HMGB1, an evolving pleiotropic protein critical for cellular and tissue homeostasis: Role in aging and age-related diseases

Ageing Res Rev. 2024 Dec:102:102550. doi: 10.1016/j.arr.2024.102550. Epub 2024 Oct 18.

Abstract

Aging is a universal biological process characterized by a progressive, cumulative decline in homeostatic capabilities and physiological functions, which inevitably increases vulnerability to diseases. A number of molecular pathomechanisms and hallmarks of aging have been recognized, yet we miss a thorough understanding of their complex interconnectedness. This review explores the molecular and cellular mechanisms underlying human aging, with a focus on the multiple roles of high mobility group Box 1 protein (HMGB1), the archetypal damage-associated molecular pattern (DAMP) molecule. In the nucleus, this non-histone chromatin-associated protein functions as a DNA chaperone and regulator of gene transcription, influencing DNA structure and gene expression. Moreover, this versatile protein can translocate to the cytoplasm to orchestrate other processes, such as autophagy, or be unconventionally secreted into the extracellular environment, where it acts as a DAMP, combining inflammatory and regenerative properties. Notably, lower expression of HMGB1 within the cell and its heightened extracellular release have been associated with diverse age-associated traits, making it a suitable candidate as a universal biomarker of aging. In this review, we outline the evidence implicating HMGB1 in aging, also in light of an evolutionary perspective on its functional pleiotropy, and propose critical issues that need to be addressed to gauge the value of HMGB1 as a potential biomarker across age-related diseases and therapeutic target to promote healthy longevity.

Keywords: Aging; Autophagy; Biomarker; DAMP (damage-associated molecular pattern); DNA; HMGB1 (high mobility group protein B1); Homeostasis; Inflammation; Redox; Regeneration.

Publication types

  • Review

MeSH terms

  • Aging* / genetics
  • Aging* / metabolism
  • Animals
  • HMGB1 Protein* / metabolism
  • Homeostasis* / physiology
  • Humans

Substances

  • HMGB1 Protein