陥没穴が進化の罠となるメカニズムを解明(Chinese Researchers Uncover Sinkhole Evolutionary Trap)

2026-07-16 中国科学院(CAS)

中国科学院(CAS)華南植物園(SCBG)などの研究チームは、カルスト地形のシンクホール(陥没穴)が絶滅危惧樹木Magnolia aromatica(旧 Manglietia aromatica)の避難場所である一方、進化的には「進化の罠」となり得ることを明らかにし、Current Biologyに発表した。研究では、基準ゲノムを構築した上で、中国南西部26集団・112個体のゲノムを解析した。その結果、シンクホール周辺の集団は気候変動下でも種の存続に寄与する遺伝的多様性を維持していたが、シンクホール内部の集団では遺伝的多様性が低く、有害変異の蓄積が多いことが判明した。また、内部集団は極端な低照度環境に適応しており、強光下では実生が高率で枯死する一方、弱光下で良好に成長した。光合成や炭素固定に関わる遺伝子にも適応の痕跡が確認された。しかし、この特殊化は環境変化への適応力を低下させ、2100年には高排出シナリオで生育適地の約3分の1が失われると予測された。研究は、生息地保全だけでなく集団間の遺伝子流動を維持することが絶滅危惧植物の長期保全に不可欠であることを示した。

<関連情報>

カルスト天坑は絶滅危惧種のモクレン(Magnolia aromatica)の進化の可能性を保存するが、同時にその可能性を制限する Karst tiankengs preserve but constrain evolutionary potential in the endangered tree Magnolia aromatica

Xian-Liang Zhu ∙ Jian-Min Tang ∙ Chao Feng ∙ … ∙ Jing Wang ∙ Xiao Wei ∙ Ming Kang
Current Biology  Published:July 14, 2026
DOI:https://doi.org/10.1016/j.cub.2026.06.051

陥没穴が進化の罠となるメカニズムを解明(Chinese Researchers Uncover Sinkhole Evolutionary Trap)

Highlights

  • Tiankengs act as nested microrefugia that buffer stress but isolate populations
  • Tiankeng-interior populations show reduced diversity and elevated deleterious load
  • Selection on photosynthesis aligns with strong seedling dependence on deep shade
  • Future persistence faces compound risks from climate mismatch and genomic erosion

Summary

Karst tiankengs—giant enclosed sinkholes—harbor humid, shaded forests that may buffer climate stress yet isolate populations. Here, we generated a near telomere-to-telomere genome assembly for the endangered karst tree Magnolia aromatica and resequenced 26 populations across tiankeng interiors and surrounding habitats in southwest China. Population genomics resolved four lineages and indicated a history of divergence with gene flow constrained by strong dispersal barriers. At the lineage scale, tiankeng-associated populations exhibited intermediate genomic diversity and mutation load relative to non-tiankeng lineages. At fine spatial scales, however, tiankeng-interior populations showed reduced diversity and elevated deleterious burden compared with nearby exterior populations, consistent with demographic isolation and strong genetic drift. We detected lineage-specific selection signals in genes related to photosynthesis and carbon fixation, and shading experiments revealed that seedlings exhibited high mortality under strong light but survived and grew well under deep shade. Forecasts combining species distribution models, genomic offset, and mutation-load prediction identified future risk hotspots near barriers and suggested that genomic erosion may compound climate vulnerability in parts of the range. Together, these results indicate that karst tiankengs can function as nested microrefugia that promote persistence while constraining connectivity and long-term evolutionary potential, with important implications for conserving edaphic specialists under climate change.

1903自然環境保全
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