated through treatments that affect metabolic dysfunction. These studies utilized a rat model of CKD to conduct metabolic assessments, bone perfusion measurements, bone imaging studies, and isolated vessel reactivity experiments. Our results showed that animals with CKD had higher levels of parathyroid hormone (PTH), leading to substantial bone resorption. Bone perfusion measurements showed CKD-induced elevations in cortical bone perfusion with levels progressing alongside CKD severity. Conversely we show that marrow perfusion was lower in advanced CKD. PTH suppression therapy in animals with CKD resulted in the normalization of cortical bone perfusion and cortical bone mass, but did not normalize marrow bone perfusion. These results show a clear association between bone deterioration and altered bone perfusion in CKD. While the relationship of altered bone perfusion and bone deterioration in CKD necessitates further work, these results indicate that determining the mechanisms of bone perfusion alterations and whether they are drivers, propagators, or consequences of skeletal deterioration in CKD could help untangle a key player in CKD-induced bone alterations.
  • Thumbnail Image
    Item
    Coronary Smooth Muscle Cell Cytodifferentiation and Intracellular Ca2+ Handling in Coronary Artery Disease
    (2019-08) Badin, Jill Kimberly; Sturek, Michael S.; Evans-Molina, Carmella; Moe, Sharon; Tune, Jonathan D.
    Metabolic syndrome (MetS) affects 1/3 of all Americans and is the clustering of three or more of the following cardiometabolic risk factors: obesity, hypertension, dyslipidemia, glucose intolerance, and insulin resistance. MetS drastically increases the incidence of coronary artery disease (CAD), which is the leading cause of mortality globally. A cornerstone of CAD is arterial remodeling associated with coronary smooth muscle (CSM) cytodifferentiation from a contractile phenotype to proliferative and osteogenic phenotypes. This cytodifferentiation is tightly coupled to changes in intracellular Ca2+ handling that regulate several key cellular functions, including contraction, transcription, proliferation, and migration. Our group has recently elucidated the time course of Ca2+ dysregulation during MetS-induced CAD development. Ca2+ transport mechanisms, including voltage-gated calcium channels, sarcoplasmic reticulum (SR) Ca2+ store, and sarco-endoplasmic reticulum Ca2+ ATPase (SERCA), are enhanced in early, mild disease and diminished in late, severe disease in the Ossabaw miniature swine. Using this well-characterized large animal model, I tested the hypothesis that this Ca2+ dysregulation pattern occurs in multiple etiologies of CAD, including diabetes and aging. The fluorescent intracellular Ca2+ ([Ca2+]i) indicator fura-2 was utilized to measure [Ca2+]i handling in CSM from lean and diseased swine. I found that [Ca2+]i handling is enhanced in mild disease with minimal CSM phenotypic switching and diminished in severe disease with greater phenotypic switching, regardless of CAD etiology. We are confident of the translatability of this research, as the Ca2+ influx, SR Ca2+ store, and SERCA functional changes in CSM of humans with CAD are similar to those found in Ossabaw swine with MetS. Single-cell RNA sequencing revealed that CSM cells from an organ culture model of CAD exhibited many different phenotypes, indicating that phenotypic modulation is not a discreet event, but a continuum. Transcriptomic analysis revealed differential expression of many genes that are involved in the osteogenic signaling pathway and in cellular inflammatory responses across phenotypes. These genes may be another regulatory mechanism common to the different CAD etiologies. This study is the first to show that CSM Ca2+ dysregulation is common among different CAD etiologies in a clinically relevant animal model.