Wegner Lars H, Li Xuewen, Zhang Jie, Yu Min, Shabala Sergey, Hao Zhifeng
International Research Centre for Environmental Membrane Biology, Foshan University, Foshan, 528041, China.
Tasmanian Institute of Agricultural Research, University of Tasmania, Hobart, 7001, Australia.
New Phytol. 2021 Apr;230(2):408-415. doi: 10.1111/nph.17176. Epub 2021 Mar 11.
P-type H ATPases mediate active H efflux from plant cells. They generate a proton motive force across the plasma membrane, providing the free energy to drive the transport of other solutes, partly by coupling to H influx. Wegner & Shabala (2020) recently suggested that passive H influx can exceed pump-driven efflux due to 'active buffering', that is, cytosolic H scavenging and apoplastic H generation by metabolism ('biochemical pH clamp'). Charge balance is provided by K efflux or anion influx. Here, this hypothesis is extended to net H efflux: even though H pumping is faster than backflow via symporters and antiporters, a progressive increase in the transmembrane pH gradient is avoided. Cytosolic H release is associated with bicarbonate formation from CO . Bicarbonate serves as substrate for the PEPCase, catalyzing the reaction from phosphoenolpyruvate to oxaloacetate, which is subsequently reduced to malate. Organic anions such as malate and citrate are released across the plasma membrane and are (partly) protonated in the apoplast, thus limiting pump-induced acidification. Moreover, a 'biophysical pH clamp' is introduced, that is, adjustment of apoplastic/cytosolic pH involving net H fluxes across the plasma membrane, while the gradient between compartments is maintained. The clamps are not mutually exclusive but are likely to coexist.
P型H⁺-ATP酶介导植物细胞中H⁺的主动外流。它们在质膜上产生质子动力,提供自由能以驱动其他溶质的转运,部分是通过与H⁺内流偶联来实现的。韦格纳和沙巴拉(2020年)最近提出,由于“主动缓冲”,即胞质H⁺清除和代谢产生质外体H⁺(“生化pH钳制”),被动H⁺内流可能超过泵驱动的外流。电荷平衡由K⁺外流或阴离子内流提供。在此,这一假设扩展到净H⁺外流:即使H⁺泵出比通过同向转运体和反向转运体的回流更快,也能避免跨膜pH梯度的逐渐增加。胞质H⁺释放与CO₂形成碳酸氢根有关。碳酸氢根作为磷酸烯醇式丙酮酸羧化酶的底物,催化磷酸烯醇式丙酮酸到草酰乙酸的反应,随后草酰乙酸被还原为苹果酸。苹果酸和柠檬酸等有机阴离子通过质膜释放,并在质外体中(部分)质子化,从而限制泵诱导的酸化。此外,引入了“生物物理pH钳制”,即涉及跨质膜净H⁺通量的质外体/胞质pH调节,同时保持各隔室之间的梯度。这些钳制并非相互排斥,而是可能共存。
