Vaughn Matthew W, Harrington Gregory N, Bush Daniel R
Program in Physiological and Molecular Plant Biology, University of Illinois at Urbana-Champaign, Urbana IL, 61801, USA.
Proc Natl Acad Sci U S A. 2002 Aug 6;99(16):10876-80. doi: 10.1073/pnas.172198599. Epub 2002 Jul 29.
A proton-sucrose symporter mediates the key step in carbon export from leaves of most plants. Sucrose transport activity and steady-state mRNA levels of BvSUT1, a sugar beet leaf sucrose symporter, are negatively regulated specifically by sucrose. Results reported here show that BvSUT1 mRNA was localized to companion cells of the leaf's vascular system, which supports its role in the systemic distribution of photoassimilate. Immunoblot analysis showed that decreased transport activity was caused by a reduction in the abundance of symporter protein. RNA gel blot analysis of the leaf symporter revealed that message levels also declined, and nuclear run-on experiments demonstrated that this was the result of decreased transcription. Further analysis showed that symporter protein and message are both degraded rapidly. Taken together, these data show that phloem loading is regulated by means of sucrose-mediated changes in transcription of a phloem-specific sucrose symporter gene in a regulatory system that may play a pivotal role in balancing photosynthetic activity with resource utilization.
质子-蔗糖同向转运体介导了大多数植物叶片中碳输出的关键步骤。甜菜叶片蔗糖同向转运体BvSUT1的蔗糖转运活性和稳态mRNA水平受到蔗糖的特异性负调控。本文报道的结果表明,BvSUT1 mRNA定位于叶片维管系统的伴胞中,这支持了其在光合产物系统分布中的作用。免疫印迹分析表明,转运活性的降低是由于同向转运体蛋白丰度的降低所致。对叶片同向转运体的RNA凝胶印迹分析显示,mRNA水平也下降,核转录实验表明这是转录减少的结果。进一步分析表明,同向转运体蛋白和mRNA均迅速降解。综上所述,这些数据表明,韧皮部装载是通过蔗糖介导的韧皮部特异性蔗糖同向转运体基因转录变化来调节的,该调节系统可能在平衡光合活性与资源利用方面发挥关键作用。