Burg Leonard, Yoon Heeyong, Peng Min, Germano Peter, Reesey Gretzmacher Emily, Xiao Rui, Anderson Vernon E, Nakamaru-Ogiso Eiko, Falk Marni J
Mitochondrial Medicine Frontier Program, Division of Human Genetics, Department of Pediatrics, The Children's Hospital of Philadelphia, Philadelphia, PA, United States.
Cyclerion Therapeutics, Cambridge, MA, United States.
Front Pharmacol. 2025 Jul 25;16:1588426. doi: 10.3389/fphar.2025.1588426. eCollection 2025.
Zagociguat (zag) is a CNS-penetrant, soluble guanylate cyclase (sGC) stimulator that has been evaluated in phase 2a, with phase 2b ongoing, clinical studies of primary mitochondrial disease (PMD) subjects with mitochondrial encephalomyopathy, lactic acidosis, and stroke-like episodes syndrome (MELAS). To explore its utility in a broader array of PMDs and secondary mitochondrial disorders, we performed prfeclinical modeling of zag across larval and adult zebrafish models with biochemical deficiencies in diverse respiratory chain (RC) complexes or dihydrolipoamide dehydrogenase (Dldh).
Zag was evaluated for tissue uptake, gross toxicity, protection from RC toxin-induced brain death, neuromuscular dysfunction, heartbeat loss, and biochemical dysfunction in transgenic or toxin-exposed zebrafish with mitochondrial enzyme deficiencies in complex I ( or rotenone-exposed wild type (WT)), complex IV ( or azide-exposed WT), multiple RC complexes ( ), or pyruvate dehydrogenase complex ( ). Zag effects were also studied on the whole-body oxygen consumption capacity (MO) and swimming activity of WT and complex IV disease adult zebrafish.
Similar zag levels were observed in adult brains and tail muscle. No morphological or functional toxic effects of zag were observed on larvae viability. Zag provided neuromuscular protection in complex I deficient genetic and pharmacologic inhibitor models. In complex IV deficient models, prevention from brain death occurred at 100 nM zag in high-dose azide-exposed WT larvae; however, no rescue of swimming or neuromuscular phenotypes in low-dose azide-exposed larvae was observed. A total of 100 nM zag rescued MO and maximum swimming speed in adult zebrafish. Larval swimming activity was also preserved with 10 nM zag treatment in azide-stressed larvae but not at 10 nM, 100 nM, or 1 µM zag in larvae. Zag (10 nM) enhanced complex I enzyme activity that is suggestive of mitochondrial biogenesis and key aspects of mitochondrial physiology in azide-exposed and larvae.
Preclinical evaluation of zag demonstrated its safety, significant protection of neuromuscular dysfunction and/or acute RC stressor-induced decompensation, and improved mitochondrial physiology across multiple different genetic and/or pharmacologic models of RC-deficient PMD. Thus, zag may yield therapeutic potential for an array of diseases with mitochondrial dysfunction beyond MELAS, potentially including Leigh syndrome spectrum disorder and primary mitochondrial myopathies.
扎戈西呱(zag)是一种可穿透中枢神经系统的可溶性鸟苷酸环化酶(sGC)刺激剂,已在2a期进行了评估,2b期临床试验正在进行,该试验针对患有线粒体脑肌病、乳酸酸中毒和卒中样发作综合征(MELAS)的原发性线粒体疾病(PMD)患者。为了探索其在更广泛的PMD和继发性线粒体疾病中的应用,我们在幼虫和成年斑马鱼模型中对zag进行了临床前建模,这些模型在不同的呼吸链(RC)复合物或二氢硫辛酰胺脱氢酶(Dldh)中存在生化缺陷。
在具有线粒体酶缺陷的转基因或毒素暴露斑马鱼中,评估zag的组织摄取、总体毒性、对RC毒素诱导的脑死亡、神经肌肉功能障碍、心跳丧失和生化功能障碍的保护作用,这些斑马鱼的线粒体酶缺陷分别存在于复合物I(或鱼藤酮暴露的野生型(WT))、复合物IV(或叠氮化物暴露的WT)、多个RC复合物( )或丙酮酸脱氢酶复合物( )中。还研究了zag对WT和复合物IV疾病成年斑马鱼的全身耗氧能力(MO)和游泳活动的影响。
在成年大脑和尾肌中观察到相似的zag水平。未观察到zag对幼虫活力有形态或功能毒性作用。zag在复合物I缺陷的遗传和药理抑制剂模型中提供了神经肌肉保护。在复合物IV缺陷模型中,在高剂量叠氮化物暴露的WT幼虫中,100 nM的zag可预防脑死亡;然而,在低剂量叠氮化物暴露的 幼虫中,未观察到游泳或神经肌肉表型的挽救。总共100 nM的zag可挽救成年 斑马鱼的MO和最大游泳速度。在叠氮化物应激的 幼虫中,10 nM的zag处理可保留幼虫的游泳活动,但在 幼虫中,10 nM、100 nM或1 μM的zag则不能。zag(10 nM)增强了复合物I酶活性,这提示了在叠氮化物暴露的 和 幼虫中线粒体生物发生和线粒体生理学的关键方面。
zag的临床前评估证明了其安全性、对神经肌肉功能障碍和/或急性RC应激源诱导的失代偿的显著保护作用,以及在多种不同的RC缺陷型PMD遗传和/或药理模型中改善线粒体生理学。因此,zag可能对除MELAS之外的一系列线粒体功能障碍疾病具有治疗潜力,可能包括Leigh综合征谱系障碍和原发性线粒体肌病。
