An update on the role of sex hormones in the function of the cardiorenal mitochondria.

Multiple studies have highlighted the crucial role of mitochondrial bioenergetics in understanding the progression of cardiorenal diseases, revealing new potential treatment targets related to mitochondrial metabolism. There are well-established sexual dimorphisms in cardiac and renal physiology, with premenopausal females being generally protected from pathology compared with males. The mechanisms of this protection remain to be fully elucidated, however, they clearly depend, at least in part, on sex hormones.

Mechanistic Insights Into Redox Damage of the Podocyte in Hypertension.

Podocytes are specialized cells within the glomerular filtration barrier, which are crucial for maintaining glomerular structural integrity and convective ultrafiltration. Podocytes exhibit a unique arborized morphology with foot processes interfacing by slit diaphragms, ladder-like, multimolecular sieves, which provide size and charge selectivity for ultrafiltration and transmembrane signaling. Podocyte dysfunction, resulting from oxidative stress, dysregulated prosurvival signaling, or structural damage, can drive the development of proteinuria and glomerulosclerosis in hypertensive nephropathy.

Commentary: the perspectives of harnessing the power of scattered tubular-like cells for renal repair.

The commentary discusses the regenerative capacity of the kidneys; recent studies reveal that renal cells can regenerate when exposed to certain conditions. A major focus is on scattered tubular-like cells (STCs), which can dedifferentiate and acquire progenitor-like properties in response to injury. These cells exhibit a glycolytic metabolism, making them resilient to hypoxic conditions and capable of repairing damaged renal tissues.

Blood pressure management strategies and podocyte health.

Hypertension (HTN) is one of the key global cardiovascular risk factors, which is tightly linked to kidney health and disease development. Podocytes, glomerular epithelial cells that play a pivotal role in maintenance of the renal filtration barrier, are significantly affected by increased glomerular capillary pressure in HTN. Damage or loss of these cells causes proteinuria, which marks the initiation of the HTN-driven renal damage.