Abstract
Light plays pivotal roles as an important environmental signal in plant growth and development. In Arabidopsis, phototropin 1 (phot1) and 2 (phot2) are the photoreceptors that mediate phototropism, chloroplast relocation, stomatal opening and leaf flattening, in response to blue light. However, little is known about how phototropins transduce the signals after the light is perceived. Changes induced by blue light in terms of intracellular localization patterns of phot2 in Arabidopsis were examined. Phot2 distributed uniformly in the plasma membrane under dark conditions. Upon irradiation with blue light, some of the phot2 associated with the Golgi apparatus. It was also shown that the kinase domain, but not the photosensory domain, is required for a plasma membrane and Golgi localization. Furthermore a kinase fragment, lacking the photosensory domain, constitutively triggered physiological responses in planta. Thus, the plasma membrane and the Golgi apparatus appear to be the most likely sites for the initial step of phot2 signal transduction. The Golgi apparatus facilitates vesicle trafficking and delivery of membrane proteins to the required locations in the cell. Therefore, this study implicates the regulation of vesicle trafficking by the Golgi apparatus as a mechanism by which phot2 elicits its cellular responses.
Key words: Golgi apparatus, kinase, light signal transduction, photoreceptor, phototropin, vesicle trafficking
A range of physiological responses in plants is brought about by blue (390–500 nm) and ultraviolet-A (320–390 nm) light. Phototropin, one of major classes of blue light photoreceptors in plants, mediates responses such as phototropism, chloroplast relocation, light-induced stomatal opening and leaf flattening.1–6 The dicotyledon Arabidopsis, possesses two phototropins, termed phot1 and phot2, which have both overlapping and distinct functions.5,7 Phototropins consist of two functional domains, a N-terminal photosensory domain, containing two LOV (Light, Oxygen, Voltage) domains (LOV1 and LOV2) and a flavin-mononucleotide (FMN) chromophore and a regulatory serine/threonine kinase domain at the C-terminus.8
To understand the mechanism of phototropin signal transduction, we expressed phot2 derivatives with translationally-fused green fluorescent protein (GFP) in a phot1phot2 double mutant in a wild type background in Arabidopsis.9,10 Phototropin is a membrane- associated protein lacking a membrane spanning domain.8 Phot1 fused to GFP (P1G) is mainly localized to the plasma membrane, regardless of the light conditions.6 This property was retained when phot2 was fused to GFP (P2G).9 A part of P2G associates with punctate structures in the cytoplasm in response to blue light. The punctate P2G colocalized with KAM1ΔC:mRFP, a Golgi marker, we therefore conclude that phot2 associated with the Golgi apparatus in a blue light-dependent manner.9 This association was observed even in the presence of brefeldin A (BFA), an inhibitor of the vesicle trafficking.9
To determine which domain of phot2 is responsible for the Golgi association, fragments of phot2 were fused to GFP and expressed in protoplasts.9 The N-terminal fragment fused to GFP (P2NG) was distributed uniformly in the cytoplasm. By contrast, the C-terminal fragment fused to GFP (P2CG) localized to both plasma membrane and punctate structures. The latter was shown to be the Golgi apparatus with the aid of the Golgi marker, KAM1ΔC:mRFP.9 These observations were corroborated from data using transgenic plants.10 Hence the C-terminal kinase domain, but not the N-terminal photo-sensory domain, is essential for the association of phot2 with the plasma membrane and the Golgi apparatus.
The Golgi network is a key player in vesicle trafficking, to and from ER, vacuoles, trans-Golgi network, endosome and the plasma membrane.11 Membrane spanning proteins are delivered and recycled through the Golgi apparatus. Among the membrane spanning proteins that are especially interesting, with respect to phototropin function, are auxin carriers such as PIN proteins. Phototropic curvature, which is under the control of phototropin, is believed to be caused by an uneven distribution of auxin.12 The intracellular distribution of PIN proteins is maintained and regulated by vesicle trafficking.13 Indeed, factors such as ADP-ribosylation factor1 (ARF1) and guanine-nucleotide exchange factors (GEFs), which are involved in vesicle trafficking, are indispensable for the proper distribution of PIN proteins.14–17 It is intriguing that a light stimulus alters the distribution pattern of PIN proteins.18 Hence, a fascinating possibility arises that phot2 alters the intracellular distribution of PIN proteins by regulating vesicle trafficking at the level of the Golgi apparatus.
Phototropins are members of the subfamily VIII of AGC kinases.19 Interestingly, PINOID, another member of the subfamily, is localized at the cell periphery and regulates the apical-basal polar distribution of PIN proteins.20–22 Accordingly, overexpression of PINOID disturbs the auxin distribution in transgenic plants.23,24 The kinase fragment of phototropin exhibits constitutive kinase activity in vitro.25 Interestingly, the auxin distribution is disturbed in plants expressing P2CG, as is the case with PINOID.10 Hence, both PINOID and phot2 might alter the PIN protein distribution in the cell through a common mechanism, in response to distinct stimuli.
To date, no authentic substrate has been described for any of the AGC VIII kinases.19 Considering the localization pattern of phototropins, the substrates are most likely to reside in the plasma membrane and/or the Golgi apparatus. NPH3, RPT2 and PKS1 are downstream factors for phototropic responses,26–28 all associating with the plasma membrane. Although they interact preferentially with the N-terminal rather than the C-terminal domain of phot1,26,29 it is also possible that the C-terminal kinase domain interacts transiently with these factors leading to their phosphorylation. However, at present the molecular functions of NPH3, RPT2 and PKS1 remain unclear and await future investigation.
Although both phot1 and phot2 are localized to the plasma membrane, punctate structures are yet to be described for P1G. Instead, a part of phot1-GFP is released from the plasma membrane to the cytosol in response to a light stimulus.6 We recently reexamined the intracellular localization of P1G. A specific network-like structure in the cytoplasm in addition to intense plasma membrane staining was observed (Fig. 1). A similar pattern was observed for P2G although it is less clear.9 Hence, both phot1 and phot2 might be associating with a structure in the cytoplasm that has yet to be described, and which might be another site of phototropin signaling in the cell.
Figure 1.
A light-induced network-like distribution pattern of P1G in the cytoplasm. The P1G seedlings grown under dark conditions6 were incubated in MS solution (diluted 50%) without (upper panels) or with (lower panels) 100 µM BFA. The cells were inspected with a confocal laser scanning microscope. Images taken before (left) or after (right) blue light illumination at 48 µmol m−2 sec−1 are shown. Bar = 10 µm.
P2CG elicits some phototropin responses without a light stimulus.10 That is, chloroplasts were in the avoidance position and stomata opened without a blue light stimulus in the P2CG overexpressing plants. It is a fascinating possibility that phototropin elicits those responses through the regulation of vesicle trafficking, although other possibilities exist. Stomata open as the result of phosphorylation of the plasma membrane H+-ATPase30 and it is unlikely that the vesicle trafficking is directly involved in this regulatory process. It is possible to conjecture that vesicle trafficking affects chloroplast positioning but how this would work remains to be determined. Overall how a single photoreceptor such as phototoropin might regulate diverse physiological responses awaits future study.
Acknowledgements
This work was partially supported by a Grant-in-Aid for Scientific Research (B) 17370018 (to A.N.), a Grand-in-Aid for Research on Priority Areas 17084002 (to A.N.). S.-G.K. was supported by the postdoctoral research fellowship from the Japan Society for the Promotion of Science for foreign researchers (P06181).
Abbreviations
- ARF1
ADP-ribosylation factor1
- BFA
brefeldin A
- FMN
flavin-mononucleotide
- GEF
guanine-nucleotide exchange factor
- GFP
green fluorescent protein
- LOV
light, oxygen, voltage
- P2CG
phot2 C-terminal fragment fused to GFP
- P1G
full-length phot1 fused to GFP
- P2G
full-length phot2 fused to GFP
- P2NG
phot2 N-terminal fragment fused to GFP
- Phot1
phototropin 1
- Phot2
phototropin 2
Footnotes
Previously published online as a Plant Signaling & Behavior E-publication: www.landesbioscience.com/journals/psb/article/5239
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