A larval zebrafish model of cardiac physiological recovery following cardiac arrest and myocardial hypoxic damage.

IF 1.8 4区 生物学 Q3 BIOLOGY Biology Open Pub Date : 2024-09-15 Epub Date: 2024-09-12 DOI:10.1242/bio.060230
Warren Burggren, Regina Abramova, Naim M Bautista, Regina Fritsche Danielson, Ben Dubansky, Avi Gupta, Kenny Hansson, Neha Iyer, Pudur Jagadeeswaran, Karin Jennbacken, Katarina Rydén-Markinhutha, Vishal Patel, Revathi Raman, Hersh Trivedi, Karem Vazquez Roman, Steven Williams, Qing-Dong Wang
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Abstract

Contemporary cardiac injury models in zebrafish larvae include cryoinjury, laser ablation, pharmacological treatment and cardiac dysfunction mutations. Although effective in damaging cardiomyocytes, these models lack the important element of myocardial hypoxia, which induces critical molecular cascades within cardiac muscle. We have developed a novel, tractable, high throughput in vivo model of hypoxia-induced cardiac damage that can subsequently be used in screening cardioactive drugs and testing recovery therapies. Our potentially more realistic model for studying cardiac arrest and recovery involves larval zebrafish (Danio rerio) acutely exposed to severe hypoxia (PO2=5-7 mmHg). Such exposure induces loss of mobility quickly followed by cardiac arrest occurring within 120 min in 5 days post fertilization (dpf) and within 40 min at 10 dpf. Approximately 90% of 5 dpf larvae survive acute hypoxic exposure, but survival fell to 30% by 10 dpf. Upon return to air-saturated water, only a subset of larvae resumed heartbeat, occurring within 4 min (5 dpf) and 6-8 min (8-10 dpf). Heart rate, stroke volume and cardiac output in control larvae before hypoxic exposure were 188±5 bpm, 0.20±0.001 nL and 35.5±2.2 nL/min (n=35), respectively. After briefly falling to zero upon severe hypoxic exposure, heart rate returned to control values by 24 h of recovery. However, reflecting the severe cardiac damage induced by the hypoxic episode, stroke volume and cardiac output remained depressed by ∼50% from control values at 24 h of recovery, and full restoration of cardiac function ultimately required 72 h post-cardiac arrest. Immunohistological staining showed co-localization of Troponin C (identifying cardiomyocytes) and Capase-3 (identifying cellular apoptosis). As an alternative to models employing mechanical or pharmacological damage to the developing myocardium, the highly reproducible cardiac effects of acute hypoxia-induced cardiac arrest in the larval zebrafish represent an alternative, potentially more realistic model that mimics the cellular and molecular consequences of an infarction for studying cardiac tissue hypoxia injury and recovery of function.

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心脏停搏和心肌缺氧损伤后心脏生理恢复的幼体斑马鱼模型。
现代斑马鱼幼体心脏损伤模型包括冷冻损伤、激光消融、药物治疗和心脏功能障碍突变。这些模型虽然能有效损伤心肌细胞,但缺乏心肌缺氧这一重要因素,而心肌缺氧会诱导心肌内的关键分子级联。我们开发了一种新型、可控、高通量的缺氧诱导心脏损伤体内模型,随后可用于筛选心肌活性药物和测试恢复疗法。我们研究心脏骤停和恢复的模型可能更符合实际情况,即幼体斑马鱼(Danio rerio)急性暴露于严重缺氧(PO2=5-7 mmHg)环境中。在受精后 5 dpf 的 120 分钟内和 10 dpf 的 40 分钟内,这种暴露会导致斑马鱼迅速丧失活动能力,随后心脏骤停。大约 90% 的 5 dpf 幼虫在急性缺氧暴露中存活下来,但到 10 dpf 存活率下降到 30%。回到空气饱和的水中后,只有一部分幼虫恢复心跳,分别在4分钟(5 dpf)和6-8分钟(8-10 dpf)内发生。缺氧前对照组幼虫的心率、每搏量和心输出量分别为188±5 bpm、0.20±0.001 nL和35.5±2.2 nL/min(n=35)。在严重缺氧暴露后,心率短暂降至零,但在恢复 24 小时后又恢复到控制值。然而,由于缺氧引起了严重的心脏损伤,恢复 24 小时后,每搏量和心输出量仍比对照值低 50%,心脏功能的完全恢复最终需要心脏停搏后 72 小时。免疫组织学染色显示肌钙蛋白 C(识别心肌细胞)和 Capase-3(识别细胞凋亡)共定位。作为对发育中的心肌进行机械或药物损伤的模型的替代方案,斑马鱼幼体急性缺氧诱导心脏停搏对心脏的影响具有高度的可重复性,它是一种替代方案,有可能成为研究心肌组织缺氧损伤和功能恢复的更真实的模型,它模拟了心肌梗死的细胞和分子后果。
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来源期刊
Biology Open
Biology Open BIOLOGY-
CiteScore
3.90
自引率
0.00%
发文量
162
审稿时长
8 weeks
期刊介绍: Biology Open (BiO) is an online Open Access journal that publishes peer-reviewed original research across all aspects of the biological sciences. BiO aims to provide rapid publication for scientifically sound observations and valid conclusions, without a requirement for perceived impact.
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