Richards Mark, Lomas Oliver, Jalink Kees, Ford Kerrie L, Vaughan-Jones Richard D, Lefkimmiatis Konstantinos, Swietach Pawel
Burdon Sanderson Cardiac Science Centre, Department of Physiology, Anatomy and Genetics, Parks Road, Oxford OX1 3PT, UK.
Division of Cell Biology, Netherlands Cancer Institute, 1066 CX Amsterdam, Netherlands.
Cardiovasc Res. 2016 Jun 1;110(3):395-407. doi: 10.1093/cvr/cvw080. Epub 2016 Apr 18.
3',5'-Cyclic adenosine monophosphate (cAMP) signals in the heart are often confined to concentration microdomains shaped by cAMP diffusion and enzymatic degradation. While the importance of phosphodiesterases (degradative enzymes) in sculpting cAMP microdomains is well established in cardiomyocytes, less is known about cAMP diffusivity (DcAMP) and factors affecting it. Many earlier studies have reported fast diffusivity, which argues against sharply defined microdomains.
[cAMP] dynamics in the cytoplasm of adult rat ventricular myocytes were imaged using a fourth generation genetically encoded FRET-based sensor. The [cAMP]-response to the addition and removal of isoproterenol (β-adrenoceptor agonist) quantified the rates of cAMP synthesis and degradation. To obtain a read out of DcAMP, a stable [cAMP] gradient was generated using a microfluidic device which delivered agonist to one half of the myocyte only. After accounting for phosphodiesterase activity, DcAMP was calculated to be 32 µm(2)/s; an order of magnitude lower than in water. Diffusivity was independent of the amount of cAMP produced. Saturating cAMP-binding sites with the analogue 6-Bnz-cAMP did not accelerate DcAMP, arguing against a role of buffering in restricting cAMP mobility. cAMP diffused at a comparable rate to chemically unrelated but similar sized molecules, arguing for a common physical cause of restricted diffusivity. Lower mitochondrial density and order in neonatal cardiac myocytes allowed for faster diffusion, demonstrating the importance of mitochondria as physical barriers to cAMP mobility.
In adult cardiac myocytes, tortuosity due to physical barriers, notably mitochondria, restricts cAMP diffusion to levels that are more compatible with microdomain signalling.
心脏中的3',5'-环磷酸腺苷(cAMP)信号通常局限于由cAMP扩散和酶促降解形成的浓度微区。虽然磷酸二酯酶(降解酶)在塑造cAMP微区中的重要性在心肌细胞中已得到充分证实,但关于cAMP扩散率(DcAMP)及其影响因素的了解较少。许多早期研究报道了快速扩散率,这与明确界定的微区观点相悖。
使用基于荧光共振能量转移(FRET)的第四代基因编码传感器对成年大鼠心室肌细胞质中的[cAMP]动态进行成像。添加和去除异丙肾上腺素(β-肾上腺素能受体激动剂)后的[cAMP]反应量化了cAMP的合成和降解速率。为了获得DcAMP的读数,使用微流控装置在心肌细胞的一半区域仅递送激动剂,从而产生稳定的[cAMP]梯度。在考虑磷酸二酯酶活性后,计算得出DcAMP为32 µm(2)/s;比在水中低一个数量级。扩散率与产生的cAMP量无关。用类似物6-Bnz-cAMP饱和cAMP结合位点并不会加速DcAMP,这表明缓冲作用在限制cAMP移动性方面不起作用。cAMP的扩散速率与化学性质无关但大小相似的分子相当,这表明存在限制扩散的共同物理原因。新生心肌细胞中线粒体密度和有序性较低,使得扩散更快,这证明了线粒体作为cAMP移动性物理屏障的重要性。
在成年心肌细胞中,由物理屏障(尤其是线粒体)导致的曲折度限制了cAMP扩散,使其达到与微区信号传导更相符的水平。
