Biomolecular condensates in kidney physiology and disease

Research output: Contribution to journalReview articleContributedpeer-review

Contributors

  • Guoming Gao - , University of Michigan, Ann Arbor (Author)
  • Emily S. Sumrall - , University of Michigan, Ann Arbor (Author)
  • Sethuramasundaram Pitchiaya - , University of Michigan, Ann Arbor (Author)
  • Markus Bitzer - , University of Michigan, Ann Arbor (Author)
  • Simon Alberti - , Biotechnology Center, Chair of Cellular Biochemistry (Author)
  • Nils G. Walter - , University of Michigan, Ann Arbor (Author)

Abstract

The regulation and preservation of distinct intracellular and extracellular solute microenvironments is crucial for the maintenance of cellular homeostasis. In mammals, the kidneys control bodily salt and water homeostasis. Specifically, the urine-concentrating mechanism within the renal medulla causes fluctuations in extracellular osmolarity, which enables cells of the kidney to either conserve or eliminate water and electrolytes, depending on the balance between intake and loss. However, relatively little is known about the subcellular and molecular changes caused by such osmotic stresses. Advances have shown that many cells, including those of the kidney, rapidly (within seconds) and reversibly (within minutes) assemble membraneless, nano-to-microscale subcellular assemblies termed biomolecular condensates via the biophysical process of hyperosmotic phase separation (HOPS). Mechanistically, osmotic cell compression mediates changes in intracellular hydration, concentration and molecular crowding, rendering HOPS one of many related phase-separation phenomena. Osmotic stress causes numerous homo-multimeric proteins to condense, thereby affecting gene expression and cell survival. HOPS rapidly regulates specific cellular biochemical processes before appropriate protective or corrective action by broader stress response mechanisms can be initiated. Here, we broadly survey emerging evidence for, and the impact of, biomolecular condensates in nephrology, where initial concentration buffering by HOPS and its subsequent cellular escalation mechanisms are expected to have important implications for kidney physiology and disease.

Details

Original languageEnglish
Pages (from-to)756-770
Number of pages15
JournalNature Reviews. Nephrology
Volume19
Issue number12
Early online date26 Sept 2023
Publication statusPublished - Dec 2023
Peer-reviewedYes

External IDs

PubMed 37752323
ORCID /0000-0003-4017-6505/work/161409857

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