Intact Cytoskeleton Is Required for Small G Protein Dependent Activation of the Epithelial Na+ Channel

BACKGROUND: The Epithelial Na(+) Channel (ENaC) plays a central role in control of epithelial surface hydration and vascular volume. Similar to other ion channels, ENaC activity is regulated, in part, by cortical cytoskeleton. Besides, the cytoskeleton is an established target for small G proteins signaling. Here we studied whether ENaC activity is modulated by changes in the state of the cytoskeleton and whether cytoskeletal elements are involved in small G protein mediated increase of ENaC activity. METHODS AND FINDINGS: First, the functional importance of the cytoskeleton was established with whole-cell patch clamp experiments recording ENaC reconstituted in CHO cells. Pretreatment with Cytochalasin D (CytD; 10 microg/ml; 1-2 h) or colchicine (500 microM; 1-3 h) to disassembly F-actin and destroy microtubules, respectively, significantly decreased amiloride sensitive current. However, acute application of CytD induced rapid increase in macroscopic current. Single channel measurements under cell-attached conditions revealed similar observations. CytD rapidly increased ENaC activity in freshly isolated rat collecting duct, polarized epithelial mouse mpkCCD(c14) cells and HEK293 cells transiently transfected with ENaC subunits. In contrast, colchicine did not have an acute effect on ENaC activity. Small G proteins RhoA, Rac1 and Rab11a markedly increase ENaC activity. 1-2 h treatment with colchicine or CytD abolished effects of these GTPases. Interestingly, when cells were coexpressed with ENaC and RhoA, short-term treatment with CytD decreased ENaC activity. CONCLUSIONS: We conclude that cytoskeleton is involved in regulation of ENaC and is necessary for small G protein mediated increase of ENaC activity

Intravital imaging of the kidney in a rat model of salt-sensitive hypertension

Hypertension is one of the most prevalent diseases worldwide and a major risk factor for renal failure and cardiovascular disease. The role of albuminuria, a common feature of hypertension and robust predictor of cardiorenal disorders, remains incompletely understood. The goal of this study was to investigate the mechanisms leading to albuminuria in the kidney of a rat model of hypertension, the Dahl salt-sensitive (SS) rat. To determine the relative contributions of the glomerulus and proximal tubule (PT) to albuminuria, we applied intravital two-photon-based imaging to investigate the complex renal physiological changes that occur during salt-induced hypertension. Following a high-salt diet, SS rats exhibited elevated blood pressure, increased glomerular sieving of albumin (GSCalb = 0.0686), relative permeability to albumin (+Δ16%), and impaired volume hemodynamics (-Δ14%). Serum albumin but not serum globulins or creatinine concentration was decreased (-0.54 g/dl), which was concomitant with increased filtration of albumin (3.7 vs. 0.8 g/day normal diet). Pathologically, hypertensive animals had significant tubular damage, as indicated by increased prevalence of granular casts, expansion and necrosis of PT epithelial cells (+Δ2.20 score/image), progressive augmentation of red blood cell velocity (+Δ269 µm/s) and micro vessel diameter (+Δ4.3 µm), and increased vascular injury (+Δ0.61 leakage/image). Therefore, development of salt-induced hypertension can be triggered by fast and progressive pathogenic remodeling of PT epithelia, which can be associated with changes in albumin handling. Collectively, these results indicate that both the glomerulus and the PT contribute to albuminuria, and dual treatment of glomerular filtration and albumin reabsorption may represent an effective treatment of salt-sensitive hypertension

mCCDcl1 cells show Plasticity Consistent with the Ability to Transition between Principal and Intercalated Cells

The cortical collecting duct of the mammalian kidney plays a critical role in the regulation of body volume, sodium pH, and osmolarity and is composed of two distinct cells types, principal cells and intercalated cells. Each cell type is detectable in the kidney by the localization of specific transport proteins such as aquaporin 2 (Aqp2) and epithelial sodium channel (ENaC) in principal cells and V-ATPase B1 and connexin 30 (Cx30) in intercalated cells. mCCD cl1 cells have been widely used as a mouse principal cell line on the basis of their physiological characteristics. In this study, the mCCD cl1 parental cell line and three sublines cloned from isolated single cells (Ed1, Ed2, and Ed3) were grown on filters to assess their transepithelial resistance, transepithelial voltage, equivalent short circuit current and expression of the cell-specific markers Aqp2, ENaC, V-ATPaseB1, and Cx30. The parental mCCD cl1 cell line presented amiloride-sensitive electrogenic sodium transport indicative of principal cell function; however, immunocytochemistry and RT-PCR showed that some cells expressed the intercalated cell-specific markers V-ATPase B1 and Cx30, including a subset of cells also positive for Aqp2 and ENaC. The three subclonal lines contained cells that were positive for both intercalated and principal cell-specific markers. The vertical transmission of both principal and intercalated cell characteristics via single cell cloning reveals the plasticity of mCCD cl1 cells and a direct lineage relationship between these two physiologically important cell types and is consistent with mCCDcl1 cells being precursor cells. </p

Piezo is essential for amiloride-sensitive stretch-activated mechanotransduction in larval Drosophila dorsal bipolar dendritic sensory neurons

Date of Acceptance: 05/06/2015Peer reviewedPublisher PD

Knockout of kcnj16 (kir5.1) in Dahl salt-sensitive rats produces seizure phenotype

Kir5.1 is a member of an inwardly rectifying potassium (Kir) channel family notably present in the kidney and brain. We previously established that a knockout rat model of Kcnj16 (gene encoding Kir5.1) on a Dahl salt-sensitive background (SSKcnj16-/-) exhibits a severe cardiovascular phenotype (Palygin et al., JCI Insight, 2017). Mutations in ion channel genes can alter neuronal excitability and mutations in Kir genes have been linked to seizure disorders in humans. Since Kir5.1 is known to be expressed in the brain and may contribute to neuronal membrane potential and spatial potassium buffering, we hypothesized that in addition to cardiovascular and renal dysfunction, neurological phenotypes, including seizures, would be prevalent in the SSKcnj16-/-rats. We found that SSKcnj16-/- rats (but not control SS rats) experience tonic-clonic seizures when exposed to a 10 kHz tone (86 dB for 2 min), whereas other frequencies (0.1 or 1 kHz) did not elicit seizures. When exposed to the seizure-inducing acoustic stimulus once/day for 10 days, we noted that SSKcnj16-/- rats experienced a seizure in response to 92% of stimuli. SSKcnj16-/- rats also showed spontaneous mortality within hours after a stimulus with a survival rate of 67% (N=21) for the duration of the 10 day protocol. Control rats (N=10) had no incidence of seizure or death during the 10 days of acoustic stimulation. We found no difference among male and female SSKcnj16-/- rats, where both sexes had a similar audiogenic seizure response and reduced survival. Behavioral tests including a modified Irwin screen and open field test revealed that before and after seizure stimulation SSKcnj16-/- rats tended to have altered activity levels, gait, piloerection, and respiration rates. Analysis of blood electrolytes revealed critically low serum potassium levels in SSKcnj16-/- compared to SS controls, a difference that appeared to be exacerbated by repeated seizures. We hypothesize that seizures may be intensifying potassium imbalance and disrupting the homeostasis that is particularly essential for excitable cells such as neurons. We conclude that knockout of Kir5.1 leads to distinct neurological phenotypes including a seizure disorder and subsequent spontaneous death, which may have relevance to channelopathies associated with seizure disorders in humans