Cawley Center for Translational Cancer Research, Helen F. Graham Cancer Center and Research Institute, Newark, DE, United States of America.
University of Delaware, Newark, DE, United States of America.
PLoS One. 2020 Oct 28;15(10):e0239601. doi: 10.1371/journal.pone.0239601. eCollection 2020.
APC mutations drive human colorectal cancer (CRC) development. A major contributing factor is colonic stem cell (SC) overpopulation. But, the mechanism has not been fully identified. A possible mechanism is the dysregulation of neuroendocrine cell (NEC) maturation by APC mutations because SCs and NECs both reside together in the colonic crypt SC niche where SCs mature into NECs. So, we hypothesized that sequential inactivation of APC alleles in human colonic crypts leads to progressively delayed maturation of SCs into NECs and overpopulation of SCs. Accordingly, we used quantitative immunohistochemical mapping to measure indices and proportions of SCs and NECs in human colon tissues (normal, adenomatous, malignant), which have different APC-zygosity states. In normal crypts, many cells staining for the colonic SC marker ALDH1 co-stained for chromogranin-A (CGA) and other NEC markers. In contrast, in APC-mutant tissues from familial adenomatous polyposis (FAP) patients, the proportion of ALDH+ SCs progressively increased while NECs markedly decreased. To explain how these cell populations change in FAP tissues, we used mathematical modelling to identify kinetic mechanisms. Computational analyses indicated that APC mutations lead to: 1) decreased maturation of ALDH+ SCs into progenitor NECs (not progenitor NECs into mature NECs); 2) diminished feedback signaling by mature NECs. Biological experiments using human CRC cell lines to test model predictions showed that mature GLP-2R+ and SSTR1+ NECs produce, via their signaling peptides, opposing effects on rates of NEC maturation via feedback regulation of progenitor NECs. However, decrease in this feedback signaling wouldn't explain the delayed maturation because both progenitor and mature NECs are depleted in CRCs. So the mechanism for delayed maturation must explain how APC mutation causes the ALDH+ SCs to remain immature. Given that ALDH is a key component of the retinoic acid (RA) signaling pathway, that other components of the RA pathway are selectively expressed in ALDH+ SCs, and that exogenous RA ligands can induce ALDH+ cancer SCs to mature into NECs, RA signaling must be attenuated in ALDH+ SCs in CRC. Thus, attenuation of RA signaling explains why ALDH+ SCs remain immature in APC mutant tissues. Since APC mutation causes increased WNT signaling in FAP and we found that sequential inactivation of APC in FAP patient tissues leads to progressively delayed maturation of colonic ALDH+ SCs, the hypothesis is developed that human CRC evolves due to an imbalance between WNT and RA signaling.
APC 突变驱动人类结直肠癌 (CRC) 的发展。一个主要的促成因素是结肠干细胞 (SC) 的过度增殖。但是,其机制尚未完全确定。一种可能的机制是 APC 突变导致神经内分泌细胞 (NEC) 成熟失调,因为 SC 和 NEC 都存在于结肠隐窝 SC 龛位中,SC 在其中成熟为 NEC。因此,我们假设 APC 等位基因在人结肠隐窝中的顺序失活会导致 SC 向 NEC 的成熟逐渐延迟,并导致 SC 的过度增殖。因此,我们使用定量免疫组织化学图谱测量了具有不同 APC 杂合状态的人结肠组织(正常、腺瘤、恶性)中 SC 和 NEC 的指数和比例。在正常隐窝中,许多染色为结肠 SC 标志物 ALDH1 的细胞也染色为嗜铬粒蛋白-A (CGA) 和其他 NEC 标志物。相比之下,在家族性腺瘤性息肉病 (FAP) 患者的 APC 突变组织中,ALDH+SC 的比例逐渐增加,而 NEC 则明显减少。为了解释这些细胞群体在 FAP 组织中的变化,我们使用数学建模来识别动力学机制。计算分析表明,APC 突变导致:1)ALDH+SCs 向祖代 NEC 的成熟减少(而不是祖代 NEC 向成熟 NEC 的成熟减少);2)成熟 NEC 的反馈信号减少。使用人 CRC 细胞系进行的生物学实验以测试模型预测表明,成熟的 GLP-2R+和 SSTR1+NEC 通过其信号肽产生相反的作用,通过祖代 NEC 的反馈调节来影响 NEC 的成熟率。然而,这种反馈信号的减少并不能解释成熟的延迟,因为在 CRC 中祖代和成熟的 NEC 都被耗尽了。因此,成熟延迟的机制必须解释 APC 突变如何导致 ALDH+SCs 保持不成熟。鉴于 ALDH 是视黄酸 (RA) 信号通路的关键组成部分,RA 通路的其他组成部分选择性地在 ALDH+SCs 中表达,并且外源性 RA 配体可以诱导 ALDH+癌症 SC 成熟为 NEC,因此在 CRC 中,RA 信号必须在 ALDH+SCs 中受到抑制。因此,RA 信号的衰减解释了为什么 APC 突变组织中的 ALDH+SCs 保持不成熟。由于 APC 突变导致 FAP 中的 WNT 信号增加,并且我们发现 APC 在 FAP 患者组织中的顺序失活导致结肠 ALDH+SCs 的成熟逐渐延迟,因此提出了一个假设,即人类 CRC 的发展是由于 WNT 和 RA 信号之间的不平衡。
