Department of Biological Science, Florida State University, Tallahassee, FL, 32306-4295, USA.
Plant J. 2014 Apr;78(2):319-27. doi: 10.1111/tpj.12470. Epub 2014 Mar 26.
Bundle sheath (BS) cells form a single cell layer surrounding the vascular tissue in leaves. In C3 plants, photosynthesis occurs in both the BS and mesophyll cells, but the BS cells are the major sites of photosynthesis in C4 plants, whereas the mesophyll cells are only involved in CO2 fixation. Because C4 plants are more efficient photosynthetically, introduction of the C4 mechanism into C3 plants is considered a key strategy to improve crop yield. One prerequisite for such C3-to-C4 engineering is the ability to manipulate the number and physiology of the BS cells, but the molecular basis of BS cell-fate specification remains unclear. Here we report that mutations in three GRAS family transcription factors, SHORT-ROOT (SHR), SCARECROW (SCR) and SCARECROW-LIKE 23 (SCL23), affect BS cell fate in Arabidopsis thaliana. SCR and SCL23 are expressed specifically in the BS cells and act redundantly in BS cell-fate specification, but their expression pattern and function diverge at later stages of leaf development. Using ChIP-chip experiments and sugar assays, we show that SCR is primarily involved in sugar transport whereas SCL23 functions in mineral transport. SHR is also essential for BS cell-fate specification, but it is expressed in the central vascular tissue. However, the SHR protein moves into the BS cells, where it directly regulates SCR and SCL23 expression. SHR, SCR and SCL23 homologs are present in many plant species, suggesting that this developmental pathway for BS cell-fate specification is likely to be evolutionarily conserved.
束鞘细胞(BS)形成一层围绕叶片维管束组织的细胞。在 C3 植物中,光合作用发生在 BS 和叶肉细胞中,但 BS 细胞是 C4 植物光合作用的主要部位,而叶肉细胞仅参与 CO2 固定。由于 C4 植物光合作用效率更高,因此将 C4 机制引入 C3 植物被认为是提高作物产量的关键策略。这种 C3 到 C4 工程的一个前提条件是能够操纵 BS 细胞的数量和生理学特性,但 BS 细胞命运特化的分子基础仍不清楚。在这里,我们报告三个 GRAS 家族转录因子 SHORT-ROOT(SHR)、SCARECROW(SCR)和 SCARECROW-LIKE 23(SCL23)的突变会影响拟南芥的 BS 细胞命运。SCR 和 SCL23 特异性表达在 BS 细胞中,在 BS 细胞命运特化中发挥冗余作用,但它们的表达模式和功能在叶片发育的后期阶段有所不同。通过 ChIP-chip 实验和糖测定,我们表明 SCR 主要参与糖转运,而 SCL23 则在矿物质转运中起作用。SHR 对于 BS 细胞命运特化也是必不可少的,但它在中央维管束组织中表达。然而,SHR 蛋白进入 BS 细胞,在那里它直接调节 SCR 和 SCL23 的表达。SHR、SCR 和 SCL23 同源物存在于许多植物物种中,这表明 BS 细胞命运特化的这种发育途径可能在进化上是保守的。
