Shovlin Stephen, Delepine Chloe, Swanson Lindsay, Bach Snow, Sahin Mustafa, Sur Mriganka, Kaufmann Walter E, Tropea Daniela
Neuropsychiatric Genetics, Trinity Center for Health Sciences, Trinity Translational Medicine Institute, St James Hospital, Dublin, Ireland.
Department of Brain and Cognitive Sciences, Simons Center for the Social Brain, Picower Institute for Learning and Memory, MIT, Cambridge, MA, United States.
Front Neurosci. 2022 May 31;16:868008. doi: 10.3389/fnins.2022.868008. eCollection 2022.
Rett syndrome (RTT) is a devastating neurodevelopmental disorder without effective treatments. Attempts at developing targetted therapies have been relatively unsuccessful, at least in part, because the genotypical and phenotypical variability of the disorder. Therefore, identification of biomarkers of response and patients' stratification are high priorities. Administration of Insulin-like Growth Factor 1 (IGF-1) and related compounds leads to significant reversal of RTT-like symptoms in preclinical mouse models. However, improvements in corresponding clinical trials have not been consistent. A 20-weeks phase I open label trial of mecasermin (recombinant human IGF-1) in children with RTT demonstrated significant improvements in breathing phenotypes. However, a subsequent randomised controlled phase II trial did not show significant improvements in primary outcomes although two secondary clinical endpoints showed positive changes. To identify molecular biomarkers of response and surrogate endpoints, we used RNA sequencing to measure differential gene expression in whole blood samples of participants in the abovementioned phase I mecasermin trial. When all participants ( = 9) were analysed, gene expression was unchanged during the study (baseline vs. end of treatment, T0-T3). However, when participants were subclassified in terms of breathing phenotype improvement, specifically by their plethysmography-based apnoea index, individuals with moderate-severe apnoea and breathing improvement (Responder group) displayed significantly different transcript profiles compared to the other participants in the study (Mecasermin Study Reference group, MSR). Many of the differentially expressed genes are involved in the regulation of cell cycle processes and immune responses, as well as in IGF-1 signalling and breathing regulation. While the Responder group showed limited gene expression changes in response to mecasermin, the MSR group displayed marked differences in the expression of genes associated with inflammatory processes (e.g., neutrophil activation, complement activation) throughout the trial. Our analyses revealed gene expression profiles associated with severe breathing phenotype and its improvement after mecasermin administration in RTT, and suggest that inflammatory/immune pathways and IGF-1 signalling contribute to treatment response. Overall, these data support the notion that transcript profiles have potential as biomarkers of response to IGF-1 and related compounds.
雷特综合征(RTT)是一种严重的神经发育障碍,目前尚无有效治疗方法。开发靶向治疗的尝试相对不太成功,至少部分原因是该疾病的基因型和表型存在变异性。因此,确定反应生物标志物和患者分层是当务之急。在临床前小鼠模型中,给予胰岛素样生长因子1(IGF-1)及相关化合物可使类似RTT的症状得到显著逆转。然而,相应临床试验的改善并不一致。一项针对RTT儿童的美卡舍明(重组人IGF-1)为期20周的I期开放标签试验表明,呼吸表型有显著改善。然而,随后的随机对照II期试验并未显示主要结局有显著改善,尽管两个次要临床终点显示出积极变化。为了确定反应的分子生物标志物和替代终点,我们使用RNA测序来测量上述美卡舍明I期试验参与者全血样本中的差异基因表达。对所有参与者(n = 9)进行分析时,研究期间基因表达未发生变化(基线与治疗结束时,T0-T3)。然而,当根据呼吸表型改善情况对参与者进行亚分类时,特别是根据基于体积描记法的呼吸暂停指数,与研究中的其他参与者(美卡舍明研究参考组,MSR)相比,中度至重度呼吸暂停且呼吸改善的个体(反应者组)显示出明显不同的转录谱。许多差异表达基因参与细胞周期进程和免疫反应的调节,以及IGF-1信号传导和呼吸调节。虽然反应者组对美卡舍明的反应显示出有限的基因表达变化,但MSR组在整个试验中与炎症过程相关基因(如中性粒细胞活化、补体活化)的表达存在显著差异。我们的分析揭示了与严重呼吸表型及其在RTT中给予美卡舍明后改善相关的基因表达谱,并表明炎症/免疫途径和IGF-1信号传导有助于治疗反应。总体而言,这些数据支持转录谱有潜力作为对IGF-1及相关化合物反应的生物标志物这一观点。
