Regulatory architecture of high-altitude adaptation in Artemisia: from signal perception to specialized metabolism
摘要
High-altitude environments impose a multifactorial stress matrix, including cold, intense UV-B radiation, hypoxia, and drought, which demand integrated adaptive responses. The genus Artemisia exhibits coordinated phenotypic, physiological, and metabolic adaptations to altitude, collectively termed the Altitudinal Stress Syndrome. While recent work has established that this syndrome emerges from integration across genomic, physiological, metabolic, and architectural levels, the regulatory mechanisms coordinating this multi-level integration remain undefined. This review synthesizes molecular evidence from Artemisia to construct a testable framework for the regulatory architecture underlying altitude adaptation. We organize the known components into three functionally distinct levels: signal transducers (reactive oxygen species, calcium, hormones) that convert physical stress into biochemical information; signal integrators (hormonal crosstalk nodes, photoreceptor pathways) where convergent inputs combine; and transcriptional regulators (bHLH, MYB, WRKY families) that execute genome-wide reprogramming. The artemisinin biosynthetic pathway provides a well-mapped case study, revealing how cold signals propagate through AabHLH112 and AaERF1 to biosynthetic genes, how UV-B signals are transduced via AaHY5 and AaGSW1, and how AabHLH113 integrates jasmonate and abscisic acid signals. Competitive dimerization among bHLH factors creates tunable regulatory nodes, whereas epigenetic modifications at AaPAL1 may stabilize adaptive states. We critically evaluate evidence for each connection, distinguishing direct biochemical validation, genetic evidence, and correlational observations. This framework generates specific hypotheses about network architecture testable via genetic, biochemical, and systems-level approaches. By building upon the systems-level foundation of Altitudinal Stress Syndrome, this review advances our understanding from descriptive cataloging to a mechanistic and predictive model of plant adaptation to extreme environments.