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GENETICS, GENOMICS, AND MOLECULAR EVOLUTION

The Gene for the P-Subunit of Glycine Decarboxylase from the C₄ Species Flaveria trinervia: Analysis of Transcriptional Control in Transgenic Flaveria bidentis (C₄) and Arabidopsis (C₃)^1,[W],[OA]

Institut für Entwicklungs- und Molekularbiologie der Pflanzen, Heinrich-Heine-Universität, 40225 Duesseldorf, Germany (S.E., C.W., J.B., U.G., U.S., M.K., M.S., P.W.); Institute of Plant Genetics and Crop Plant Research (IPK), 06466 Gatersleben, Germany (R.C.); and Abteilung Pflanzenphysiologie der Universität Rostock, 18051 Rostock, Germany (H.B.)

	ABSTRACT

TOP ABSTRACT RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

 
Glycine decarboxylase (GDC) plays an important role in the photorespiratory metabolism of plants. GDC is composed of four subunits (P, H, L, and T) with the P-subunit (GLDP) serving as the actual decarboxylating unit. In C₃ plants, GDC can be found in all photosynthetic cells, whereas in leaves of C₃-C₄ intermediate and C₄ species its occurrence is restricted to bundle-sheath cells. The specific expression of GLDP in bundle-sheath cells might have constituted a biochemical starting point for the evolution of C₄ photosynthesis. To understand the molecular mechanisms responsible for restricting GLDP expression to bundle-sheath cells, we performed a functional analysis of the GLDPA promoter from the C₄ species Flaveria trinervia. Expression of a promoter-reporter gene fusion in transgenic plants of the transformable C₄ species Flaveria bidentis (C₄) showed that 1,571 bp of the GLDPA 5' flanking region contain all the necessary information for the specific expression in bundle-sheath cells and vascular bundles. Interestingly, we found that the GLDPA promoter of F. trinervia exhibits a C₄-like spatial activity also in the C₃ plant Arabidopsis (Arabidopsis thaliana), indicating that a mechanism for bundle-sheath-specific expression is also present in this C₃ species. Using transgenic Arabidopsis, promoter deletion studies identified two regions in the GLDPA promoter, one conferring repression of gene expression in mesophyll cells and one functioning as a general transcriptional enhancer. Subsequent analyses in transgenic F. bidentis confirmed that these two segments fulfill the same function also in the C₄ context.

In C₄ plants, the CO₂ assimilatory enzymes are compartmentalized into either mesophyll or bundle-sheath cells, and this is governed by differential gene expression. It has been shown that mesophyll-specific expression of C₄ cycle genes is mainly regulated at the transcriptional level (Schaffner and Sheen, 1992; Stockhaus et al., 1994; Rosche et al., 1998; Sheen, 1999), whereas bundle-sheath-specific expression is controlled at both transcriptional and posttranscriptional levels (Long and Berry, 1996; Marshall et al., 1997; Sheen, 1999; Patel et al., 2006).

There are indications that photorespiration also exists in C₄ plants, albeit at a much lower level than in C₃ plants (Osmond and Harris, 1971; Furbank and Badger, 1983; de Veau and Burris, 1989). This is likely due to the fact that photorespiration in C₄ species is strictly confined to the bundle-sheath cells in the leaves, while in C₃ plants photorespiration occurs in all photosynthetically active mesophyll cells (Ohnishi and Kanai, 1983).

The mitochondrial multienzyme complex Gly decarboxylase (GDC) plays a key role in the photorespiratory pathway. GDC is composed of four different subunits (P, H, T, and L) and catalyzes, in cooperation with Ser hydroxymethyltransferase, the oxidative decarboxylation of Gly that originates from the breakdown of photorespiratory phosphoglycolate. In the course of these reactions, two molecules of Gly are converted to one molecule each of Ser, NH₃, and CO₂ (Neuburger et al., 1986). Consistent with the compartmentation of the photorespiratory cycle, GDC is present in all photosynthetic cells of C₃ plant leaves, but strictly confined to the bundle-sheath cells in C₄ species (Ohnishi and Kanai, 1983). None of the GDC subunits has been detected in the mesophyll cells of C₄ plants (Morgan et al., 1993).

Plant species possessing a C₃-C₄ intermediate type of photosynthesis are of special interest for studying the evolution of C₄-characteristic traits. Some C₃-C₄ plants are to some extent able to fix CO₂ into malate and Asp (Monson et al., 1986), but most of these species do not have a C₄ metabolism. They can be characterized as "intermediate," for example, by their CO₂ compensation points, which are lower than those of C₃ plants but higher than those of C₄ plants (Edwards and Ku, 1987; Rawsthorne, 1992). As in C₄ plants, functional GDC occurs only in the bundle-sheath cells of the leaves of C₃-C₄ intermediate plants, as it was first demonstrated for Moricandia arvensis (Rawsthorne et al., 1988a, 1988b). Later on, it was discovered that the loss of GDC activity in the mesophyll is due to a lack of the P-subunit (GLDP). Because of the absence of GDC activity in mesophyll cells of M. arvensis leaves, photorespiratory Gly moves to the bundle-sheath cells to be processed by GDC. The bundle-sheath cells of M. arvensis contain a large number of mitochondria that are arranged at the centripetal cell wall adjacent to the vascular tissue, whereas the chloroplasts are located at the cell periphery. This special distribution of organelles and the restriction of Gly oxidation to the bundle-sheath compartment result in an efficient recapture of released photorespiratory CO₂, thereby lowering the CO₂ compensation point when compared to a typical C₃ plant (Rawsthorne et al., 1998). C₃-C₄ intermediate species are thought to represent a stage in the evolutionary transition from C₃ to C₄ photosynthesis (Edwards and Ku, 1987). It was therefore tempting to speculate that the confinement of GDC to the bundle-sheath cells has been one of the biochemical starting points for the evolution of C₄ plants (Morgan et al., 1993; Bauwe and Kolukisaoglu, 2003; Sage, 2004). However, the possible effects of this relocation for C₄ evolution are discussed controversially (Edwards et al., 2001). The loss of the P-subunit seems to be the initial step to inactivate GDC in the mesophyll, and the absence of all GDC subunits in the leaf mesophyll of other C₃-C₄ intermediate species suggests that they have developed further toward C₄ photosynthesis than M. arvensis (Morgan et al., 1993).

A well-established experimental system for investigating the evolution of C₄-characteristic traits is the genus Flaveria of the Asteraceae (Powell, 1978). This small genus comprising 23 known species includes both C₃ and C₄ species, but also a large number of C₃-C₄ intermediate species (Edwards and Ku, 1987). In this study we examined the promoter of the gene encoding GLDP from the C₄ species Flaveria trinervia to gain insight into the molecular basis of bundle-sheath-specific gene expression. Two genes encoding GLDP have been identified in F. trinervia, GLDPA and the pseudogene GLDPB (Cossu, 1997). The GLDPA promoter was fused to a GUS reporter gene and promoter activity was analyzed in transgenic Flaveria bidentis (C₄) and Arabidopsis (Arabidopsis thaliana; C₃). Similar expression patterns were observed in these two species, which allowed the use of Arabidopsis as a heterologous system for testing a series of promoter deletions to identify C₄-characteristic regulatory elements within the GLDPA promoter. These analyses resulted in the identification of regions within the GLDPA promoter that contribute mainly to the regulation of expression quantity or to the spatial expression pattern of the GLDPA gene, respectively.

	RESULTS

TOP ABSTRACT RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

 

In Situ RNA Hybridization

Immunolabeling studies have shown that, in C₄ plants, GLDP accumulates exclusively in bundle-sheath cells of leaves (Hylton et al., 1988; Morgan et al., 1993; Yoshimura et al., 2004). To examine whether this C₄-characteristic localization of the P-protein is due to specific accumulation of GLDPA mRNA in this compartment, we analyzed the expression pattern of the GLDPA gene in leaves of the C₄ species F. trinervia by in situ hybridization. As a probe we used a 2.4-kb fragment of the GLDPA cDNA from F. trinervia, and control hybridizations were performed with the corresponding sense probe.

In leaves of F. trinervia, transcripts of the GLDPA gene could only be detected in bundle-sheath and not in mesophyll cells (Fig. 1A ). The GLDPA mRNA accumulated near the centripetal cell walls of the bundle-sheath cells due to the concentration of cytoplasm in this region. The confinement of the P-protein to the bundle-sheath cells therefore is controlled by the specific accumulation of GLDPA mRNA in this compartment. The same result was obtained by in situ hybridization of the GLDPA probe to leaf cross sections of the C₄ species F. bidentis (Fig. 1C).

View larger version (126K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 1. In situ localization of GLDPA RNA accumulation in leaves of F. trinervia (A) and F. bidentis (C). Hybridizations with a GLDPA sense probe to leaf cross sections of F. trinervia (B) and F. bidentis (D) served as negative controls. BS, Bundle-sheath cell.

The in situ RNA hybridization analysis showed that the occurrence of GLDPA transcripts is restricted to the bundle-sheath cells in F. trinervia and F. bidentis (Fig. 1). To test whether the available 1,571 bp of the 5' flanking region of the GLDPA gene (including the 5' untranslated region upstream of the AUG start codon) harbor all the necessary information for this bundle-sheath-specific expression pattern, we fused this region to GUS reporter gene (construct GLDPA-Ft; Fig. 2A ) and examined its expression behavior in transgenic F. bidentis plants. The C₄ species F. bidentis is a close relative to F. trinervia, but unlike F. trinervia it is suitable for transformation by Agrobacterium tumefaciens-mediated gene transfer (Chitty et al., 1994).

View larger version (58K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 2. Analysis of GLDPA-Ft promoter activity in transgenic F. bidentis. A, Structure of the chimeric GLDPA-Ft::GUS gene. B and C, Histochemical localization of GUS activity (blue staining) in leaf sections of transgenic F. bidentis transformed with GLDPA-Ft. The photograph (C) was taken from the leaf surface displaying GUS activity in the stomatal guard cells of F. bidentis leaves. Incubation times were 1 h. D, GUS activities in leaves of transgenic F. bidentis plants transformed with GLDPA-Ft. GUS activities are expressed in nanomoles of the reaction product 4-methylumbelliferone (MU) per milligram of protein per minute. The numbers of independent transgenic plants investigated (N) and the median values of GUS activity (M) are indicated at the top of each column.

The Expression Pattern of the GLDPA-GUS Construct in Arabidopsis Is Similar to That in F. bidentis

Bundle-sheath cells are not a unique feature of C₄ plants. They are also present in many C₃ plants, but compared to the situation in C₄ species, these cells exhibit fewer chloroplasts and mitochondria (Kinsman and Pyke, 1998; Leegood, 2002). To examine whether the GLDPA promoter of F. trinervia shows a cell-specific activity in a C₃ background, we introduced the GLDPA-GUS construct into Arabidopsis.

The histochemical analysis revealed GUS expression in the vascular tissue and in the surrounding bundle-sheath cells (Fig. 3, C and D ). Notably, very similar to the expression pattern in F. bidentis, no GUS activity could be detected in the mesophyll cells of transgenic Arabidopsis plants. The quantification of GUS levels showed that the median activity of the reporter protein was comparable in Arabidopsis and F. bidentis leaves (Figs. 2D and 3B).

View larger version (46K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 3. Analysis of GLDPA-Ft promoter activity in transgenic Arabidopsis. A, Schematic structure of the chimeric GLDPA-Ft::GUS, GLDPA-Ft::mGFP5-ER, and GLDPA-Ft::H2B:YFP genes. B, GUS activities in leaves of transgenic Arabidopsis plants transformed with GLDPA-Ft::GUS. GUS activities are expressed in nanomoles of the reaction product 4-methylumbelliferone (MU) per milligram of protein per minute. The numbers of independent transgenic plants investigated (N) and the median values of GUS activity (M) are indicated at the top of each column. C and D, Histochemical localization of GUS activity (blue staining) in leaf sections of transgenic Arabidopsis transformed with GLDPA-Ft::GUS. Picture (D) was taken from the leaf surface displaying GUS activity in the vascular strands and the adjacent layer of bundle-sheath cells in Arabidopsis. Incubation times were 1 h. E to L, Fluorescence microscopy images taken from leaf cross sections of Arabidopsis plants transformed with the construct GLDPA-Ft::mGFP5-ER (E–H) or GLDPA-Ft::H2B:YFP (I–L). For E, G, I, and K, images taken with a GFP imaging filter system were merged with corresponding bright-field images. Photographs in F, H, J, and L were captured using the GFP imaging filter system alone. Selected bundle-sheath cells that express the reporter gene are highlighted by yellow arrows. BS, Bundle-sheath cell; V, vascular tissue; X, xylem; P, phloem.

Deletion Analysis of the GLDPA Promoter

The "C₄-like" expression pattern of GLDPA-GUS in transgenic Arabidopsis provided the opportunity to functionally dissect the GLDPA promoter by using this C₃ model organism as an experimental system. To identify cis-regulatory determinants that are responsible for the activity of the GLDPA promoter in bundle-sheath cells and the vascular bundle, we produced a set of 5' deletions and analyzed their expression specificity and level in transgenic Arabidopsis. The GLDPA promoter was subdivided into seven fragments that are referred to as region 1 to region 7 in the following (Fig. 4A ).

View larger version (47K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 4. Deletion analysis of the GLDPA promoter of F. trinervia in the C3 plant Arabidopsis. A, Overview of GLDPA promoter deletion constructs analyzed in transgenic Arabidopsis. Due to the cloning strategy, the GLDPA promoter of F. trinervia was subdivided into seven regions. B and C, Histochemical localization of GUS activity in leaf sections of transgenic Arabidopsis transformed with deletion construct GLDPA-Ft-1 (B) or GLDPA-Ft-2 (C). Incubation times were 12 h (A) and 20 h (B). D, GUS activities in leaves of transgenic Arabidopsis plants transformed with different GLDPA deletion constructs. GUS activities are expressed in nanomoles of the reaction product 4-methylumbelliferone (MU) per milligram of protein per minute. The numbers of independent transgenic plants investigated (N) and the median values of GUS activity (M) are indicated at the top of each column.

This deletion analysis clearly demonstrated the pronounced importance of regions 1, 2, and 3 for the transcriptional activity of the GLDPA promoter in the leaves of transgenic Arabidopsis plants. While truncation of regions 1 and 2 causes a dramatic decrease of transcriptional activity without affecting the spatial expression pattern, the additional deletion of region 3 results in a further reduction of promoter activity, which impeded further analysis of cell type-specific expression within the leaf.

Regions 1 and 2 of the GLDPA Promoter Together Function as a General Enhancer of Transcription in the Arabidopsis Leaf

To investigate whether the GLDPA promoter fragment reaching from –1,571 to –1,139 (regions 1 and 2) was able to act as a transcriptional enhancer, we combined this segment of the promoter with region 7 of the GLDPA promoter (–298 to –1). Region 7 harbors a putative TATA box and the starting point of transcription, but as reported above this part of the promoter alone is not sufficient to drive GUS expression in the Arabidopsis leaf (Fig. 4D).

The transformation of construct GLDPA-Ft-1-2-7 (Fig. 5A ) into Arabidopsis caused a substantial level of GUS expression in mesophyll and bundle-sheath cells as well as in the vascular strands of the leaves (Fig. 5, B and C) and confirms that regions 1 and 2 contain transcriptional enhancers with no apparent cell type specificity within the leaf.

View larger version (64K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 5. Functional analysis of GLDPA promoter regions 1 and 2 in transgenic Arabidopsis. A, Chimeric promoter constructs used for plant transformation. B, GUS activities in leaves of transgenic Arabidopsis plants transformed with different promoter constructs. GUS activities are expressed in nanomoles of the reaction product 4-methylumbelliferone (MU) per milligram of protein per minute. The numbers of independent transgenic plants investigated (N) and the median values of GUS activity (M) are indicated at the top of each column. C and D, Histochemical localization of GUS activity in leaf sections of transgenic Arabidopsis plants transformed with GLDPA-Ft-1-2-7 (C) and GLDPA-Ft-1-2-ppcA-PRFt (D). Incubation times were 12 h.

The fusion of regions 1 and 2 of the GLDPA promoter with the ppcA-PR_Ft promoter fragment resulted in strong GUS expression in leaves of Arabidopsis (Fig. 5B). The GUS reporter gene was active in both mesophyll and bundle-sheath cells as well as in the vascular bundles (Fig. 5D), and the expression profile of this chimeric promoter is thus indistinguishable from that of GLDPA-Ft-1-2-7. We conclude from these experiments that regions 1 and 2 of the GLDPA promoter constitute a general transcriptional enhancer module that, in combination with a basal promoter, stimulates the expression of a linked reporter gene in all types of interior leaf cells of Arabidopsis.

Region 3 of the GLDPA Promoter Acts as a Mesophyll-Specific Repressor of Gene Expression

The role of region 3 (–1,138 to –927) in regulating GLDPA promoter activity was investigated by introducing the relevant promoter fragment into construct GLDPA-Ft-1-2-7, resulting in the production of the chimeric promoter GLDPA-Ft-1-2-3-7 (Fig. 6A ). The addition of region 3 to GLDPA-Ft-1-2-7 caused a significant change in the spatial expression pattern of the GUS reporter gene. While GLDPA-Ft-1-2-7 plants expressed the GUS reporter gene in mesophyll and bundle-sheath cells as well as in the vascular tissue (Fig. 5C), GUS activity of GLDPA-Ft-1-2-3-7 plants was strictly confined to the bundle-sheath cells and the vascular compartment (Fig. 6B). These observations indicate that region 3 of the GLDPA promoter from F. trinervia functions as a mesophyll-specific repressor of gene expression in the Arabidopsis leaf.

View larger version (72K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 6. Functional analysis of GLDPA promoter region 3 in transgenic Arabidopsis. A, Schematic structure of construct GLDPA-Ft-1-2-3-7. B, Histochemical localization of GUS activity in the leaf sections of a transgenic Arabidopsis plant transformed with GLDPA-Ft-1-2-3-7. Incubation time was 20 h. C, GUS activities in leaves of transgenic Arabidopsis plants transformed with promoter construct GLDPA-Ft-1-2-3-7. GUS activities are expressed in nanomoles of the reaction product 4-methylumbelliferone (MU) per milligram of protein per minute. The numbers of independent transgenic plants investigated (N) and the median values of GUS activity (M) are indicated at the top of each column.

We have shown that the GLDPA promoter fragment comprising base pairs –1,571 to –927 (regions 1–3) in combination with the most proximal promoter part (region 7) is sufficient to direct GUS expression in the bundle-sheath cells and vascular bundles of transgenic Arabidopsis plants. Nevertheless, additional cis-regulatory determinants that could be involved in the spatial regulation of transcriptional activity might also be present in promoter regions 4, 5, and 6. To investigate the occurrence of cis-regulatory elements within these promoter regions, it was necessary to raise the GUS expression levels of constructs GLDPA-Ft-3 to GLDPA-Ft-6 to a level that allowed a histochemical analysis. Since regions 1 and 2 of the GLDPA promoter contain a general transcriptional enhancer with no apparent leaf cell specificity, we attached this GLDPA transcriptional enhancer module to the 5' borders of the truncated promoters (Fig. 7A ).

View larger version (96K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 7. Analysis of promoter constructs GLDPA-Ft-1-2-4-5-6-7, GLDPA-Ft-1-2-5-6-7, and GLDPA-Ft-1-2-6-7 in transgenic Arabidopsis. A, Schematic structure of constructs GLDPA-Ft-1-2-4-5-6-7, GLDPA-Ft-1-2-5-6-7, and GLDPA-Ft-1-2-6-7. B, GUS activities in leaves of transgenic Arabidopsis plants transformed with different promoter constructs. GUS activities are expressed in nanomoles of the reaction product 4-methylumbelliferone (MU) per milligram of protein per minute. The numbers of independent transgenic plants investigated (N) and the median values of GUS activity (M) are indicated at the top of each column. C to H, Histochemical localization of GUS activity in leaf sections of transgenic Arabidopsis plants transformed with GLDPA-Ft-1-2-4-5-6-7 (C and F), GLDPA-Ft-1-2-5-6-7 (D and G), or GLDPA-Ft-1-2-6-7 (E and H). Incubation times were 4 h (C, D, F, and G) and 5 h (E and H).

Analysis of Promoter Construct GLDPA-Ft-1-2-3-7 in Transgenic F. bidentis

A truncated promoter containing the transcription-enhancing regions 1 and 2, the mesophyll repressor region 3, and the basal expression segment 7 generated the same spatial expression profile in the leaf of the C₃ plant Arabidopsis as the complete GLDPA promoter, i.e. the promoter regions 4, 5, and 6 (–926 to –299) were not essential for creating the C₄-characteristic spatial expression pattern of a reporter gene. We now wished to examine whether this chimeric GLDPA-Ft-1-2-3-7 promoter is capable of providing this C₄ expression profile also in the C₄ background of F. bidentis. This chimeric promoter construct was therefore transformed into F. bidentis, and its expression was examined in the leaves of the transgenic plants (Fig. 8 ).

View larger version (71K): [in this window] [in a new window] [as a PowerPoint slide]   Figure 8. Analysis of the promoter construct GLDPA-Ft-1-2-3-7 in transgenic F. bidentis. A, Schematic structure of construct GLDPA-Ft-1-2-3-7. B and C, Histochemical localization of GUS activity in leaf sections of transgenic F. bidentis plants transformed with GLDPA-Ft-1-2-3-7. Incubation times were 28 h. D, GUS activities in leaves of transgenic F. bidentis plants transformed with GLDPA-Ft-1-2-3-7. GUS activities are expressed in nanomoles of the reaction product 4-methylumbelliferone (MU) per milligram of protein per minute. The numbers of independent transgenic plants investigated (N) and the median values of GUS activity (M) are indicated at the top of each column.

	DISCUSSION

TOP ABSTRACT RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

 
The correct functioning of the C₄ photosynthetic cycle requires strict compartmentalization of C₄ enzymes in either mesophyll or bundle-sheath cells of the leaf. This cell type-specific accumulation of proteins is governed by differential gene expression (Sheen, 1999). To broaden our knowledge on the molecular basis of bundle-sheath-specific gene expression in C₄ plants, we have performed a functional analysis of the 5' flanking sequences of the GLDPA gene from F. trinervia (C₄). The GLDPA gene encodes GLDP, which is specifically located in the bundle-sheath cells of C₄ species (Morgan et al., 1993). To determine whether the bundle-sheath-specific accumulation of the GLDP protein in the C₄ leaf is paralleled by the accumulation of the corresponding mRNA, we studied the occurrence of GLDPA transcripts within the leaves of F. trinervia and F. bidentis by in situ hybridizations. GLDPA RNA was exclusively found in the bundle-sheath cells of both C₄ species, indicating that the presence of this protein in bundle-sheath cells and its absence in mesophyll cells are caused by differential GLDPA mRNA accumulation.

We then investigated whether the available 1,571 bp of the 5' flanking region of the GLDPA coding sequence harbor all the necessary information for this bundle-sheath-specific expression. Fusion of these sequences—including the 5' untranslated segment of the GLDPA gene—to the GUS reporter gene resulted in reporter gene activity in the bundle-sheath but not in the mesophyll cells of transgenic F. bidentis plants. In addition, GUS activity could be detected in the vascular bundles. Here, GUS activity was clearly visible in minor veins but very low in major veins.

The expression of the reporter gene in the bundle-sheath cells and the absence of GUS activity in the mesophyll are consistent with the accumulation pattern of the GLDPA RNA. The additional activity of the GUS reporter gene in the vascular tissue, however, is in contrast to the lack of detectable GLDPA RNA in this tissue. There are two possible explanations that could account for this discrepancy in the patterns of RNA accumulation and reporter gene activity. First, there could be additional cis-regulatory sequences further upstream within the introns or even downstream of the GLDPA gene that might control GLDPA transcription in the natural genome context, but are absent in the GLDPA-Ft promoter-GUS construct. These elements would be required for repressing reporter gene expression in the vascular tissue. Alternatively, the absence of GLDPA mRNA in the vascular tissue might be caused by the low GLDPA RNA stability in this tissue (Parker and Song, 2004; Moore, 2005). While the 5' untranslated region of the GLDPA mRNA is included in the GLDPA promoter construct, the 3' untranslated segment is not. If this latter RNA segment or the coding region contains stability determinants leading to degradation of the GLDPA mRNA in the vascular tissue, the GUS mRNA lacking these segments would accumulate.

Interestingly, expression of the GLDPA promoter-GUS construct in transgenic Arabidopsis showed a spatial activity of the GLDPA promoter that was very similar to that observed in transgenic F. bidentis (Fig. 3). As found for the C₄ species, the GLDPA promoter of F. trinervia was inactive in the leaf mesophyll of the C₃ plant Arabidopsis, but active in the bundle-sheath cells and the vascular bundle. The level of reporter gene expression was similar in both species. We therefore conclude that the C₄-characteristic cis-regulatory transcriptional determinants are recognized in the same spatial manner also in the C₃ context. This indicates that the transcription factors necessary for the correct interpretation of these cis-regulatory sequences are already present in this C₃ species and are operating in the same spatial pattern. Moreover, the similar spatial expression profiles in C₄ and C₃ leaves allow us to conclude that the gene regulatory networks operating in mesophyll and bundle-sheath cells of dicot C₃ and C₄ species share common elements, as it was previously proposed by Matsuoka et al. (1993).

The exact physiological and biochemical functions of bundle-sheath cells in C₃ species are poorly understood. They are involved in phloem loading and unloading (van Bel, 1993), and for tobacco (Nicotiana tabacum) it was shown that the bundle-sheath cells of stems and petioles exhibit high activities of enzymes characteristic of C₄ photosynthesis, thus allowing the decarboxylation of four-carbon organic acids derived from the xylem and phloem (Hibberd and Quick, 2002). Additionally, a class of Arabidopsis mutants termed dov (differential development of vascular associated cells) demonstrates that differential chloroplast development occurs between bundle-sheath and mesophyll cells in the Arabidopsis leaf (Kinsman and Pyke, 1998).

These observations from tobacco and Arabidopsis provide some evidence that bundle-sheath cells in C₃ plants are somehow predetermined to evolve C₄-characteristic features. The special physiology of bundle-sheath cells in Arabidopsis and the fact that preexisting transcription factors in this C₃ species are able to recognize heterologous C₄-characteristic cis-regulatory elements in the correct fashion provide further evidence for the view that the evolution of C₄ plants must have been relatively simple in genetic terms (Westhoff and Gowik, 2004). C₄-like spatial activities of C₄ promoters in transgenic C₃ plants have also been reported for the C₄ isoform of PEPC of maize (Zea mays; Matsuoka et al., 1994; Nomura et al., 2000), the pyruvate orthophosphate dikinase gene of maize (Matsuoka et al., 1993), and the phosphoenolpyruvate carboxykinase of Zoysia japonica (Nomura et al., 2005). On the other hand, the C₄-PEPC promoter of F. trinervia loses mesophyll specificity when it is introduced in Arabidopsis (Akyildiz et al., 2007). Similarly, the NADP-dependent malic enzyme promoter from maize loses its bundle-sheath specificity in rice (Oryza sativa; Nomura et al., 2005). This shows that the functionality of C₄-specific regulatory cis-elements in C₃ plants cannot be generalized.

The C₄-like expression pattern of the GLDPA-Ft promoter in Arabidopsis provided us with the possibility to dissect the functional organization of this promoter in Arabidopsis. A series of GLDPA promoter deletion and recombination constructs were analyzed, and two major functional modules were identified and localized, a non-cell-type-specific transcriptional enhancer and a segment that represses gene expression in mesophyll cells.

The transcriptional enhancer is located within the outermost distal regions 1 and 2 of the GLDPA promoter comprising base pairs –1,571 to –1,139. The enhancer functioned in all interior leaf tissues of Arabidopsis, i.e. in mesophyll and bundle-sheath cells as well as in the vascular bundle. The transcription-enhancing activity of these regions was not restricted to the context of the GLDPA promoter but was also functional when combined with the proximal part of the ppcA1 promoter of F. trinervia. The enhancer is thus not GLDPA gene specific but functions as a general enhancer module.

The quantitative analysis of promoter activities (Fig. 4D) indicates that region 1 has a higher potential for transcriptional enhancement than region 2. A search for known cis-regulatory elements (Prestridge, 1991; Higo et al., 1999) revealed the presence of a motif with similarity to the simian virus 40 enhancer core (GTGGWWHG) at positions –1,455 to –1,448 in region 1. This motif is also present in a region of the GLDPA promoter of Flaveria pringlei that is associated with an increase in expression quantity (Bauwe et al., 1995).

Region 3 (–1,138 to –927) harbors cis-regulatory elements that confer cell specificity to the GLDPA promoter by repressing its activity in the mesophyll cells of the Arabidopsis leaf. A chimeric promoter consisting of the transcription-enhancing regions 1 and 2, region 3, and the proximal basal expression region 7 is also not active in the mesophyll cells of the C₄ species F. bidentis. This indicates that region 3 can repress expression in mesophyll cells also in the C₄ context, i.e. the mesophyll-repressing function of region 3 is conserved between the C₃ and the C₄ species. The lack of GLDPA expression in the mesophyll is thus caused by transcriptional regulation and not by posttranscriptional regulation as it was reported for the FbRbcS1 gene of F. bidentis. FbRbcS1 encodes the small subunit of Rubisco, and its bundle-sheath-specific expression is entirely established by selective rbcS transcript stabilization in the bundle-sheath cells (Patel et al., 2006).

Additional mesophyll-repressing cis-regulatory sequences are located in region 6 (–521 to –299). They can partially compensate for the lack of the mesophyll-repressing cis-regulatory sequences in region 3, when this segment is not present in the promoter construct. However, these cis-regulatory elements are not able to establish a robust repression of reporter gene activity in the mesophyll cells of Arabidopsis and appear to be of minor importance. This is documented by the cell type-specific expression of construct GLDPA-Ft-1-2-3-7 that consists of the transcription-enhancing regions 1 and 2, region 3, and the proximal basal promoter region 7. GLDPA-Ft-1-2-3-7 directs a C₄-characteristic expression profile in F. bidentis. This demonstrates that the cis-regulatory motives present in region 6 are not necessary for the repression of GLDPA expression in mesophyll cells of this C₄ species. Moreover, we can infer from the expression profile of this truncated promoter that regions 4 and 5 are also not necessary to achieve a C₄-typical GUS expression pattern in both Arabidopsis and F. bidentis. Regarding the mechanism of mesophyll repression, no predictions can be made at this moment, since searching for known cis-regulatory elements in region 3 did not identify any robust candidate motifs.

The cis-regulatory determinants for the mesophyll-specific repression of GLDPA expression in the leaf have not been determined yet, and no other gene system for bundle-sheath-specific expression has been investigated in such detail that its cis- and trans-regulatory elements are known. However, cis-regulatory elements for mesophyll-specific gene expression have recently been identified at the nucleotide level (Gowik et al., 2004; Akyildiz et al., 2007) for the C₄-PEPC gene ppcA1 from F. trinervia. It was found that variation at two positions in a 41-bp element, a G to A transition and the presence or absence of the tetranucleotide CACT, determines whether the promoter is active in all interior tissues of the leaf of transgenic F. bidentis or only in the mesophyll cells (Akyildiz et al., 2007). Hence, for both genes, GLDPA and ppcA1, cell type-specific gene expression is achieved by repressing the activity of the gene in the respective other cell type. Further dissection of repressor regions 3 and 6 within the GLDPA promoter of F. trinervia should allow precise mapping of the involved cis-regulatory elements. Such identification of a bundle-sheath-specific expression module consisting of a cis-regulatory sequence and the corresponding transcription factor would mark an important step in our understanding of the evolution of C₄ photosynthesis. Moreover, this information would also be of great value for attempts to convert a C₃ species into a C₄ species, as it has been proposed for rice (Mitchell and Sheehy, 2006).

	MATERIALS AND METHODS

TOP ABSTRACT RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

 

Construction of Chimeric Promoters

DNA manipulations and cloning were carried out according to Sambrook and Russell (2001). Construct GLDPA-Ft (Cossu, 1997) served as the basis for the series of GLDPA promoter deletions. In GLDPA-Ft, the 5' upstream region of the GLDPA gene of Flaveria trinervia from –1,571 to –1 (+1 describes the first base of the translational start codon) was fused to the GUS cDNA in the binary plant transformation vector pBI121 (CLONTECH Laboratories). Different 5'-deleted fragments of the GLDPA promoter were generated by PCR amplification (Tables I and II ). The primers added an XbaI restriction site at the 5' border of the DNA fragments and an XmaI site at the 3' end. Therefore, the deleted promoters could be inserted into XbaI/XmaI-cut pBI121, resulting in the formation of the constructs GLDPA-Ft-1, GLDPA-Ft-3, GLDPA-Ft-4, GLDPA-Ft-5, and GLDPA-Ft-6. For the production of GLDPA-Ft-2, plasmid GLDPA-Ft was digested with HindIII and Eco72I. The remaining plasmid was purified by gel electrophoresis and blunt ends were generated by treatment with the Klenow fragment of Escherichia coli DNA polymerase I. The vector was religated to form GLDPA-Ft-2. The DNA fragment comprising regions 1 and 2 of the GLDPA-Ft promoter was generated by PCR amplification with primers GLDPA-5'-Xba and Eco72-R. XbaI sites were introduced at both ends of the PCR product, which allowed the insertion of the DNA fragment into XbaI-cut GLDPA-Ft-3, GLDPA-Ft-4, GLDPA-Ft-5, GLDPA-Ft-6, and ppcA-S-Ft (Stockhaus et al., 1994). The resulting plasmid constructs were named GLDPA-Ft-1-2-4-5-6-7, GLDPA-Ft-1-2-5-6-7, GLDPA-Ft-1-2-6-7, GLDPA-Ft-1-2-7, and GLDPA-Ft-1-2-ppcA-PR_Ft. The cloning of construct GLDPA-Ft-1-2-3-7 involved PCR amplification of the promoter region between –1,571 and –927 using primers GLDPA-5'-Xba and gdcs3-R. The PCR product was digested with XbaI and ligated with XbaI-cut GLDPA-Ft-6. The correct orientation of the inserted DNA fragment in GLDPA-Ft-1-2-3-7 was shown by sequencing.

The cloning of construct GLDPA-Ft::mGFP5-ER was achieved by PCR amplification of the mgfp5-ER gene (Haseloff et al., 1997) from genomic DNA of the Arabidopsis (Arabidopsis thaliana) enhancer trap line E2443 (generated by Scott Poethig, http://www.arabidopsis.org/abrc/poethig.jsp) with primers 5'-mGFP5ER-BamHI and 3'-mGFP5ER-SacI. The PCR product was then cloned into BamHI/SacI-cut GLDPA-Ft::H2B:YFP to yield GLDPA-Ft::mGFP5-ER.

Plant Transformation

In all transformation experiments, the Agrobacterium tumefaciens strain AGL1 was used (Lazo et al., 1991). The promoter-GUS constructs were introduced into AGL1 by electroporation. Arabidopsis plants were transformed via the floral dip method according to Clough and Bent (1998). The transformation of Flaveria bidentis was performed as described by Chitty et al. (1994). The integration of the transgenes into the genome of regenerated F. bidentis or T₁ Arabidopsis plants was proved by PCR analyses.

Measurement of GUS Activity and Histochemical Analysis of Reporter Gene Activity

F. bidentis T₀ plants used for GUS analysis were 40 to 50 cm tall and before flower initiation; the Arabidopsis T₁ plants were examined around 3 weeks after germination. Fluorometrical quantification of GUS activity was performed according to Jefferson et al. (1987) and Kosugi et al. (1990). For histochemical analysis of GUS activity, leaves were cut manually with a razorblade and the sections were transferred to incubation buffer (100 mM Na₂HPO₄, pH 7.5, 10 mM EDTA, 50 mM K₄[Fe(CN)₆], 50 mM K₃[Fe(CN)₆], 0.1% (v/v) Triton X-100, 2 mM 5-bromo-4-chloro-3-indolyl-β-D-glucuronid acid). After brief vacuum infiltration, the sections were incubated at 37°C for 1 to 20 h. After incubation, chlorophyll was removed from the tissue by treatment with 70% ethanol. Fluorescence microscopy was performed using a Zeiss Axiophot (Carl Zeiss AG) equipped with an Olympus DP50 camera (Olympus Optical) and a Zeiss GFP imaging filter system (BP 450–490, FT 510, BP 515–565). Bright-field and fluorescence images were overlaid with Adobe Photoshop 7.0 (Adobe Systems). For confocal laser microscopy, a Zeiss LSM 510 with a Plan-Neofluar 25x objective was used. YFP fluorescence was monitored with a 505- to 550-nm band pass emission filter (488-nm excitation line). Chlorophyll autofluorescence was visualized with a long pass 560-nm emission filter.

In Situ RNA Hybridization

Nonradioactive in situ hybridization experiments were performed according to the protocol described by Simon (2002). Embedded leaves of F. bidentis and F. trinervia were cut into cross sections of 20 µm thickness using a standard microtome. For the generation of the GLDPA probe, a 2.4-kb cDNA fragment of the GLDPA gene of F. trinervia was amplified by PCR (primers gdcsF-4 and gdcsR-4; see Table I). The PCR product was digested with BamHI and XhoI and cloned into BamHI/XhoI-cut pBluescript II KS+ (Stratagene). The use of two different RNA polymerases (T3 and T7) then allowed the production of both antisense and sense probes for in situ hybridization.

Supplemental Data

The following materials are available in the online version of this article.

Supplemental Video S1. Histochemical localization of H2B:YFP in Arabidopsis plants transformed with the construct GLDPA-Ft::H2B:YFP by confocal laser microscopy.

Supplemental Video S2. Histochemical localization of H2B:YFP in Arabidopsis plants transformed with the construct GLDPA-Ft::H2B:YFP by confocal laser microscopy.

	ACKNOWLEDGMENTS

 
We thank Smita Kurup for the generous gift of plasmid pBI121-35S::H2B:YFP and Scott Poethig for the donation of the Arabidopsis enhancer trap line E2443. We are indebted to Ute Hoecker for carefully reading the manuscript.

Received December 2, 2007; accepted February 17, 2008; published February 27, 2008.

	FOOTNOTES

 
¹ This work was supported by the Deutsche Forschungsgemeinschaft within the SFB 590. Initial studies on the Flaveria trinervia GLDP gene were funded by the Bundesministerium für Bildung und Forschung (grant to H.B.).

The author responsible for distribution of materials integral to the findings presented in this article in accordance with the policy described in the Instructions for Authors (www.plantphysiol.org) is: Peter Westhoff (west{at}uni-duesseldorf.de).

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^* Corresponding author; e-mail west{at}uni-duesseldorf.de.

	LITERATURE CITED

TOP ABSTRACT RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

 
Akyildiz M, Gowik U, Engelmann S, Koczor M, Streubel M, Westhoff P (2007) Evolution and function of a cis-regulatory module for mesophyll-specific gene expression in the C₄ dicot Flaveria trinervia. Plant Cell 19: 3391–3402[Abstract/Free Full Text]

Bauwe H, Chu C, Kopriva S, Nan Q (1995) Structure and expression analysis of the gdcsPA and gdcsPB genes encoding two P-isoproteins of the glycine-cleavage system from Flaveria pringlei. Eur J Biochem 234: 116–124[ISI][Medline]

Bauwe H, Kolukisaoglu U (2003) Genetic manipulation of glycine decarboxylation. J Exp Bot 54: 1523–1535[Abstract/Free Full Text]

Boisnard-Lorig C, Colon-Carmona A, Bauch M, Hodge S, Doerner P, Bancharel E, Dumas C, Haseloff J, Berger F (2001) Dynamic analyses of the expression of the HISTONE:YFP fusion protein in Arabidopsis show that syncytial endosperm is divided in mitotic domains. Plant Cell 13: 495–509[Abstract/Free Full Text]

Chitty JA, Furbank RT, Marshall JS, Chen Z, Taylor WC (1994) Genetic transformation of the C4 plant, Flaveria bidentis. Plant J 6: 949–956[CrossRef][ISI]

Clough SJ, Bent AF (1998) Floral dip: a simplified method for Agrobacterium-mediated transformation of Arabidopsis thaliana. Plant J 16: 735–743[CrossRef][ISI][Medline]

Cossu R (1997) Charakterisierung der Glycindecarboxylase-Gene von Flaveria trinervia (C₄) und ihre Expression in transgenen Nicotiana tabacum, Flaveria pubescens und Solanum tuberosum. PhD thesis. Universität Hannover, Hannover, Germany

de Veau EJ, Burris JE (1989) Photorespiratory rates in wheat and maize as determined by O-labeling. Plant Physiol 90: 500–511[Abstract/Free Full Text]

Edwards GE, Furbank RT, Hatch MD, Osmond CB (2001) What does it take to be C₄? Lessons from the evolution of C₄ photosynthesis. Plant Physiol 125: 46–49[Free Full Text]

Edwards GE, Ku MSB (1987) Biochemistry of C₃-C₄ intermediates. In MD Hatch, NK Boardman, eds, The Biochemistry of Plants, Vol 10. Academic Press, New York, pp 275–325

Furbank RT, Badger MR (1983) Photorespiratory characteristics of isolated bundle sheath strands of C₄ monocotyledons. Aust J Plant Physiol 10: 451–458[ISI]

Gowik U, Burscheidt J, Akyildiz M, Schlue U, Koczor M, Streubel M, Westhoff P (2004) cis-Regulatory elements for mesophyll-specific gene expression in the C₄ plant Flaveria trinervia, the promoter of the C₄ phosphoenolpyruvate carboxylase gene. Plant Cell 16: 1077–1090[Abstract/Free Full Text]

Haseloff J, Siemering KR, Prasher DC, Hodge S (1997) Removal of a cryptic intron and subcellular localization of green fluorescent protein are required to mark transgenic Arabidopsis plants brightly. Proc Natl Acad Sci USA 94: 2122–2127[Abstract/Free Full Text]

Hatch MD (1987) C₄ photosynthesis: a unique blend of modified biochemistry, anatomy and ultrastructure. Biochim Biophys Acta 895: 81–106

Hermans J, Westhoff P (1992) Homologous genes for the C4 isoform of phosphoenolpyruvate carboxylase in a C3 and a C4 Flaveria species. Mol Gen Genet 234: 275–284[ISI][Medline]

Hibberd JM, Quick WP (2002) Characteristics of C4 photosynthesis in stems and petioles of C3 flowering plants. Nature 415: 451–454[CrossRef][Medline]

Higo K, Ugawa Y, Iwamoto M, Korenaga T (1999) Plant cis-acting regulatory DNA elements (PLACE) database: 1999. Nucleic Acids Res 27: 297–300[Abstract/Free Full Text]

Hylton CM, Rawsthorne S, Smith AM, Jones DA, Woolhouse HW (1988) Glycine decarboxylase is confined to the bundle-sheath cells of leaves of C₃-C₄ intermediate species. Planta 175: 452–459[CrossRef][ISI]

Jefferson RA, Kavanagh TA, Bevan MW (1987) GUS fusions: beta-glucuronidase as a sensitive and versatile gene fusion marker in higher plants. EMBO J 6: 3901–3907[ISI][Medline]

Kinsman EA, Pyke KA (1998) Bundle sheath cells and cell-specific plastid development in Arabidopsis leaves. Development 125: 1815–1822[Abstract]

Kosugi S, Ohashi Y, Nakajima K, Arai Y (1990) An improved assay for beta-glucuronidase in transformed cells: Methanol almost completely suppresses a putative endogenous beta-glucuronidase activity. Plant Sci 70: 133–140

Lazo GR, Stein PA, Ludwig RA (1991) A DNA transformation-competent Arabidopsis genomic library in Agrobacterium. Biotechnology (N Y) 9: 963–967[CrossRef][Medline]

Leegood RC (2002) C(4) photosynthesis: principles of CO(2) concentration and prospects for its introduction into C(3) plants. J Exp Bot 53: 581–590[Abstract/Free Full Text]

Long JJ, Berry JO (1996) Tissue-specific and light-mediated expression of the C₄ photosynthetic NAD-dependent malic enzyme of amaranth mitochondria. Plant Physiol 112: 473–482[Abstract]

Marshall JS, Stubbs JD, Chitty JA, Surin B, Taylor WC (1997) Expression of the C₄ Me1 gene from Flaveria bidentis requires an interaction between 5' and 3' sequences. Plant Cell 9: 1515–1525[Abstract]

Matsuoka M, Kyozuka J, Shimamoto K, Kano-Murakami Y (1994) The promoters of two carboxylases in a C4 plant (maize) direct cell-specific, light-regulated expression in a C3 plant (rice). Plant J 6: 311–319[CrossRef][ISI][Medline]

Matsuoka M, Tada Y, Fujimura T, Kano-Murakami Y (1993) Tissue-specific light-regulated expression directed by the promoter of a C4 gene, maize pyruvate,orthophosphate dikinase, in a C3 plant, rice. Proc Natl Acad Sci USA 90: 9586–9590[Abstract/Free Full Text]

Mitchell PL, Sheehy JE (2006) Supercharging rice photosynthesis to increase yield. New Phytol 171: 688–693[CrossRef][ISI][Medline]

Monson RK, Moore BD, Ku MSB, Edwards GE (1986) Co-function of C₃- and C₄-photosynthetic pathways in C₃, C₄ and C₃-C₄ intermediate Flaveria species. Planta 168: 493–502[CrossRef][ISI]

Moore MJ (2005) From birth to death: the complex lives of eukaryotic mRNAs. Science 309: 1514–1518[Abstract/Free Full Text]

Morgan CL, Turner SR, Rawsthorne S (1993) Coordination of the cell-specific distribution of the four subunits of glycine decarboxylase and serine hydroxymethyltransferase in leaves of C3-C4 intermediate species from different genera. Planta 190: 468–473[CrossRef][ISI]

Neuburger M, Bourguignon J, Douce R (1986) Isolation of a large complex from the matrix of pea leaf mitochondria involved in the rapid transformation of glycine into serine. FEBS Lett 207: 18–22[CrossRef][ISI]

Nomura M, Higuchi T, Ishida Y, Ohta S, Komari T, Imaizumi N, Miyao-Tokutomi M, Matsuoka M, Tajima S (2005) Differential expression pattern of C4 bundle sheath expression genes in rice, a C3 plant. Plant Cell Physiol 46: 754–761[Abstract/Free Full Text]

Nomura M, Sentoku N, Nishimura A, Lin JH, Honda C, Taniguchi M, Ishida Y, Ohta S, Komari T, Miyao-Tokutomi M, et al (2000) The evolution of C4 plants: acquisition of cis-regulatory sequences in the promoter of C4-type pyruvate, orthophosphate dikinase gene. Plant J 22: 211–221[CrossRef][ISI][Medline]

Ohnishi J, Kanai R (1983) Differentiation of photorespiratory activity between mesophyll and bundle sheath cells of C₄ plants. I: Glycine oxidation by mitochondria. Plant Cell Physiol 24: 1411–1420[Abstract/Free Full Text]

Osmond CB, Harris B (1971) Photorespiration during C 4 photosynthesis. Biochim Biophys Acta 234: 270–282[Medline]

Parker R, Song H (2004) The enzymes and control of eukaryotic mRNA turnover. Nat Struct Mol Biol 11: 121–127[CrossRef][ISI][Medline]

Patel M, Siegel AJ, Berry JO (2006) Untranslated regions of FbRbcS1 mRNA mediate bundle sheath cell-specific gene expression in leaves of a C4 plant. J Biol Chem 281: 25485–25491[Abstract/Free Full Text]

Powell AM (1978) Systematics of Flaveria (Flaveriinae-Asteraceae). Ann Mo Bot Gard 65: 590–636[CrossRef]

Prestridge DS (1991) SIGNAL SCAN: a computer program that scans DNA sequences for eukaryotic transcriptional elements. Comput Appl Biosci 7: 203–206[Abstract/Free Full Text]

Rawsthorne S (1992) C₃-C₄ photosynthesis. Linking physiology to gene expression. Plant J 2: 267–274[CrossRef][ISI]

Rawsthorne S, Hylton CM, Smith AM, Woolhouse HW (1988a) Distribution of photorespiratory enzymes between bundle sheath and mesophyll cells in leaves of the C₃-C₄ intermediate species Moricandia arvensis (L.) DC. Planta 176: 527–532[CrossRef][ISI]

Rawsthorne S, Hylton CM, Smith AM, Woolhouse HW (1988b) Photorespiratory metabolism and immunogold localisation of photorespiratory enzymes in leaves of C₃ and C₃-C₄ intermediate species of Moricandia. Planta 173: 298–308[CrossRef][ISI]

Rawsthorne S, Morgan CL, O'Neill CM, Hylton CM, Jones DA, Frean ML (1998) Cellula