Multimodal SHG-2PF Imaging of Microdomain Ca
            <sup>2+</sup>
            -Contraction Coupling in Live Cardiac Myocytes

Awasthi, Samir; Izu, Leighton T.; Mao, Ziliang; Jian, Zhong; Landas, Trevor; Lerner, Aaron B.; Shimkunas, Rafael; Woldeyesus, Rahwa; Bossuyt, Julie; Wood, Brian D.; Chen, Yi‐Je; Matthews, Dennis L; Lieu, Deborah K.; Chiamvimonvat, Nipavan; Lam, Kit S.; Chen‐Izu, Ye; Chan, James W.

doi:10.1161/circresaha.115.307919

Cited by 21 publications

(18 citation statements)

References 61 publications

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“…outside the transverse and axial tubular system (16). Using second harmonic generation and 2-photon-fluorescence, Ca 2+ microdomains generated by RYR2 as well as local sarcomere contractions were analyzed, resulting in detection of locally coordinated Ca 2+ sparks and contractions (17). Although the ER in T cells is not as much ordered as the sarcoplasmic reticulum in cardiac myocytes, we observed alternating patches of RYR and ORAI1 at or very close below the plasma membrane (Fig 4G–J), indicating that proper localization of RYR may in general be an important mechanism for regulation of Ca 2+ microdomains.…”

Section: Spontaneous Ca2+ Microdomainsmentioning

confidence: 99%

ORAI1, STIM1/2, and RYR1 shape subsecond Ca ²⁺ microdomains upon T cell activation

et al. 2018

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The earliest intracellular signals determined in T cell activation are local, sub-second Ca2+ microdomains (1). Here we identify a Ca2+ entry component involved in Ca2+ microdomain formation in both non-stimulated and stimulated cells. In non-stimulated cells, spontaneous small Ca2+ microdomains depend on expression of ORAI1, STIM1, and STIM2. Using T cells stably transfected with ORAI1 fused to a genetically encoded Ca2+ indicator for optical imaging spontaneous Ca2+ microdomains depending on ORAI1 were also detected. Super resolution microscopy of non-stimulated T cells resulted in identification of a circular subplasmalemmal region with a diameter of approx. 300 nm with preformed patches of co-localized ORAI1, ryanodine receptors (RYR), and STIM1. Preformed complexes of STIM1 and ORAI1 in non-stimulated cells were confirmed by co-immunoprecipitation and Förster resonance energy transfer studies. Furthermore, within the first second of T cell receptor (TCR) stimulation, Ca2+ microdomain numbers increase in the subplasmalemmal space, an effect not observed upon genetic deletion of Orai1, Stim2 or Ryr1 or upon antagonism of the Ca2+ mobilizing second messenger nicotinic acid adenine dinucleotide phosphate (NAADP). Taken together, while preformed clusters of STIM and ORAI1 allow for local Ca2+ entry events in non-stimulated cells, upon TCR activation, NAADP-evoked Ca2+ release via RYR1, in tight interplay with Ca2+ entry via ORAI1 and STIM, rapidly increases the number of Ca2+ microdomains, thereby initiating spread of Ca2+ signals deeper into the cytoplasm to promote full T cell activation.

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Section: Spontaneous Ca2+ Microdomainsmentioning

confidence: 99%

ORAI1, STIM1/2, and RYR1 shape subsecond Ca ²⁺ microdomains upon T cell activation

et al. 2018

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“…However, the MCT also caused spontaneous Ca 2+ sparks during diastole that sometimes arise synchronously to form Ca 2+ waves (Awasthi et al . ), which could trigger afterdepolarizations and premature action potentials that provide substrate for cardiac arrhythmias (Kass & Tsien, ; Berlin et al . ; Katra & Laurita, ).…”

Section: Knowledge Gap In Mechano‐chemo‐transductionmentioning

confidence: 99%

Mechano‐chemo‐transduction in cardiac myocytes

Chen‐Izu

Izu

2017

The Journal of Physiology

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The heart has the ability to adjust to changing mechanical loads. The Frank-Starling law and the Anrep effect describe exquisite intrinsic mechanisms the heart has for autoregulating the force of contraction to maintain cardiac output under changes of preload and afterload. Although these mechanisms have been known for more than a century, their cellular and molecular underpinnings are still debated. How does the cardiac myocyte sense changes in preload or afterload? How does the myocyte adjust its response to compensate for such changes? In cardiac myocytes Ca is a crucial regulator of contractile force and in this review we compare and contrast recent studies from different labs that address these two important questions. The 'dimensionality' of the mechanical milieu under which experiments are carried out provide important clues to the location of the mechanosensors and the kinds of mechanical forces they can sense and respond to. As a first approximation, sensors inside the myocyte appear to modulate reactive oxygen species while sensors on the cell surface appear to also modulate nitric oxide signalling; both signalling pathways affect Ca handling. Undoubtedly, further studies will add layers to this simplified picture. Clarifying the intimate links from cellular mechanics to reactive oxygen species and nitric oxide signalling and to Ca handling will deepen our understanding of the Frank-Starling law and the Anrep effect, and also provide a unified view on how arrhythmias may arise in seemingly disparate diseases that have in common altered myocyte mechanics.

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“…Multimodal imaging harnesses the advantages of several imaging techniques to visualize discrete biological processes simultaneously, which otherwise would not be possible by using just one technique at a time ( Awasthi et al., 2016 , Cheng et al., 2011 , Nuriya et al., 2016 , Weissleder and Pittet, 2008 ). TPEF and SHG-based multimodal imaging is mostly restricted to the situation where part of the sample itself generates SHG signals, for example, sarcomeres in cardiomyocytes, thus requiring only a single dye to be used for fluorescence ( Awasthi et al., 2016 ). We performed TPEF and SHG-based multimodal imaging of far-red to NIR emitting dye AK-1 in HEK293T cells with two fluorescent cell trackers, mitochondrial tracker RH123 and LysoTracker Yellow HCK-123 ( Figure 5 ).…”

Section: Resultsmentioning

confidence: 99%

Porphyrin Dyes for Nonlinear Optical Imaging of Live Cells

et al. 2018

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SummarySecond harmonic generation (SHG)-based probes are useful for nonlinear optical imaging of biological structures, such as the plasma membrane. Several amphiphilic porphyrin-based dyes with high SHG coefficients have been synthesized with different hydrophilic head groups, and their cellular targeting has been studied. The probes with cationic head groups localize better at the plasma membrane than the neutral probes with zwitterionic or non-charged ethylene glycol-based head groups. Porphyrin dyes with only dications as hydrophilic head groups localize inside HEK293T cells to give SHG, whereas tricationic dyes localize robustly at the plasma membrane of cells, including neurons, in vitro and ex vivo. The copper(II) complex of the tricationic dye with negligible fluorescence quantum yield works as an SHG-only dye. The free-base tricationic dye has been demonstrated for two-photon fluorescence and SHG-based multimodal imaging. This study demonstrates the importance of a balance between the hydrophobicity and hydrophilicity of amphiphilic dyes for effective plasma membrane localization.

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Multimodal SHG-2PF Imaging of Microdomain Ca ²⁺ -Contraction Coupling in Live Cardiac Myocytes

Cited by 21 publications

References 61 publications

ORAI1, STIM1/2, and RYR1 shape subsecond Ca ²⁺ microdomains upon T cell activation

ORAI1, STIM1/2, and RYR1 shape subsecond Ca ²⁺ microdomains upon T cell activation

Mechano‐chemo‐transduction in cardiac myocytes

Porphyrin Dyes for Nonlinear Optical Imaging of Live Cells

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Multimodal SHG-2PF Imaging of Microdomain Ca 2+ -Contraction Coupling in Live Cardiac Myocytes

Cited by 21 publications

References 61 publications

ORAI1, STIM1/2, and RYR1 shape subsecond Ca 2+ microdomains upon T cell activation

ORAI1, STIM1/2, and RYR1 shape subsecond Ca 2+ microdomains upon T cell activation

Mechano‐chemo‐transduction in cardiac myocytes

Porphyrin Dyes for Nonlinear Optical Imaging of Live Cells

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Product

Resources

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Multimodal SHG-2PF Imaging of Microdomain Ca ²⁺ -Contraction Coupling in Live Cardiac Myocytes

ORAI1, STIM1/2, and RYR1 shape subsecond Ca ²⁺ microdomains upon T cell activation

ORAI1, STIM1/2, and RYR1 shape subsecond Ca ²⁺ microdomains upon T cell activation