K+ channel interactions detected by a genetic system optimized for systematic studies of membrane protein interactions

Organization of proteins into complexes is crucial for many cellular functions. However, most proteomic approaches primarily detect protein interactions for soluble proteins but are less suitable for membrane-associated complexes. Here we describe a mating-based split ubiquitin system (mbSUS) for systematic identification of interactions between membrane proteins as well as between membrane and soluble proteins. mbSUS allows in vivo cloning of PCR products into a vector set, detection of interactions via mating, regulated expression of baits, and improved selection of interacting proteins. Cloning is simplified by introduction of lambda attachment sites for GATEWAY. Homo- and heteromeric interactions between Arabidopsis K(+) channels KAT1, AKT1, and AKT2 were identified. Tests with deletion mutants demonstrate that the C terminus of KAT1 and AKT1 is necessary for physical assembly of complexes. Screening of a sorted collection of 84 plant proteins with K(+) channels as bait revealed differences in oligomerization between KAT1, AKT1, and AtKC1, and allowed detection of putative interacting partners of KAT1 and AtKC1. These results show that mbSUS is suited for systematic analysis of membrane protein interactions.     

The RNA-binding proteins HYL1 and SE promote accurate in vitro processing of pri-miRNA by DCL1

The results of genetic studies in Arabidopsis indicate that three proteins, the RNase III DICER-Like1 (DCL1), the dsRNA-binding protein HYPONASTIC LEAVES1 (HYL1), and the C2H2 Zn-finger protein SERRATE (SE), are required for the accurate processing of microRNA (miRNA) precursors in the plant cell nucleus. To elucidate the biochemical mechanism of miRNA processing, we developed an in vitro miRNA processing assay using purified recombinant proteins. We find that DCL1 alone releases 21-nt short RNAs from dsRNA as well as synthetic miR167b precursor RNAs. However, correctly processed miRNAs constitute a minority of the cleavage products. We show that recombinant HYL1 and SE proteins accelerate the rate of DCL1-mediated cleavage of pre- and pri-miR167b substrates and promote accurate processing.     

Qa-SNAREs localized to the trans-Golgi network regulate multiple transport pathways and extracellular disease resistance in plants

In all eukaryotic cells, a membrane-trafficking system connects the post-Golgi organelles, such as the trans-Golgi network (TGN), endosomes, vacuoles, and the plasma membrane. This complex network plays critical roles in several higher-order functions in multicellular organisms. The TGN, one of the important organelles for protein transport in the post-Golgi network, functions as a sorting station, where cargo proteins are directed to the appropriate post-Golgi compartments. Unlike its roles in animal and yeast cells, the TGN has also been reported to function like early endosomal compartments in plant cells. However, the physiological roles of the TGN functions in plants are not understood. Here, we report a study of the SYP4 group (SYP41, SYP42, and SYP43), which represents the plant orthologs of the Tlg2/syntaxin16 Qa-SNARE (soluble N-ethylmaleimide sensitive factor attachment protein receptor) that localizes on the TGN in yeast and animal cells. The SYP4 group regulates the secretory and vacuolar transport pathways in the post-Golgi network and maintains the morphology of the Golgi apparatus and TGN. Consistent with a secretory role, SYP4 proteins are required for extracellular resistance responses to a fungal pathogen. We also reveal a plant cell-specific higher-order role of the SYP4 group in the protection of chloroplasts from salicylic acid-dependent biotic stress.     

LIL3, a light-harvesting-like protein,plays an essential role in chlorophyll and tocopherol biosynthesis

The light-harvesting chlorophyll-binding (LHC) proteins are major constituents of eukaryotic photosynthetic machinery. In plants, six different groups of proteins, LHC-like proteins, share a conserved motif with LHC. Although the evolution of LHC and LHC-like proteins is proposed to be a key for the diversification of modern photosynthetic eukaryotes, our knowledge of the evolution and functions of LHC-like proteins is still limited. In this study, we aimed to understand specifically the function of one type of LHC-like proteins, LIL3 proteins, by analyzing Arabidopsis mutants lacking them. The Arabidopsis genome contains two gene copies for LIL3, LIL3:1 and LIL3:2. In the lil3:1/lil3:2 double mutant, the majority of chlorophyll molecules are conjugated with an unsaturated geranylgeraniol side chain. This mutant is also deficient in α-tocopherol. These results indicate that reduction of both the geranylgeraniol side chain of chlorophyll and geranylgeranyl pyrophosphate, which is also an essential intermediate of tocopherol biosynthesis, is compromised in the lil3 mutants. We found that the content of geranylgeranyl reductase responsible for these reactions was severely reduced in the lil3 double mutant, whereas the mRNA level for this enzyme was not significantly changed. We demonstrated an interaction of geranylgeranyl reductase with both LIL3 isoforms by using a split ubiquitin assay, bimolecular fluorescence complementation, and combined blue-native and SDS polyacrylamide gel electrophoresis. We propose that LIL3 is functionally involved in chlorophyll and tocopherol biosynthesis by stabilizing geranylgeranyl reductase.     

Translationally controlled tumor protein is a conserved mitotic growth integrator in animals and plants

The growth of an organism and its size determination require the tight regulation of cell proliferation and cell growth. However, the mechanisms and regulatory networks that control and integrate these processes remain poorly understood. Here, we address the biological role of Arabidopsis translationally controlled tumor protein (AtTCTP) and test its shared functions in animals and plants. The data support a role of plant AtTCTP as a positive regulator of mitotic growth by specifically controlling the duration of the cell cycle. We show that, in contrast to animal TCTP, plant AtTCTP is not implicated in regulating postmitotic growth. Consistent with this finding, plant AtTCTP can fully rescue cell proliferation defects in Drosophila loss of function for dTCTP. Furthermore, Drosophila dTCTP is able to fully rescue cell proliferation defects in Arabidopsis tctp knockouts. Our data provide evidence that TCTP function in regulating cell division is part of a conserved growth regulatory pathway shared between plants and animals. The study also suggests that, although the cell division machinery is shared in all multicellular organisms to control growth, cell expansion can be uncoupled from cell division in plants but not in animals.     

Endosidin1 defines a compartment involved in endocytosis of the brassinosteroid receptor BRI1 and the auxin transporters PIN2 and AUX1

Although it is known that proteins are delivered to and recycled from the plasma membrane (PM) via endosomes, the nature of the compartments and pathways responsible for cargo and vesicle sorting and cellular signaling is poorly understood. To define and dissect specific recycling pathways, chemical effectors of proteins involved in vesicle trafficking, especially through endosomes, would be invaluable. Thus, we identified chemicals affecting essential steps in PM/endosome trafficking, using the intensely localized PM transport at the tips of germinating pollen tubes. The basic mechanisms of this localized growth are likely similar to those of non-tip growing cells in seedlings. The compound endosidin 1 (ES1) interfered selectively with endocytosis in seedlings, providing a unique tool to dissect recycling pathways. ES1 treatment induced the rapid agglomeration of the auxin translocators PIN2 and AUX1 and the brassinosteroid receptor BRI1 into distinct endomembrane compartments termed "endosidin bodies"; however, the markers PIN1, PIN7, and other PM proteins were unaffected. Endosidin bodies were defined by the syntaxin SYP61 and the V-ATPase subunit VHA-a1, two trans-Golgi network (TGN)/endosomal proteins. Interestingly, brassinosteroid (BR)-induced gene expression was inhibited by ES1 and treated seedlings displayed a brassinolide (BL)-insensitive phenotype similar to a bri1 loss-of-function mutant. No effect was detected in auxin signaling. Thus, PIN2, AUX1, and BRI1 use interactive pathways involving an early SYP61/VHA-a1 endosomal compartment.     

Reconstitution of abscisic acid activation of SLAC1 anion channel by CPK6 and OST1 kinases and branched ABI1 PP2C phosphatase action

The plant hormone abscisic acid (ABA) is produced in response to abiotic stresses and mediates stomatal closure in response to drought via recently identified ABA receptors (pyrabactin resistance/regulatory component of ABA receptor; PYR/RCAR). SLAC1 encodes a central guard cell S-type anion channel that mediates ABA-induced stomatal closure. Coexpression of the calcium-dependent protein kinase 21 (CPK21), CPK23, or the Open Stomata 1 kinase (OST1) activates SLAC1 anion currents. However, reconstitution of ABA activation of any plant ion channel has not yet been attained. Whether the known core ABA signaling components are sufficient for ABA activation of SLAC1 anion channels or whether additional components are required remains unknown. The Ca(2+)-dependent protein kinase CPK6 is known to function in vivo in ABA-induced stomatal closure. Here we show that CPK6 robustly activates SLAC1-mediated currents and phosphorylates the SLAC1 N terminus. A phosphorylation site (S59) in SLAC1, crucial for CPK6 activation, was identified. The group A PP2Cs ABI1, ABI2, and PP2CA down-regulated CPK6-mediated SLAC1 activity in oocytes. Unexpectedly, ABI1 directly dephosphorylated the N terminus of SLAC1, indicating an alternate branched early ABA signaling core in which ABI1 targets SLAC1 directly (down-regulation). Furthermore, here we have successfully reconstituted ABA-induced activation of SLAC1 channels in oocytes using the ABA receptor pyrabactin resistant 1 (PYR1) and PP2C phosphatases with two alternate signaling cores including either CPK6 or OST1. Point mutations in ABI1 disrupting PYR1-ABI1 interaction abolished ABA signal transduction. Moreover, by addition of CPK6, a functional ABA signal transduction core from ABA receptors to ion channel activation was reconstituted without a SnRK2 kinase.     

REDUCED CHLOROPLAST COVERAGE genes from Arabidopsis thaliana help to establish the size of the chloroplast compartment

Eukaryotic cells require mechanisms to establish the proportion of cellular volume devoted to particular organelles. These mechanisms are poorly understood. From a screen for plastid-to-nucleus signaling mutants in Arabidopsis thaliana, we cloned a mutant allele of a gene that encodes a protein of unknown function that is homologous to two other Arabidopsis genes of unknown function and to FRIENDLY, which was previously shown to promote the normal distribution of mitochondria in Arabidopsis. In contrast to FRIENDLY, these three homologs of FRIENDLY are found only in photosynthetic organisms. Based on these data, we proposed that FRIENDLY expanded into a small gene family to help regulate the energy metabolism of cells that contain both mitochondria and chloroplasts. Indeed, we found that knocking out these genes caused a number of chloroplast phenotypes, including a reduction in the proportion of cellular volume devoted to chloroplasts to 50% of wild type. Thus, we refer to these genes as REDUCED CHLOROPLAST COVERAGE (REC). The size of the chloroplast compartment was reduced most in rec1 mutants. The REC1 protein accumulated in the cytosol and the nucleus. REC1 was excluded from the nucleus when plants were treated with amitrole, which inhibits cell expansion and chloroplast function. We conclude that REC1 is an extraplastidic protein that helps to establish the size of the chloroplast compartment, and that signals derived from cell expansion or chloroplasts may regulate REC1.Chloroplasts drive plant growth, development, and reproduction by converting solar energy into biologically useful forms of energy. Thus, the biogenesis and function of chloroplasts underpin crop yields and, indeed, life on Earth. Chloroplasts develop from proplastids during germination and leaf development (1). After chloroplast biogenesis, chloroplasts divide by binary fission. A number of mutant alleles enhance or reduce the size of individual chloroplasts by attenuating or promoting chloroplast division (2). Regardless of the size of individual chloroplasts, the proportion of cellular volume devoted to all chloroplasts appears indistinguishable from wild type in these mutants (3–5). Thus, the mechanism that establishes the size of the chloroplast compartment appears distinct from the mechanisms of chloroplast division.The cell expansion that drives the expansion of leaves also drives the proliferation of chloroplasts. Indeed, the proliferation of chloroplasts is so tightly correlated with cell expansion that the ratio of the size of the chloroplast compartment to the size of mesophyll cells is constant, regardless of cell size (2, 6, 7). Cell type exerts a major influence over the proportion of cellular volume devoted to the chloroplast. For instance, the size of the chloroplast compartment in mesophyll cells is larger than in epidermal cells. Thus, an extraplastidic mechanism appears to determine the size of the chloroplast compartment (6). However, during the expansion of leaves, chloroplasts are not completely submissive to the cell. Indeed, chloroplast dysfunction inhibits the expansion of leaves (8).Although mechanisms that establish the proportion of cellular volume devoted to particular organelles are of fundamental importance to biology, these mechanisms remain poorly understood (2). In the particular case of chloroplasts, understanding these mechanisms may lead to significant advances for agriculture. For example, introducing C₄ photosynthesis into rice, a plant that performs C₃ photosynthesis, is one strategy for potentially increasing yields from this important crop (9). C₃ and C₄ leaves are distinct at the metabolic, cellular, and anatomical levels (9, 10). One of the conserved features of C₄ leaves is the increase and decrease in the size of the chloroplast compartment in bundle sheath and mesophyll cells, respectively, relative to C₃ leaves (10). The engineering of C₄ photosynthesis in important C₃ crops, such as rice, is thought to depend on the ability to rationally manipulate the size of the chloroplast compartment (11).We performed a screen for plastid-to-nucleus signaling mutants in Arabidopsis thaliana (12). From this screen, we obtained one mutant allele of a gene that encodes a protein of unknown function. This gene is homologous to two Arabidopsis genes that encode proteins of unknown function and to FRIENDLY. FRIENDLY and its orthologs promote the normal distribution of mitochondria in Arabidopsis and in nonphotosynthetic organisms (13). However, these three Arabidopsis homologs of FRIENDLY are found only in photosynthetic organisms. Based on these data, we thought that FRIENDLY may have expanded into a small gene family to help manage the energy metabolism of cells that contain both chloroplasts and mitochondria. We tested this idea by examining the phenotypes of mutants in which one, two, three, or all four of these genes are knocked out. We found that these mutants exhibited a number of chloroplast phenotypes, including a smaller chloroplast compartment relative to wild type. Thus, we named these genes REDUCED CHLOROPLAST COVERAGE (REC). We also found that the protein that contributes most to establishing the size of the chloroplast compartment, REC1, localizes to both the nucleus and the cytosol, and we provide evidence that signals derived from dysfunctional chloroplasts or the inhibition of cell expansion may regulate the nucleocytoplasmic partitioning of REC1.     

ABC transporter AtABCG25 is involved in abscisic acid transport and responses

Abscisic acid (ABA) is one of the most important phytohormones involved in abiotic stress responses, seed maturation, germination, and senescence. ABA is predominantly produced in vascular tissues and exerts hormonal responses in various cells, including guard cells. Although ABA responses require extrusion of ABA from ABA-producing cells in an intercellular ABA signaling pathway, the transport mechanisms of ABA through the plasma membrane remain unknown. Here we isolated an ATP-binding cassette (ABC) transporter gene, AtABCG25, from Arabidopsis by genetically screening for ABA sensitivity. AtABCG25 was expressed mainly in vascular tissues. The fluorescent protein-fused AtABCG25 was localized at the plasma membrane in plant cells. In membrane vesicles derived from AtABCG25-expressing insect cells, AtABCG25 exhibited ATP-dependent ABA transport. The AtABCG25-overexpressing plants showed higher leaf temperatures, implying an influence on stomatal regulation. These results strongly suggest that AtABCG25 is an exporter of ABA and is involved in the intercellular ABA signaling pathway. The presence of the ABA transport mechanism sheds light on the active control of multicellular ABA responses to environmental stresses among plant cells.     

Arabidopsis semidwarfs evolved from independent mutations in GA20ox1, ortholog to green revolution dwarf alleles in rice and barley

Understanding the genetic bases of natural variation for developmental and stress-related traits is a major goal of current plant biology. Variation in plant hormone levels and signaling might underlie such phenotypic variation occurring even within the same species. Here we report the genetic and molecular basis of semidwarf individuals found in natural Arabidopsis thaliana populations. Allelism tests demonstrate that independent loss-of-function mutations at GA locus 5 (GA5), which encodes gibberellin 20-oxidase 1 (GA20ox1) involved in the last steps of gibberellin biosynthesis, are found in different populations from southern, western, and northern Europe; central Asia; and Japan. Sequencing of GA5 identified 21 different loss-of-function alleles causing semidwarfness without any obvious general tradeoff affecting plant performance traits. GA5 shows signatures of purifying selection, whereas GA5 loss-of-function alleles can also exhibit patterns of positive selection in specific populations as shown by Fay and Wu’s H statistics. These results suggest that antagonistic pleiotropy might underlie the occurrence of GA5 loss-of-function mutations in nature. Furthermore, because GA5 is the ortholog of rice SD1 and barley Sdw1/Denso green revolution genes, this study illustrates the occurrence of conserved adaptive evolution between wild A.thaliana and domesticated plants.Bioactive gibberellins (GAs) are plant growth regulators involved in important traits such as seed germination, flowering time, flower development, and elongation growth (1). GA biosynthesis and signaling pathways are well defined (1, 2) and have been targeted in crop breeding. Modification of GA pathways was crucial in the green revolution because it conferred semidwarfness, thus reducing lodging and increasing crop yields (3–6). Green revolution semidwarf varieties in wheat are due to mutations in DELLA genes, whereas many short straw rice varieties carry a mutation in the Semi-Dwarf-1 (SD1) locus. This locus codes for GA 20-oxidase-2, a GA biosynthesis gene that is also mutated in most modern barley varieties in which the gene was called Denso or Semi-dwarf 1 (Sdw1) (7).GA 20-oxidases are involved in the later steps of GA biosynthesis and belong to the group of 2-oxoglutarate–dependent dioxygenases that, together with GA 3-oxidases, form biologically active GA (8). Arabidopsis thaliana has five GA20ox paralogous genes. AtGA20ox-1, AtGA20ox-2, AtGA20ox-3, and AtGA20ox-4 can catalyze the in vitro conversion of GA₁₂ to GA₉. Therefore, GA20ox paralogs might have partial redundant functions (9). However, among paralog genes, only AtGA20ox-1 (GA5), which was cloned on the basis of the ga5 mutant (10), affected plant height (8).Natural variation for GA biosynthesis has been previously described in A. thaliana because the Bur-0 accession carries a loss-of-function allele at GA20ox4 (9), which does not result in a semidwarf phenotype. In addition, genetic variation in GA1 has been associated with variation in floral morphology (11). Furthermore, the semidwarf phenotype (here defined as a plant height shorter than half the size of genetically related individuals) observed in the Kas-2 accession is due to a recessive allele at the GA5 locus (12). The latter finding led to the questions of whether green revolution alleles, artificially selected in cereals, could also occur in natural populations of the wild species A. thaliana, and if so, how many different GA5 loss-of-function alleles exist, how they are distributed, and why they occur in some populations.     

PolV(PolIVb) function in RNA-directed DNA methylation requires the conserved active site and an additional plant-specific subunit

Two forms of a plant-specific RNA polymerase (Pol), PolIV(PolIVa) and PolV(PolIVb), currently defined by their respective largest subunits [NRPD1(NRPD1a) and NRPE1(NRPD1b)], have been implicated in the production and activity of 24-nt small RNAs (sRNAs) in RNA-directed DNA methylation (RdDM). Prevailing models support the view that PolIV(PolIVa) plays an upstream role in RdDM by producing the 24-nt sRNAs, whereas PolV(PolIVb) would act downstream at a structural rather than an enzymatic level to reinforce sRNA production by PolIV(PolIVa) and mediate DNA methylation. However, the composition and mechanism of action of PolIV(PolIVa)/PolV(PolIVb) remain unclear. In this work, we have identified a plant-specific PolV(PolIVb) subunit, NRPE5a, homologous to NRPB5a, a common subunit shared by PolI-III and shown here to be present in PolIV(PolIVa). Our results confirm the combinatorial diversity of PolIV(PolIVa)/PolV(PolIVb) subunit composition and indicate that these plant-specific Pols are eukaryotic-type polymerases. Moreover, we show that nrpe5a-1 mutation differentially impacts sRNAs accumulation at various PolIV(PolIVa)/PolV(PolIVb)-dependent loci, indicating a target-specific requirement for NRPE5a in the process of PolV(PolIVb)-dependent gene silencing. We then describe that the triad aspartate motif present in the catalytic center of PolV(PolIVb) is required for recapitulation of all activities associated with this Pol complex in RdDM, suggesting that RNA polymerization is important for PolV(PolIVb) to perform its regulatory functions.     

Recognition and repair of UV lesions in loop structures of duplex DNA by DASH-type cryptochrome

DNA photolyases and cryptochromes (cry) form a family of flavoproteins that use light energy in the blue/UV-A region for the repair of UV-induced DNA lesions or for signaling, respectively. Very recently, it was shown that members of the DASH cryptochrome subclade repair specifically cyclobutane pyrimidine dimers (CPDs) in UV-damaged single-stranded DNA. Here, we report the crystal structure of Arabidopsis cryptochrome 3 with an in-situ-repaired CPD substrate in single-stranded DNA. The structure shows a binding mode similar to that of conventional DNA photolyases. Furthermore, CPD lesions in double-stranded DNA are bound and repaired with similar efficiency as in single-stranded DNA if the CPD lesion is present in a loop structure. Together, these data reveal that DASH cryptochromes catalyze light-driven DNA repair like conventional photolyases but lack an efficient flipping mechanism for interaction with CPD lesions within duplex DNA.     

Carlactone is converted to carlactonoic acid by MAX1 in Arabidopsis and its methyl ester can directly interact with AtD14 in vitro

Strigolactones (SLs) stimulate seed germination of root parasitic plants and induce hyphal branching of arbuscular mycorrhizal fungi in the rhizosphere. In addition, they have been classified as a new group of plant hormones essential for shoot branching inhibition. It has been demonstrated thus far that SLs are derived from carotenoid via a biosynthetic precursor carlactone (CL), which is produced by sequential reactions of DWARF27 (D27) enzyme and two carotenoid cleavage dioxygenases CCD7 and CCD8. We previously found an extreme accumulation of CL in the more axillary growth1 (max1) mutant of Arabidopsis, which exhibits increased lateral inflorescences due to SL deficiency, indicating that CL is a probable substrate for MAX1 (CYP711A1), a cytochrome P450 monooxygenase. To elucidate the enzymatic function of MAX1 in SL biosynthesis, we incubated CL with a recombinant MAX1 protein expressed in yeast microsomes. MAX1 catalyzed consecutive oxidations at C-19 of CL to convert the C-19 methyl group into carboxylic acid, 9-desmethyl-9-carboxy-CL [designated as carlactonoic acid (CLA)]. We also identified endogenous CLA and its methyl ester [methyl carlactonoate (MeCLA)] in Arabidopsis plants using LC-MS/MS. Although an exogenous application of either CLA or MeCLA suppressed the growth of lateral inflorescences of the max1 mutant, MeCLA, but not CLA, interacted with Arabidopsis thaliana DWARF14 (AtD14) protein, a putative SL receptor, as shown by differential scanning fluorimetry and hydrolysis activity tests. These results indicate that not only known SLs but also MeCLA are biologically active in inhibiting shoot branching in Arabidopsis.Strigolactones (SLs) are allelochemicals, exuded from plant roots, that stimulate seed germination of root parasitic plants, Striga spp., Orobanche spp., and Phelipanche spp. (1). The hyphal branching of the biotrophic arbuscular mycorrhizal (AM) fungi is also induced by SLs in the vicinity of host roots to ensure symbiosis with host plants (2). SLs are not only host recognition signals in the rhizosphere but also play important roles in the SL-producing plants themselves. Since the mid-1990s, the existence of novel hormone-like signals involved in shoot branching inhibition of plants had been proposed following the isolation and analysis of mutants with increased shoot branching, ramosus (rms) of pea (Pisum sativum), decreased apical dominance (dad) of petunia (Petunia hybrida), more axillary growth (max) of Arabidopsis (Arabidopsis thaliana), and dwarf (d) and high tillering dwarf (htd) of rice (Oryza sativa) (3–6). Recently, these mutants have been identified as SL-deficient or -insensitive mutants, providing decisive evidence that SLs function as shoot branch-inhibiting hormones (7, 8). In addition, further characterization of these mutants has shown that SLs affect root growth and development, leaf shape and senescence, internode elongation, secondary growth, and drought and salinity stress responses (9–11).Despite the fact that SLs play important roles in plant growth and development and in the rhizosphere, the biosynthesis pathway of SLs has not fully been elucidated. The natural SLs consist of a tricyclic lactone (ABC ring) connecting to a butenolide group (D ring) via an enol ether bridge. 5-Deoxystrigol (5DS) and ent-2′-epi-5-deoxystrigol [4-deoxyorobanchol (4DO); Fig. 1] are thought to be the precursors of other natural SLs, which have methyl group(s) on the A ring and hydroxyl or acetyloxyl group(s) on the A/B ring (1, 12). Because the mutations in the CCD7 (MAX3/RMS5/HTD1) and CCD8 (MAX4/RMS1/DAD1/D10) genes, both of which encode carotenoid cleavage dioxygenases, result in SL deficiency (7, 8), it has been thought that SLs are synthesized from carotenoids by these enzymes. Recently, it has been demonstrated that the Fe-containing protein D27 catalyzes the isomerization at C-9 of all-trans-β-carotene to produce 9-cis-β-carotene in vitro (13) (Fig. 1). The product 9-cis-β-carotene was a substrate for CCD7 to produce 9-cis-β-apo-10′-carotenal, and this cleavage product was subsequently catalyzed by CCD8 to produce an SL precursor named carlactone (CL) (13) (Fig. 1). More recently, we reported that CL was detected from rice and Arabidopsis, and exogenous CL was converted into SLs in rice, demonstrating that CL is an endogenous precursor for SLs (14). Because CL contains the A and D rings and the enol ether bridge but lacks the B and C rings, additional biosynthetic steps are needed for the conversion of CL to 5DS and 4DO in plants.Open in a separate windowFig. 1.Proposed biosynthesis pathway for SL from carotenoid. The conversion from β-carotene to CL by D27, CCD7, and CCD8 enzymes has been confirmed previously by in vitro assay (13). The conversion from CL to CLA by MAX1 and the existence of CLA and MeCLA in Arabidopsis were shown in this study.The most probable enzyme catalyzing these reactions is MAX1 (CYP711A1), a cytochrome P450 monooxygenase (5). In reciprocal grafting experiments of Arabidopsis, the hyperbranching phenotype in scions of the max4 (ccd8) mutant was rescued to WT shoot branching patterns when grafted to max1 rootstocks, whereas max4 rootstocks could not restore a WT shoot branching phenotype to max1 scions (5). These results suggested that MAX1 acts on a downstream pathway of CCD8 to produce a mobile signal for shoot branching inhibition. Recently, it was reported that CL could not rescue the max1 phenotype by exogenous application (15), and we found an extreme accumulation of CL in the max1 mutant (14). Hence, CL is the most probable candidate for the substrate of MAX1. In the present study, to elucidate the enzymatic function of MAX1 in SL biosynthesis, we performed in vitro conversion of CL using a recombinant MAX1 protein expressed in yeast microsomes. We then examined if CL is metabolized in a similar manner in vivo by detecting and identifying the CL metabolites in Arabidopsis and rice plants. In addition, to investigate the role of the CL derivatives for shoot branching inhibition, we examined their biological activities and interaction with Arabidopsis thaliana DWARF14 (AtD14), a putative SL receptor.