Cytokinin regulates multiple biological processes in plants [
1,
2,
3] Among the different cytokinin types, trans-zeatin (tZ-type) and isopentenyladenine (iP-type) are primarily synthesized in roots and shoots, respectively [
4]. The shoot transport of the tZ-type is necessary for normal shoot development. ATP-binding cassette subfamily G (ABCG) are localized in the plasma membrane of vascular tissue and mobilize cytokinins at local and systemic levels [
5,
6,
7,
8]. ABCG proteins have been characterized as long-distance apoplastic cytokinin transporters in plants [
4,
6,
8,
9]. Mutants of ABCG in Arabidopsis (
atabcg14) and rice (
osabcg18) display a retarded shoot development phenotype, which is restored by exogenous tZ application [
6]. Similarly,
osabcg18 and
Medicago truncatula, mtabcg56 mutants exhibit reduced grain yield and defective symbiosis, respectively. Therefore, ABCG has emerged as a cytokinin carrier that controls diverse functions such as shoot development, symbiosis, and grain yield [
4,
5]. Until recently, the role of ABCG transporters in xylem loading and the shoot transport of cytokinin has been investigated, but information on distribution to the leaves and other aerial parts remains elusive.
Recent work by Zhao et al. (2021) showed the role of AtABCG14 in the phloem unloading of root-synthesized cytokinin and its effect on shoot phenotypes. For a preliminary assessment of ABCG14 expression in Arabidopsis shoot and root, the authors performed promoter analyses (ABCG14pro:GUS/GFP) with GUS and GFP reporters. The expression pattern of ABCG14pro:GUS/GFP in young leaves overlapped with phloem companion cell (PCC)-specific and xylem-specific promoter expression, indicating AtABCG14 localization in PCC and xylem parenchyma cells. Further, AtABCG14 expression was observed in the minor veins of young leaves and only in the margins of old leaves. Enhanced AtABCG14 caused the accumulation of the tZ-type cytokinin in young leaves compared to mature leaves.
The contrasting leaf expression of AtABCG14 prompted authors to decipher the role of AtABCG14 in the shoot. A reciprocal micro-grafting experiment using the wild-type (WT) and mutant atabcg14, i.e., WT scion and atabcg14 rootstock (WT/atabcg14) or atabcg14 scion and WT rootstock (atabcg14/WT), revealed smaller shoots in heterografts than WT/WT. A reduction in the diameter of rosette leaves, the number of siliques, and shoot apical meristem activity was also observed in the order of atabcg14/atabcg14 > atabcg14/WT > WT/atabcg14, compared to WT/WT. These parameters were more restored in WT/atabcg14 versus atabcg14/WT, suggesting the importance of the aerial expression of AtABCG14 for shoot growth.
Moreover, cytokinin-responsive Arabidopsis Response Regulator 5 promoter-driven GUS/GFP expression in homo- and heterografts correlated shoot AtABCG14 expression and cytokinin distribution in the aerial tissues. The WT/atabcg14 displayed significantly high GFP and GUS expression in the leaves or inflorescences, whereas atabcg14/WT exhibited low expression. In addition, cytokinin-responsive gene expression was also high in WT/atabcg14 compared to the atabcg14/WT shoot. Thus, shoot cytokinin signaling recovered substantially in WT/atabcg14 and slightly in atabcg14/WT compared to WT/WT. Limited shoot cytokinin signaling in atabcg14/WT indicated that shoot AtABCG14 expression is indispensable for root-to-shoot cytokinin transport and signaling.
Furthermore, the movement of root-synthesized cytokinins to the shoot was tracked by feeding the root with 14C-labeled tZ and 2H-labeled tZ. The transport of 14C-tZ or 2H5-tZ to the shoot was suppressed in
atabcg14/
atabcg14, fully rescued in
atabcg14/WT, and partially rescued in WT/
atabcg14. Root
AtABCG14 restored shootward tZ transport in
atabcg14/WT; however, cytokinin signaling and growth were hampered. Additionally, tZ expression spread from the petiole–midrib to the lamina in WT/WT. In contrast, in
atabcg14/WT, its expression was primarily observed in the petiole–midrib, indicating impaired cytokinin distribution from the veins to the lamina of
atabcg14/WT. Further, cytokinins’ presence was high in the apoplast of WT/WT and WT/
atabcg14 and low in
atabcg14/
atabcg14 and
atabcg14/WT. However, the phloem sap of
atabcg14/WT retained much higher tZ-type compared to others. Thus, root-synthesized cytokinin reached the shoot, but aerial-tissue disruption of AtABCG14 disturbed phloem unloading and translocation to the lamina (
Figure 1). Hence, AtABCG14 plays a pivotal role in shoot cytokinin distribution. The authors proved that under dysfunctional shoot AtABCG14 expression in
atabcg14/WT, cytokinin is not distributed in the leaves and is in retrograde from shoot to root. This finding validates that
AtABCG14 expression in PCCs is associated with root-synthesized cytokinin efflux phloem unloading to the apoplast.
The authors used a mutant complementation assay to define the role of the AtABCG14 gene. AtABCG14 expression using a PCC-specific promoter complemented the atabcg14 mutant and rescued the apoplastic cytokinin levels and defective phenotypes; however, xylem-specific promoter expression was not successful in mutant complementation. These results, in summary, prove that AtABCG14 expression in the shoot is required for the distribution of cytokinin in all aboveground plant parts.
The short- and/or long-distance transport of cytokinin governs plant growth, development, and biotic–abiotic stress responses. The elucidation of cytokinin transport and the signaling nexus has substantially provided deep insights into cytokinin’s physiological roles [
9]. The authors utilized grafting experiments between the mutant and WT and isotope-labeled tZ feeding, followed by the profiling of phloem and apoplastic extract and mutant complementation studies, to determine that
AtABCG14 coordinates the root loading and shoot distribution of root-synthesized cytokinins (
Figure 1). Cytokinin transport from root to shoot and translocation determines the developmental fate of different plant tissues. Thus, the spatio-temporal expression of cytokinin signaling in the root and shoot determines the balance between cell division, elongation, and differentiation. This reprograms molecular machinery and optimizes transcriptional dynamics to favor proper organogenesis, as in shoot-and-root nodule development and enhanced grain yield [
2,
4,
5,
8]. Thus, the ABCG protein subfamily can be targeted as a potential genetic engineering candidate for regulating the spatio-temporal distribution and signaling of cytokinin to enhance stress tolerance, with better plant phenotypes and enhanced yields.