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Single-Cell Study Unveils Lead Lifespan in Blood Cell Populations Follows a Universal Lognormal Distribution with Individual Skewness.

Hui JiangYingying GaoXiaoxiang ChenBoqian WangZhixiao XuYiyang LiXinyi SunKun LiuAdeleh DivsalarEdwin CheungLai JiangYifan HongXianting Ding
Published in: Analytical chemistry (2024)
Lead is a widespread environmental hazard that can adversely affect multiple biological functions. Blood cells are the initial targets that face lead exposure. However, a systematic assessment of lead dynamics in blood cells at single-cell resolution is still absent. Herein, C57BL/6 mice were fed with lead-contaminated food. Peripheral blood was harvested at different days. Extracted red blood cells and leukocytes were stained with 19 metal-conjugated antibodies and analyzed by mass cytometry. We quantified the time-lapse lead levels in 12 major blood cell subpopulations and established the distribution of lead heterogeneity. Our results show that the lead levels in all major blood cell subtypes follow lognormal distributions but with distinctively individual skewness. The lognormal distribution suggests a multiplicative accumulation of lead with stochastic turnover of cells, which allows us to estimate the lead lifespan of different blood cell populations by calculating the distribution skewness. These findings suggest that lead accumulation by single blood cells follows a stochastic multiplicative process.
Keyphrases
  • single cell
  • induced apoptosis
  • rna seq
  • cell cycle arrest
  • peripheral blood
  • stem cells
  • high throughput
  • red blood cell
  • heavy metals
  • adipose tissue
  • drinking water
  • signaling pathway
  • body composition
  • postmenopausal women