老龄刺鼠(Acomys cahirinus)的耳部伤口再生延迟且在空间上存在异质性。

IF 1.8 4区 生物学 Q3 BIOLOGY Biology Open Pub Date : 2024-07-15 Epub Date: 2024-10-10 DOI:10.1242/bio.060565
Justin A Varholick, Jazmine Thermolice, Gizelle Godinez, Vanessa Dos Santos, Rishi Kondapaneni, Malcolm Maden
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引用次数: 0

摘要

非洲刺鼠(Acomys cahirinus)是一种独特的哺乳动物组织再生模型,其4毫米耳孔打孔可再生软骨、脂肪细胞、毛囊和肌肉。然而,耳组织再生的时间从 20 天到 90 天不等,肌肉再生的时间也不一致。一些报告称,老龄刺小鼠再生延迟,但未对肌肉的再生能力进行调查。我们认为,再生延迟和肌肉再生不一致可能与年龄相关的神经退化有关。目前的研究发现,与 3-4 个月大的棘皮小鼠相比,6-9 个月大的棘皮小鼠再生延迟,但肌肉再生能力与年龄无关,而且几乎没有证据表明存在与年龄相关的神经变性。相反,肌肉、软骨和脂肪细胞的再生在空间上是异质性的,再生组织的数量从近端向远端递减。此外,与 3-4 个月大的金丝猴相比,≥22 个月大的金丝猴远端软骨再生减少,6 个月以上的金丝猴脂肪细胞再生减少。虽然再生延迟和空间异质性的潜在机制仍不清楚,但在刺鼠实验设计中应考虑年龄和再生组织的空间区域。
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Older spiny mice (Acomys cahirinus) have delayed and spatially heterogenous ear wound regeneration.

The African spiny mouse (Acomys cahirinus) is a unique mammalian model of tissue regeneration, regenerating 4 mm ear-hole punches with cartilage, adipocytes, hair follicles, and muscle. However, the time to regenerate ear tissue varies from 20 to 90 days and muscle regeneration is inconsistent. Some report that older spiny mice have delayed regeneration without investigation on the regenerative capacity of muscle. We thought that delayed regeneration and inconsistent muscle regeneration could be linked via age-related nerve degeneration. While the current study found that spiny mice aged 6-9 months had delayed regeneration compared to 3-4 month-old spiny mice, the capacity of muscle regeneration was unrelated to age, and there was little evidence for age-related nerve degeneration. Instead, the regeneration of muscle, cartilage and adipocytes was spatially heterogeneous, declining in amount from the proximal to distal region of the regenerated tissue. Also, cartilage regeneration in the distal region was decreased in ≥22-month-old Acomys and adipocyte regeneration was decreased in those older than 6 months, compared to 3-4 month olds. While the underlying mechanisms for delayed and spatially heterogenous regeneration remain unclear, age and the spatial region of the regenerated tissue should be considered in experimental designs with spiny mice.

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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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