Shurooq H. Karam scite author profile

et al. 2021

Sci Rep

Severe renal ischemia-reperfusion injury (IRI) can lead to acute and chronic kidney dysfunction. Cytoskeletal modifications are among the main effects of this condition. The majority of studies that have contributed to the current understanding of IRI have relied on histological analyses using exogenous probes after the fact. Here we report the successful real-time visualization of actin cytoskeletal alterations in live proximal and distal tubules that arise at the onset of severe IRI. To achieve this, we induced fluorescent actin expression in these segments in rats with hydrodynamic gene delivery (HGD). Using intravital two-photon microscopy we then tracked and quantified endogenous actin dysregulation that occurred by subjecting these animals to 60 min of bilateral renal ischemia. Rapid (by 1-h post-reperfusion) and significant (up to 50%) declines in actin content were observed. The decline in fluorescence within proximal tubules was significantly greater than that observed in distal tubules. Actin-based fluorescence was not recovered during the measurement period extending 24 h post-reperfusion. Such injury decimated the renal architecture, in particular, actin brush borders, and hampered the reabsorptive and filtrative capacities of these tubular compartments. Thus, for the first time, we show that the combination of HGD and intravital microscopy can serve as an experimental tool to better understand how IRI modifies the cytoskeleton in vivo and provide an extension to current histopathological techniques.

Intravital imaging of real-time endogenous actin dysregulation in proximal and distal tubules at the onset of severe ischemia-reperfusion injury

Corridon

et al. 2021

Preprint

Severe renal ischemia-reperfusion injury (IRI) can lead to acute and chronic kidney dysfunction. Cytoskeletal modifications are among the main effects of this condition. The majority of studies that have contributed to the current understanding of IRI have relied on histological analyses using exogenous probes after the fact. Here we report the successful real-time visualization of actin cytoskeletal alterations in live proximal and distal tubules that arise at the onset of severe IRI. To achieve this, we induced fluorescent actin expression in these segments in rats with hydrodynamic gene delivery (HGD). Using intravital two-photon microscopy we then tracked and quantified endogenous actin dysregulation that occurred by subjecting these animals to 60 minutes of bilateral renal ischemia. Rapid (by 1-hour post-reperfusion) and significant (up to 50%) declines in actin content were observed. The decline in fluorescence within proximal tubules was significantly greater than that observed in distal tubules. Actin-based fluorescence was not recovered during the measurement period extending 24 hours post-reperfusion. Such injury decimated the renal architecture, in particular, actin brush borders, and hampered the reabsorptive and filtrative capacities of these tubular compartments. Thus, for the first time, we show that the combination of HGD and intravital microscopy can serve as an experimental tool to better understand how IRI modifies the cytoskeleton in vivo and provide an extension to current histopathological techniques.

Real‐time in vivo imaging confirms the presence of apoptotic signaling at the onset of ischemia‐reperfusion injury

et al. 2021

Renal ischemia‐reperfusion injury (IRI) is a complex disorder characterized by varying degrees of structural and functional losses. The degree of the insult depends on the severity of the condition and the kidney's ability to recover. IRI simultaneously contributes to the development of acute tubular injury and microvascular/endothelial injury. To further complicate matters, it is also believed that microvascular/endothelial injury leads to apoptotic signaling to, in turn, further reduce capillary density and blood flow, and exacerbate tubular damage that supports the transition from acute to chronic disorders. In recent times, studies have employed intravital imaging systems to enhance our understanding of these mechanisms. Such studies have identified ways that intravital renal imaging can be used to track apoptosis in vivo. As a result, we aimed to build on this convention by searching for evidence of apoptotic signaling at the onset of IRI. Using intravital two‐photon microscopy, fluorescent micrographs of tubular nuclei were collected and examined at the onset of ischemia. Signs of apoptosis were identified by cell shrinkage that led to the formation of apoptotic bodies. Furthermore, the concurrent presence of necrotic signaling, which led to increased cell permeability and swelling, was also visualized. Altogether these results confirm the presence of apoptotic signaling, as well as, necrotic signaling, and provide important evidence about the previously unconfirmed cell death mechanisms that can support the debilitating progression of IRI.

POS-065 Monitoring vascular function at the onset of live in vivo renal ischemia-reperfusion injury

Alhashmi

Kidney International Reports

et al. 2021

Intravital imaging of real-time endogenous actin dysregulation in proximal and distal tubules at the onset of severe ischemia-reperfusion injury

Corridon

et al. 2021

Preprint

Severe renal ischemia-reperfusion injury (IRI) can lead to acute and chronic kidney dysfunction. Cytoskeletal modifications are among the main effects of this condition. The majority of studies that have contributed to the current understanding of IRI have relied on histological analyses using exogenous probes after the fact. Here we report the successful real-time visualization of actin cytoskeletal alterations in live proximal and distal tubules that arise at the onset of severe IRI. To achieve this, we induced fluorescent actin expression in these segments in rats with hydrodynamic gene delivery (HGD). Using intravital two-photon microscopy we then tracked and quantified endogenous actin dysregulation that occurred by subjecting these animals to 60 minutes of bilateral renal ischemia. Rapid (by 1-hour post-reperfusion) and significant (up to 50%) declines in actin content were observed. The decline in fluorescence within proximal tubules was significantly greater than that observed in distal tubules. Actin-based fluorescence was not recovered during the measurement period extending 24 hours post-reperfusion. Such injury decimated the renal architecture, in particular, actin brush borders, and hampered the reabsorptive and filtrative capacities of these tubular compartments. Thus, for the first time, we show that the combination of HGD and intravital microscopy can serve as an experimental tool to better understand how IRI modifies the cytoskeleton in vivo and provide an extension to current histopathological techniques.