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GENETICS, GENOMICS, AND MOLECULAR EVOLUTION

Distinct Roles of the First Introns on the Expression of Arabidopsis Profilin Gene Family Members¹

Department of Biological Sciences, Seoul National University, Seoul 151–742, Republic of Korea (Y.-M.J., J.-H.M., I.L., C.B.H., S.-G.K.); and Department of Biology, Mokpo National University, Jeonnam 534–729, Republic of Korea (J.C.W.)

	ABSTRACT

TOP ABSTRACT RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

 
Profilin is a small actin-binding protein that regulates cellular dynamics of the actin cytoskeleton. In Arabidopsis (Arabidopsis thaliana), five profilins were identified. The vegetative class profilins, PRF1, PRF2, and PRF3, are expressed in vegetative organs. The reproductive class profilins, PRF4 and PRF5, are mainly expressed in pollen. In this study, we examined the role of the first intron in the expression of the Arabidopsis profilin gene family using transgenic plants and a transient expression system. In transgenic plants, we examined PRF2 and PRF5, which represent vegetative and reproductive profilins. The expression of the PRF2 promoter fused with the -glucuronidase (GUS) gene was observed in the vascular bundles, but transgenic plants carrying the PRF2 promoter-GUS with its first intron showed constitutive expression throughout the vegetative tissues. However, the first intron of PRF5 had little effect on the reporter gene expression pattern. Transgenic plants containing PRF5 promoter-GUS fusion with or without its first intron showed reproductive tissue-specific expression. To further investigate the different roles of the first two introns on gene expression, the first introns were exchanged between PRF2 and PRF5. The first intron of PRF5 had no apparent effect on the expression pattern of the PRF2 promoter. But, unlike the intron of PRF5, the first intron of PRF2 greatly affected the reproductive tissue-specific expression of the PRF5 promoter, confirming a different role for these introns. The results of a transient expression assay indicated that the first intron of PRF1 and PRF2 enhances gene expression, whereas PRF4 and PRF5 do not. These results suggest that the first introns of profilin genes are functionally distinctive and the first introns are required for the strong and constitutive gene expression of PRF1 and PRF2 in vegetative tissues.

In this study, to identify the regulatory elements controlling profilin gene expression, we examined the effect of an intron of the profilin genes. Although genes encoding profilins are interrupted by two introns, we only tested the first intron, because introns that regulate gene expression are generally located near the 5' region of the gene (Clancy and Hannah, 2002; Rose, 2002), and the first intron was about 4 times longer in length than the second intron. Our results show that the first intron of vegetative profilins (PRF1 and PRF2) plays an important role in strong and constitutive expression in vegetative tissues both in the transgenic and/or transient assay and enhances expression both at the mRNA and at the protein level. We also tested the first intron of reproductive profilins (PRF4 and PRF5) to determine whether a regulatory role of introns is conserved in reproductive profilin. In contrast with PRF1 and PRF2, the first intron of PRF4 and PRF5 did not alter expression patterns significantly. Furthermore, the first intron of PRF2 was able to alter spatial expression patterns of both PRF2 and PRF5 promoters.

	RESULTS

TOP ABSTRACT RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

 

The First Intron of PRF2 Is Required for Strong and Constitutive PRF2 Expression in Vegetative Tissues

Although introns are removed during the mRNA maturation process, some introns are known to enhance or regulate gene expression in various ways. To characterize the role of introns in vegetative profilin gene expression, we have cloned the PRF2 gene and generated two PRF2 promoter-GUS fusion constructs. The first construct, pPRF2-5', includes the 1.6-kb promoter, 5'-untranslated region (UTR), and the start codon fused with the GUS gene in the pBI101 vector. The second construct, pPRF2e-p2i, contains the promoter, the entire first exon including 5'-UTR, the first intron, and 24 bp of the second exon (Fig. 1A ). The short second exon was included for proper intron splicing. Three independent transgenic plants carrying single copies of the pPRF2-5' or pPRF2e-p2i constructs were examined to analyze the quantitative effect of the first intron of PRF2 on gene expression.

View larger version (63K): [in this window] [in a new window]   Figure 1. Histochemical analysis of GUS expression in transgenic Arabidopsis containing pPRF2-5' and pPRF2e-p2i constructs. A, Schematic representations of PRF2 promoter-GUS fusion constructs. The box with PRF2 pr is the promoter region of PRF2; the box with e is the first exon of PRF2; the black box with GUS is the GUS coding region; the line with p2i is the first intron of PRF2; ATG is the start codon. B to G, From pPRF2-5'; H to M, from pPRF2e-p2i; B and H, 3-d-old seedlings; C and I, roots of 3-d-old seedlings; D and J, 15-d-old plants; E and K, rosette leaves; F and L, flowers from 5-week-old plants; G and M, young siliques. GUS staining was performed for 12 h. Scale bars, 1 mm (B, D, E, H, J, and K), 0.2 mm (C, G, I, and M), and 0.5 mm (F and L).

View larger version (21K): [in this window] [in a new window]   Figure 7. Transient expression analysis of various PRF2 and PRF5 promoter-GUS fusion constructs. A, Schematic representation of construction for transient expression. GP at the end of the construct name indicates a vector for transient expression. The white box with m is a 35S minimal promoter; the black box with GUS is the GUS ORF; the thin line with p2i is the first intron of PRF2; the white box with PRF2 pr is the PRF2 promoter region; the white box with e is the first exon of PRF2; ATG is the start codon; ORF is the ORF of PRF2 cDNA; the white boxes with e2 and e3 are the second and third exons of PRF2; the line with p2i-2 is the second intron of PRF2; the gray box with PRF5 pr is the PRF5 promoter region; the gray boxes with e2 and e3 are the second and third exons of PRF5; the lines with p5i and p5i-2 are the first and second introns of PRF5. Arrows indicate the orientation of intron. The numbers in intron deletion constructs indicate the deletion points from the 5' end of the intron. B, Relative normalized GUS activity in percentage. The full name of each construct is the addition of each insert name into the brackets of the vector name. For example, p[p2iF-]35SmGP is the pp2iF-35SmGP construct. Each transfection was performed at least three times. GUS activity was normalized with cotransfected luciferase activity and relative activity of pPRF2eGP was set to 100%. Bars are means ± SD.

To investigate the basis for different expression of pPRF2-5' and pPRF2e-p2i constructs, levels of mRNA and protein were analyzed. The accumulation of GUS transcripts was analyzed by reverse transcription (RT)-PCR analyses. One microgram of total RNA from roots, leaves, stems, and flowers was used for RT, and PCR was performed for 25 cycles to prevent saturation of PCR products. Sequencing of RT-PCR products of pPRF2e-p2i indicated that splicing occurred precisely (data not shown). In all tissues, the transcript level of transgenic plants carrying pPRF2e-p2i was increased when compared to pPRF2-5' (Fig. 2 ), suggesting that different expression occurred at the transcription level. The increased mRNA levels were particularly apparent in the leaf and stem. To examine whether the increase in transcript level is fully reflected in the protein level, protein accumulation in the leaves was analyzed by western-blot analysis and GUS assay (Fig. 3 ). Twenty micrograms of total soluble proteins from the leaves of 4-week-old plants were used for immunoblot analysis with the GUS antibody. Similar to the transcript accumulation pattern, the levels of protein were much higher in pPRF2e-p2i than pPRF2-5' plants. Results of fluorometric GUS assay indicated that pPRF2e-p2i gene expression was enhanced by about 15-fold relative to that of pPRF2-5' (Fig. 3). Thus, the increase in transcript accumulation induced by the first intron was reflected in the GUS protein level. Therefore, strong expression of pPRF2e-p2i is correlated with increased accumulation of the GUS transcript. These results suggest that the role of the first intron of PRF2 is closely related to increasing steady-state mRNA levels.

View larger version (26K): [in this window] [in a new window]   Figure 2. RT-PCR analysis of transcript expression of transgenic Arabidopsis containing pPRF2-5' and pPRF2e-p2i constructs in various tissues. One microgram of total RNA from each organ was used for RT. TUBULIN2 (TUB2) amplified with TUB-F (5'-CTCAAGAGGTTCTCAGCAGTA-3') and TUB-R (5'-CTCAAGAGGTTCTCAGCAGTT-3') primers was used as a control. After electrophoresis of PCR products, it was transferred to the nylon membrane and hybridized with 32P-labeled GUS or TUB2 probes.

View larger version (28K): [in this window] [in a new window]   Figure 3. Western-blot analysis and determination of GUS activity in transgenic Arabidopsis containing pPRF2-5' and pPRF2e-p2i. A, Total soluble protein (20 µg) from mature leaves was loaded per lane and analyzed using monoclonal GUS antibody. B, GUS activity is expressed as pmol 4-methyl-umbelliferone min–1 mg–1 protein. Values are means ± SD (n = 3).

We demonstrated the important role of the first intron in gene expression of PRF2, the vegetative profilin. To determine whether the role of first introns is conserved in a reproductive profilin, we examined the first intron of PRF5. About 1.5 kb of the promoter region of PRF5 and the first exon were translationally fused with the GUS reporter gene in a pPRF5e construct that tests promoter activity. To analyze the intron's role, a pPRF5e-p5i construct, which includes all parts of pPRF5e as well as the first intron of PRF5 with 24 bp of the second exon, was generated. The schematic structures of pPRF5e and pPRF5e-p5i are depicted in Figure 4A . Because we mainly focused on the effect of the intron on the PRF5 spatial expression pattern, we did not isolate the single-copy lines, and more than 10 lines of T1 plants harboring pPRF5e and pPRF5e-p5i constructs were examined for the analysis. GUS histochemical analysis of transgenic plants harboring pPRF5e showed strong expression in pollen. Staining was also observed in the stigmas and anthers. Very weak staining was detected in the upper part of filaments and petals (Table I; Fig. 4D). GUS expression was not detected in 3-d-old seedlings and 15-d-old plants in most lines that were examined (Fig. 4, B and C). Although it is not clear whether GUS staining in other floral organs is an actual expression or just diffusion from pollen, GUS expression of pPRF5e was predominant in pollen. A pollen-specific expression pattern was in agreement with a previous report (Christensen et al., 1996). pPRF5e-p5i, which includes its own first intron within the construct, showed almost identical expression with pPRF5e. GUS staining was not observed in the vegetative tissues of nearly all transgenic plants (Fig. 4, E and F). Like pPRF5e, GUS staining in flowers was mainly detected in the pollen and anthers (Table I; Fig. 4G). These results suggest that the first intron of PRF5 has no significant effect on the expression pattern of the PRF5 gene.

View larger version (65K): [in this window] [in a new window]   Figure 4. Histochemical analysis of GUS expression in transgenic Arabidopsis containing pPRF5e and pPRF5e-p5i constructs. A, Schematic representations of PRF5 promoter-GUS fusion constructs. The gray box with PRF5 pr is the promoter region of PRF5; the gray box with e is the first exon of PRF5; the black box with GUS is the GUS coding region; the line with p5i is the first intron of PRF5; ATG is the start codon. B to D, From pPRF5e; E to G, from pPRF5e-p5i; B and E, 3-d-old seedlings; C and F, 15-d-old plants; D and G, flowers. Scale bars, 0.5 mm (B, D, E, and G), 1 mm (C and F), and 0.1 mm (anthers in small box).

The analysis of transgenic plants carrying PRF2 and PRF5 promoter-GUS fusion constructs revealed that the first intron of PRF2 plays an important role in gene expression, while the first intron of PRF5 has little effect. However, it is unclear whether only the intron itself is responsible for these differences. Other factors, such as interaction between intron and promoter, could be involved in profilin gene expression. Thus, to investigate the roles of introns in detail, introns were exchanged between PRF2 and PRF5. For the construction of pPRF2e-p5i, the first intron of PRF5 was inserted at the 3' end of the first exon in the pPRF2e construct. In the same way, the first intron of PRF2 was introduced into the pPRF5e construct, thus giving pPRF5e-p2i (Fig. 5A ). For efficient splicing, both introns were accompanied with short flanking exons. The resulting constructs were transformed into Arabidopsis, and the expression pattern was analyzed in more than 20 independent T1 plants. In 3-d-old seedlings of pPRF2-p5i, expression was mainly observed in cotyledons and roots (Fig. 5B). This vascular bundle-specific expression was also observed in leaves, petioles, and roots of 15-d-old plants (Fig. 5C). In flowers, expression was observed in the filaments and sepals. No GUS staining was detected in pollen or in anthers (Table I; Fig. 5D). The overall expression patterns of pPRF2-p5i plants were very similar to those of pPRF2-5' (Fig. 1, B–G). These data indicate that the first intron of PRF5 has no significant effect on the expression of the PRF2 promoter. However, unlike the first intron of PRF5, the first intron of PRF2 had significant influence on the expression of the PRF5 promoter. GUS histochemical analysis of pPRF5e-p2i showed strong expression throughout the plant. Deep blue staining was observed in nearly every part of the plant, including root hairs and tips of 3-d-old seedlings (Fig. 5E). The expression pattern was totally different from that of pPRF5e or pPRF5e-p5i (Table I; Fig. 4, B–G). This strong expression was also observed in 15-d-old plants (Fig. 5F). Most of the floral organs, including stigmas, anthers, pollen, filaments, petals, and sepals, also showed GUS expression (Table I; Fig. 5G). This constitutive expression pattern was quite similar to that of pPRF2e-p2i (Fig. 1, H–M). Thus, the properties of the two introns were maintained under heterogeneous promoters, and this confirmed the functional distinctiveness of the two introns. Particularly, the first intron of PRF2 had a significant effect on the expression pattern of both the PRF2 and PRF5 promoters, and this demonstrates that the first intron of PRF2 is responsible for the constitutive expression of pPRF2e-p2i and pPRF5e-p2i.

View larger version (69K): [in this window] [in a new window]   Figure 5. Histochemical analysis of GUS expression in transgenic Arabidopsis containing pPRF2e-p5i and pPRF5e-p2i. A, Schematic representation of promoter-GUS fusion constructs. The white box with PRF2 pr is the promoter region of PRF2; the white box with e is the first exon of PRF2; the line with p2i is the first intron of PRF2; the gray box with PRF5 pr is the promoter region of PRF5; the gray box with e is the first exon of PRF5; the line with p5i is the first intron of PRF5; the black box with GUS is the GUS coding region; ATG is the start codon. B to D, From pPRF2e-p5i; E to G, from pPRF5e-p2i; B and E, 3-d-old seedlings; C and F, 15-d-old plants; D and G, flowers. Scale bars, 0.5 mm (B, D, E, and G), 1 mm (C and F), and 0.1 mm (anthers in small box).

The expression of pPRF2-5' was mainly observed in the vascular bundles of vegetative tissues. But faint GUS staining was detected in nonvascular tissues. In the pPRF2e-p2i plants, GUS staining is slightly stronger in the vascular tissues. In addition, increased expression induced by the intron was observed in the RT-PCR and western-blot analysis. Therefore, it is possible that strong expression of pPRF2e-p2i could be a result of a quantitative increase in the expression pattern of pPRF2-5'. However, the result with pPRF5-p2i suggested that the intron alters the spatial expression pattern of the PRF5 promoter. To determine the role of the intron in detail, GUS staining was performed in 3-d-old seedlings at various incubation times (Fig. 6 ). In pPRF2-5', GUS staining was observed to occur weakly in the vascular bundles of cotyledons after 1-h staining. This vascular expression pattern was maintained and staining intensity was increased according to the staining time. After 12-h staining, weak staining was observed in the vascular bundles and nearby tissues. In pPRF2e-p2i plants, no vascular patterning was observed in the cotyledons after 1-h incubation. The overall parts of the cotyledons were evenly stained. This pattern was maintained after staining for 4, 8, and 12 h. In the roots, a different pattern was observed and maintained in both samples from the beginning. If the intron just increased expression, the early stage of the staining pattern of pPRF2e-p2i would be similar to that of pPRF2-5'. Therefore, these results suggest that the intron does not just increase or enhance gene expression, but instead is also involved in regulating spatial gene expression patterns.

View larger version (50K): [in this window] [in a new window]   Figure 6. GUS staining patterns of transgenic Arabidopsis containing pPRF2-5' and pPRF2e-p2i constructs at various incubation time points. Seedlings grown on Murashige and Skoog medium for 3 d were incubated for 1, 4, 8, and 12 h, respectively, and the reaction was stopped and the tissues cleared by incubation with 100% ethanol.

The results above demonstrate that the first intron of PRF2 enhances gene expression and can induce ectopic expression under the control of a tissue-specific promoter. To determine whether controlling elements exist within the intron, three intron deletion constructs were generated (Fig. 7A ). The resulting constructs were transiently expressed in Arabidopsis leaf mesophyll protoplasts, and normalized GUS activity with cotransfected luciferase activity was taken as a measure of promoter activity. Among the three intron deletions, the intron deletion d1 showed decreased GUS expression when compared to the full-length intron (Fig. 7B). The intron deletion analysis indicates that the enhancing elements would exist within the intron.

To examine the possibility that the first intron of PRF2 acts as an enhancer, the first intron of PRF2 was cloned upstream of the PRF2 promoter-GUS fusion construct in a forward or reverse direction (Fig. 7A). The resulting constructs were transiently expressed in Arabidopsis leaf mesophyll protoplasts. Although both pp2iF-PRF2eGP and pp2iR-PRF2eGP constructs have the intron upstream of the promoter region, their relative GUS activity was similar to that of the pPRF2eGP construct (Fig. 7B). This suggested that the first intron of PRF2 is not a classical enhancer. To further confirm this result, the intron was cloned upstream of the cauliflower mosaic virus 35S minimal promoter-GUS fusion construct (Fig. 7A). There was no detectable enhancer activity under the control of the minimal promoter (Fig. 7B). Therefore, these results demonstrate that the intron is not a classical transcriptional enhancer and it enhances gene expression in a position-dependent manner.

The Role of the First Intron in the Profilin Gene Family

To examine whether the role of the first intron observed in PRF2 and PRF5 gene expression is also applicable to the entire Arabidopsis profilin gene family members, the promoter-GUS fusion constructs with or without their first introns were generated and their expression levels were compared in the Arabidopsis protoplast transient expression system (Fig. 8 ). The promoter-GUS fusion constructs of two vegetative profilins, PRF1 and PRF2, showed comparable changes in the GUS expression level depending on the presence of their own first intron. This suggests that the first introns of PRF1 and PRF2 have similar effects on gene expression. On the contrary, the promoter-GUS fusion constructs of two reproductive profilins, PRF4 and PRF5, showed a basal level GUS activity in leaf mesophyll protoplasts regardless of the presence or absence of their first intron. Because they are not expressed properly in vegetative tissues, it is uncertain whether their introns enhance gene expression or not. Thus, the role of the first introns of PRF4 and PRF5 is not clear in this system. Nonetheless, considering that the first intron of the PRF2 altered the expression pattern of the PRF5 promoter (Fig. 5, E–G), our results indicate that the first introns of reproductive profilin genes are functionally different from those of PRF1 and PRF2. Interestingly, although PRF3 encodes a vegetative-type profilin, the PRF3 promoter-GUS fusion construct was expressed at a basal level and a positive role of the first intron was not detected (Fig. 8B).

View larger version (20K): [in this window] [in a new window]   Figure 8. Effect of the first intron on the expression of the Arabidopsis profilin gene family. A, Schematic representation of construction for transient expression. GP at the end of the construct name indicates a vector for transient expression. The white box is vegetative genes; the gray box is reproductive genes; the white or gray box with e is the first exon of each gene; the black box with GUS is GUS ORF; the thin lines with p1i, p2i, p3i, p4i, and p5i are the first introns of PRF1, PRF2, PRF3, PRF4 and PRF5, respectively; the white or gray box with gene name pr is the promoter region of each gene; ATG is the start codon. B, Relative normalized GUS activity in percentage. A plus (+) indicates the presence of an intron within the construct; a minus (–) indicates no intron. Each transfection was performed at least three times. GUS activity was normalized with cotransfected luciferase activity and relative activity of pPRF2eGP was set to 100%. Bars are means ± SD.

	DISCUSSION

TOP ABSTRACT RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

To further investigate the role of profilin introns, we examined the first intron of the reproductive profilin PRF5. GUS staining with the pPRF5e construct was mainly detected in pollen and anthers. But, unlike the results obtained with the intron of PRF2, GUS expression patterns of the pPRF5e and pPRF5e-p5i constructs were nearly identical (Fig. 4; Table I), indicating that the first intron of PRF5 has little effect on the gene expression pattern. Although the spliceable intron was placed downstream of the first exon of PRF2 (pPRF2e-p5i), there was no significant alteration of expression pattern, confirming that the PRF5 intron had little effect on the gene expression pattern.

The result of intron exchange between PRF2 and PRF5 suggests that the first intron of PRF2 does not just enhance or increase the level of gene expression (Fig. 5). Both pPRF5e and pPRF5e-p5i showed reproductive tissue-specific expression. But, when the first intron was replaced with the intron of PRF2, strong GUS expression was observed throughout the plant body. This expression pattern of pPRF5e-p2i is quite surprising and demonstrates that the PRF2 intron completely changes tissue-specific expression of the PRF5 promoter. To determine whether this also occurred in the expression of PRF2, GUS staining patterns of plants harboring pPRF2-5' and pPRF2e-p2i constructs were analyzed at various incubation times (Fig. 6). If the PRF2 intron just increased the expression level, the expression pattern of pPRF2e-p2i in the early stage of staining would be similar to that of pPRF2-5'. Plants of pPRF2e-p2i incubated for 1 h were stained evenly in the cotyledons and roots, and the staining was obviously different from pPRF2-5' (Fig. 6). Therefore, these results suggest that the first intron of PRF2 is involved in regulating spatial gene expression.

Because the two first introns examined in this study maintained their own properties under the control of both the PRF2 and PRF5 promoters (Fig. 5), the different roles of these introns seem to be the properties of the introns themselves. Although sequences of introns are greatly variable in higher plants, AU richness is common in plant introns and is required for efficient splicing (Goodall and Filipowicz, 1989). Therefore, we analyzed the sequences of our two introns to determine whether there are significant differences in AU content. The AU content of the first intron was slightly lower in PRF2 (64.4%) than in PRF5 (67.7%), but both were similar to the average (67.5%) of Arabidopsis introns (Table II). Because AU content of both introns is above 60%, which is required for efficient splicing in dicot plants (Goodall and Filipowicz, 1989), it is likely that there is no significant difference in AU content. The most remarkable difference between two introns was in the length of them. The first introns of PRF2 and PRF5 are 478 and 260 bp in length, and they were 2.9 and 1.6 times longer than the average length of Arabidopsis introns (165.4 bp), respectively (Table II). Although the biological significance of long introns is not certain at present, long introns may serve as binding sites for various regulatory elements. The results of our intron deletion analysis suggest that the first intron of PRF2 may have the binding motifs or regulatory elements and these are to be specified in further research.

Among the five profilins of Arabidopsis, we mainly examined the role of the first introns on the expression of PRF2 and PRF5 in transgenic plants. Genes encoding vegetative (PRF1 and PRF2) and reproductive (PRF4 and PRF5) profilin are highly similar to each other in many aspects, such as DNA and amino acid sequences, expression patterns, and, especially, the length of the first intron (Table II). These high degrees of similarity seem to be closely related to the evolutionary history of the profilin gene family. In the Arabidopsis genome, genes encoding PRF1 and PRF5 are located in chromosome 2, and PRF2 and PRF4 are located in chromosome 4 where they are arranged in tandem arrays. Interestingly, both of the PRF1 and PRF2 genes encoding vegetative profilins are flanked with a gene encoding a reproductive profilin. Considering that about 60% of the Arabidopsis genome was duplicated (Arabidopsis Genome Initiative, 2000), this suggests that one set of tandem arrayed profilin genes was duplicated to give two sets. Therefore, we expected that the role of the first intron on gene expression would also be similar. As expected, only the first introns of PRF1 and PRF2 increased reporter activity, while the first introns of PRF4 and PRF5 did not. These results indicate that different regulatory mechanisms by introns control gene expression in vegetative (except PRF3) and reproductive profilins. Considering that PRF1 and PRF2 are major vegetative profilins, our data demonstrate that their first introns are required for their strong and constitutive expression in vegetative tissues. In this respect, the PRF3 gene is unique among profilin genes as shown in Table II. The PRF3 gene is not coupled with other profilin genes in the Arabidopsis genome, and the length of the first intron was smaller than other vegetative profilins, PRF1 or PRF2. The total number of PRF3 expressed sequence tags (ESTs) found in the National Center for Biotechnology Information (NCBI) and The Institute for Genomic Research (TIGR) databases was only 25% of PRF1 or PRF2, indicating that PRF3 is not expressed as much as PRF1 or PRF2. Our results indicating that PRF3 promoter-GUS fusion constructs showed basal levels of expression in the transient expression system also support the above explanation (Fig. 8). At present, we do not know whether weak expression of PRF3 is due to loss of intron-enhancing activity or significantly reduced promoter activity. Therefore, further examination of PRF3 gene expression would provide additional clues for understanding the importance of introns on expression of the profilin gene family.

Recently, the effect on gene expression of the leader intron in the Arabidopsis ACT1 gene encoding reproductive actin was reported. ACT1 is expressed most strongly in mature pollen, but it is also expressed in vegetative tissues, such as young vascular tissues and root tips. The leader intron was found to be required for the high-level expression of ACT1 in reproductive tissues. In addition, substituting its leader intron with that of ACT2 into an ACT1 promoter-GUS fusion resulted in failure of expression in pollen (Vitale et al., 2003). Although only two introns under the control of a reproductive actin promoter were tested, at least these results suggest that introns play a role in actin gene expression. Therefore, it is possible that a role of introns in gene expression may have coevolved in the cytoskeletal genes.

In this study, we have demonstrated that the first introns of PRF1 and PRF2 play an important role in constitutive expression in most vegetative tissues and are functionally different from those of PRF4 and PRF5. And we have discussed the possible importance of introns in the expression of profilin and actin genes. In future research, we will determine how the intron of the vegetative profilin genes affects gene expression and also examine the role of introns in the expression of various cytoskeletal genes.

	MATERIALS AND METHODS

TOP ABSTRACT RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

 

Plant Materials and Construction of Promoter-GUS Fusions for Transgenic Plants

Arabidopsis (Arabidopsis thaliana) ecotype Columbia was grown in a growth chamber (23°C, 16 h day/8 h night, 300 µE m^–2). For construction of PRF2 promoter fusions, the 1.6-kb promoter region, including up to a 5'-UTR and the start codon (pPRF2-5'), the entire exon 1 (pPRF2e), and the first intron (pPRF2e-p2i), was amplified using P2-F (5'-GTCGACAATGTTCCACCACCTAC-3'), P2-R (5'-GGATCCCATCTTTCTTCTTCTCC-3'), P2e-R (5'-AGGAAGAAAAACGGATCCCTGAGGGAAAG-3'), and P2i-R (5'-GGATCCTGCTATCTCTGCAGG-3') primers, respectively. The PCR products were cloned into the pGEM-T easy vector (Promega) and confirmed by sequencing. The cloned fragments were digested with SalI/BamHI and ligated into the pBI101 vector (CLONTECH). Similar methods were used for construction of PRF5 promoter fusions, pPRF5e and pPRF5e-p5i, using PRF5-specific primers: P5-F (5'-AAGCTTCTGGTCCTGTATTTGCCTAACCAAG-3'), P5e-R (5'-GGATCCCTGAGGAAAATTAGCGCTCTGAG-3'), and P5i-R (5'-GGATCCTGTGATCTCTTGAGGTTTGAAC-3'). For intron exchange experiments, introns were amplified with P2int-F (5'-GGATCCGCTTTCCCTCAGGTTTTTCTTC-3') and P2i-R for the first intron of PRF2 and with P5int-F (5'-GGATCCAATTTTCCTCAGGTATAATTAC-3') and P5i-R for the intron of PRF5. Amplified introns were inserted into the BamHI site of pPRF2e or pPRF5e. The resulting constructs were inserted into Agrobacterium tumefaciens strain C58C1Rif⁺.

Plant Transformation and GUS Histochemical Analysis

Transgenic Arabidopsis was generated by the floral-dip method (Clough and Bent, 1998). Transformed plants were selected on 0.5x Murashige and Skoog 0.8% (w/v) agar plates containing 50 mg L^–1 kanamycin and 100 mg L^–1 cefotaxim. For analysis of pPRF2-5' and pPRF2e-p2i lines, T1 transgenic plants were self-pollinated, and single-copy lines were selected by Southern-blot analysis and tested for the segregation ratio of T2 seeds on agar plates containing kanamycin. The selected single home lines were used for further analysis. Histochemical and fluorometric analysis of GUS activity was performed as described previously (Mun et al., 2002). Images were obtained using either Nikon (Tokyo) Coolpix 4500 or Stemi SV11 (Zeiss) with photomatrix Coolsnap cf digital camera (Photomatrix).

RT-PCR Analysis

To investigate the expression patterns of the GUS transcripts in transgenic Arabidopsis, RT-PCR analyses were performed. Total RNA was purified from leaves of mature plants by Tri-Reagent (Molecular Research Center). One microgram of total RNA was used for RT in a volume of 25 µL and incubated at 42°C for 1 h with avian myeloblastosis virus reverse transcriptase and oligo(dT) primer (Promega), and inactivated by incubating for 5 min at 95°C. After completion of RT, 2 µL of RT products were amplified using P2RT-F (5'-AAACAGTCTCATCTCGCCGGAGAAG-3') and GUSRT-R (5'-AAAGACTTCGCGCTGATACCAGAC-3') primers. PCR was performed using Biotherm DNA polymerase (Genecraft) in a GeneAmp PCR system 9700 (Perkin-Elmer). The PCR condition was 5 min at 95°C, followed by 25 cycles of 30 s at 94°C, 30 s at 55°C, and 30 s at 72°C, followed by 7 min at 72°C. The PCR products were run on agarose gel, transferred to Hybond XL membranes (Amersham), and hybridized. Probes were generated from GUS ORF from pBI101 and radiolabeled with [-³²P]dCTP using the Rediprime II random prime system (Amersham). After high stringent washing, blots were exposed to the film. To confirm that correct splicing had occurred, RT-PCR products were cloned into the pGEM-T easy vector and sequenced using the ABI 3100 sequence analyzer (Applied Biosystems).

Western-Blot Analysis

Monoclonal GUS antibody (Molecular Probes) was used at a titer of 1:5,000 for western-blot analysis. Twenty micrograms of total soluble proteins from leaves were loaded per lane. Western-blot analysis was performed as described previously (Mun et al., 2000).

Sequence Analysis of Arabidopsis Profilin Genes

The genomic sequences of five profilin genes in Arabidopsis were obtained from Plant Genome Central at the NCBI (http://www.ncbi.nlm.nih.gov/genomes/PLANTS/PlantList.html). The total numbers of ESTs cloned were obtained from Unigene (http://www.ncbi.nlm.nih.gov/UniGene/) and TIGR (http://www.tigr.org). The average length and AU content of the Arabidopsis intron was calculated based on whole intron sequences obtained from The Arabidopsis Information Resource (TAIR; ftp://ftp.arabidopsis.org/home/tair/Sequences/blast_datasets/At_intron_20040301).

Transient Expression Analysis in Arabidopsis Leaf Mesophyll Protoplasts

For transient gene expression, the HindIII and EcoRI fragment from pBI101, which includes the GUS gene, was inserted into pUC19 and named as a pGP. The minimal promoter region of pBI121 was amplified with 35sm-F (5'-CTGCAGTCGACGCAAGACCCTTCCTCTATA-3') and GUSRT-R primers and the PstI/BamHI fragment was ligated into pGP to generate p35smGP. For construction of pp2iF-35smGP and pp2iR-35smGP, the first intron of PRF2, which was amplified with P2int-sal-F (5'-GTCGACGCTTTCCCTCAGGTTTTTCTTC-3') and P2int-sal-R (5'-GTCGACTGCTATCTCTGCAGGCTTCAA-3') primers, was inserted into the SalI site of p35smGP. The SalI/BamHI fragments of PRF2 and PRF5 promoter-GUS fusion constructs in pBI101 were cloned into pGP (Fig. 8A). For construction of pp2iF-PRF2eGP and pp2iR-PRF2eGP, the first intron of PRF2 was inserted into the SalI site of pPRF2eGP. To make pP2ORFGP, the SalI/BamHI fragment of the pPRF2-5' construct was ligated into pGP, thus generating pPRF2-5'GP, and the ORF of the PRF2 gene was amplified with P2orf-F (5'-GGATCCATGTCGTGGCAATCATACGTC-3') and P2orf-R (5'-GGATCCGAGACCAGACTCGATAAGGTAATC-3') primers using cDNA made from total RNA and inserted into the BamHI site of pPRF2-5'GP. The genomic region was amplified with P2-F and P2orf-R for pPRF2geGP and P5-F and P5orf-R (5'-GGATCCAAGACCCTGTTCGATCAAGTAATC-3') for pPRF5geGP and ligated into pGP vector. For construction of intron deletion constructs, P2id1-R (5'-TTATTTGAGACAGAGGATCGGAAGAAAC-3'), P2id1-F (5'-AGTCGGTTGAAGCTAATTGCCTACTTTG-3'), p2id2-R (5'-ACACCTATAGACAAGATTTGACTACTG-3'), and p2id3-F (5'-TTTGCTTGGCACAGAATCTTATCTCC-3') were used. Schematic representation of these transient vectors is depicted in Figure 7A. For construction of PRF1, PRF4, and PRF3 promoter-GUS fusions, genomic fragments were amplified with the following gene-specific primers: for PRF1, P1-F (5'-AAGCTTCATATACATACCAAAGCCATCATGGA-3'), P1e-R (5'-GGATCCCTGAGGAAATTTGGCGCTCTGAGC-3'), and P1i-R (5'-GGATCCATCGATTTCTTGAGGCTTCAAC-3'); for PRF3, P3-F (5'-AAGCTTCCCATAGAAAGCAATGTATATGCTC-3'), P3e-R (5'-GGATCCCTGAGGAAAATTGTTGCTCTGAGCC-3'), and P3i-R (5'-GGATCCCTGAATTTCCTCAGGCTTCACCTA-3'); and for PRF4, P4-F (5'-AAGCTTTTATCAGTCATACCATTTTTCTGGAC-3'), P4e-R (5'-GGATCCCTGAGGGAAGTTGGCGCTCTGAGCC-3'), and P4i-R (5'-GGATCCACTGAACTCCTGTCCCTTGAACTATATG-3'). They were inserted into the HindIII/BamHI sites of pGP (Fig. 8A). For construction of p35SLucP, the internal control for transient expression analysis, the 35S promoter region from pBI121 and the gene encoding a firefly luciferase amplified with Luc-F (5'-GGATCCATGGAAGACGCCAAAAACATAAAG-3') and Luc-R (5'-GAGCTCTTACACGGCGATCTTTCCGCCCT-3') primers using pGL3-promoter vector (Promega) were introduced into the HindIII/SacI sites of the pGP vector.

Arabidopsis mesophyll protoplasts from 3-week-old plants were transfected by the polyethylene glycol method (Sheen, 2002). Ten micrograms of plasmid DNA containing promoter-GUS fusion constructs were cotransfected with 10 µg of p35SLucP as an internal control. After transfection, protoplasts were incubated for 24 h at 24°C in the dark. Proteins were extracted by 1x cell culture lysis reagent buffer (Promega) and used for the GUS fluorometric and luciferase assay. Luciferase assay was performed according to the manufacturer's instructions (Promega) using the Victor2 multilabel microplate reader (Perkin-Elmer).

	ACKNOWLEDGMENTS

 
The authors wish to express sincere thanks to Prof. Donald J. Armstrong (Oregon State University) for helpful discussions and critical review. We would also like to thank Hyung-Seok Choi for help with analyzing sequences of the Arabidopsis whole intron.

Received September 21, 2005; returned for revision November 9, 2005; accepted November 10, 2005.

	FOOTNOTES

 
¹ This work was supported by the Ministry of Education and Human Resources Development (BK21 Research Fellowship to Y.-M.J.).

² Present address: Department of Plant Pathology, University of California, Davis, CA 95616.

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: Sang-Gu Kim (kimsg{at}plaza.snu.ac.kr).

Article, publication date, and citation information can be found at www.plantphysiol.org/cgi/doi/10.1104/pp.105.071316.

^* Corresponding author; e-mail kimsg{at}plaza.snu.ac.kr; fax 82–2–878–7256.

	LITERATURE CITED

TOP ABSTRACT RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

 
Arabidopsis Genome Initiative (2000) Analysis of the genome sequence of the flowering plant Arabidopsis thaliana. Nature 408: 796–815[CrossRef][Medline]

Balska F, Jásik J, Edelmann HG, Salajová T, Volkmann D (2001) Latrunculin B induced plant dwarfism: plant cell elongation is F-actin dependent. Dev Biol 231: 113–124[CrossRef][Web of Science][Medline]

Bamburg JR, McGough A, Ono S (1999) Putting a new twist on actin: ADF/cofilins modulate actin dynamics. Trends Cell Biol 9: 364–370[CrossRef][Web of Science][Medline]

Bolle C, Herrmann RG, Oelmuller R (1996) Intron sequences are involved in the plastid- and light-dependent expression of the spinach PsaD gene. Plant J 10: 919–924[CrossRef][Web of Science][Medline]

Bourdon V, Harvey A, Lonsdale DM (2001) Introns and their positions affect the translational activity of mRNA in plant cells. EMBO Rep 2: 394–398[Web of Science][Medline]

Callis J, Fromm M, Walbot D (1987) Introns increase gene expression in cultured maize cells. Genes Dev 1: 1183–1200[Abstract/Free Full Text]

Christensen HEM, Ramachandran S, Tan CT, Surana U, Dong CH, Chua NH (1996) Arabidopsis profilins are functionally similar to yeast profilins: identification of a vascular bundle-specific profilin and a pollen-specific profilin. Plant J 10: 269–279[CrossRef][Web of Science][Medline]

Clancy M, Hannah LC (2002) Splicing of the maize Sh1 first intron is essential for enhancement of gene expression, and a T-rich motif increases expression without affecting splicing. Plant Physiol 130: 918–929[Abstract/Free Full Text]

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

Deyholos MK, Sieburth LE (2000) Separable whorl-specific expression and negative regulation by enhancer element within the AGAMOUS second intron. Plant Cell 12: 1799–1810[Abstract/Free Full Text]

Fu H, Kim SY, Park WD (1995) A potato Sus3 sucrose synthase gene contains a context-dependent 3' element and a leader intron with both positive and negative tissue-specific effects. Plant Cell 7: 1395–1403[Abstract]

Gibbon BC, Staiger CJ (2000) Profilin. In CJ Staiger, F Baluka, D Volkmann, P Barlow, eds, Actin: A Dynamic Framework for Multiple Plant Cell Functions. Kluwer Academic Publishers, Dordrecht, The Netherlands, pp 45–65

Goodall GJ, Filipowicz W (1989) The AU-rich sequences present in the introns of plant nuclear pre-mRNAs are required for splicing. Cell 58: 473–483[CrossRef][Web of Science][Medline]

Guillen G, Valdes-Lpoez V, Noguez R, Oliveares J, Rodriguez-Zapata LC, Perez H, Viali L, Villanueva MA, Sanchez F (1999) Profilin in Phaseolus vulgaris is encoded by two genes (only one expressed in root nodules) but multiple isoforms are generated in vivo by phosphorylation on tyrosine residues. Plant J 19: 497–508[CrossRef][Web of Science][Medline]

Huang S, McDowell JM, Weise MJ, Meagher RB (1996) The Arabidopsis profilin gene family: evidence for an ancient split between constitutive and pollen-specific profilin genes. Plant Physiol 111: 115–126[Abstract]

Jeon JS, Lee S, Jung KH, Jun SH, Kim C, An G (2000) Tissue-preferential expression of a rice -tubulin gene, OsTubA1, mediated by the first intron. Plant Physiol 123: 1005–1014[Abstract/Free Full Text]

Kandasamy MK, McKinney EC, Meagher RB (2002) Plant profilin isovariants are distinctly regulated in vegetative and reproductive tissues. Cell Motil Cytoskeleton 52: 22–32[CrossRef][Web of Science][Medline]

Kost B, Mathur J, Chua NH (1999) Cytoskeleton in plant development. Curr Opin Plant Biol 2: 462–467[CrossRef][Web of Science][Medline]

Kovar DR, Drøbak BK, Staiger CJ (2000) Maize profilin isoforms are functionally distinct. Plant Cell 12: 583–598[Abstract/Free Full Text]

McKinney EC, Kandasamy MK, Meagher RB (2001) Small changes in the regulation of one Arabidopsis profilin isovariant, PRF1, alter seedling development. Plant Cell 13: 1179–1191[Abstract/Free Full Text]

Meagher RB, McKinney EC, Vitale AV (1999) The evolution of new structures: clues from plant cytoskeletal genes. Trends Genet 15: 278–284[CrossRef][Web of Science][Medline]

Mittermann I, Swoboda I, Pierson E, Eller N, Kraft D, Valenta R, Heberle-Bors E (1995) Molecular cloning and characterization of profilin from tobacco (Nicotiana tabacum): increased profilin expression during pollen maturation. Plant Mol Biol 27: 137–146[CrossRef][Medline]

Mun JH, Lee SY, Yu HJ, Jeong YM, Shin MY, Kim H, Lee I, Kim SG (2002) Petunia actin depolymerizing factor is mainly accumulated in vascular tissue and its gene expression is enhanced by the first intron. Gene 292: 233–243[CrossRef][Web of Science][Medline]

Mun JH, Yu HJ, Lee HS, Kwon YM, Lee JS, Lee I, Kim SG (2000) Two closely related cDNAs encoding actin-depolymerizing factors of petunia are mainly expressed in vegetative tissues. Gene 257: 167–176[Medline]

Plesse B, Criqui MC, Durr A, Parmentier Y, Fleck J, Genschik P (2001) Effects of the polyubiquitin gene Ubi. U4 leader intron and first ubiquitin monomer on reporter gene expression in Nicotiana tabacum. Plant Mol Biol 45: 655–667[CrossRef][Web of Science][Medline]

Ramachandran S, Christensen HE, Ishimaru Y, Dong CH, Chao-Ming W, Cleary AL, Chua NH (2000) Profilin plays a role in cell elongation, cell shape maintenance, and flowering in Arabidopsis. Plant Physiol 124: 1637–1647[Abstract/Free Full Text]

Rethmeier N, Kramer E, Van Montagu M, Cornelissen M (1997) Intron-mediated enhancement of transgene expression in maize is a nuclear, gene-dependent process. Plant J 12: 895–899[CrossRef][Web of Science][Medline]

Rose AB (2002) Requirements for intron-mediated enhancement of gene expression in Arabidopsis. RNA 8: 1444–1453[Abstract]

Rose AB (2004) The effect of intron location on intron-mediated enhancement of gene expression in Arabidopsis. Plant J 40: 744–751[CrossRef][Web of Science][Medline]

Rose AB, Last RL (1997) Introns act post-transcriptionally to increase expression of the Arabidopsis thaliana tryptophan pathway gene PAT1. Plant J 11: 455–464[CrossRef][Web of Science][Medline]

Schobert C, Gottschalk M, Kovar DR, Staiger CJ, Yoo BC, Lucas WJ (2000) Characterization of Ricinus communis phloem profilin, RcPRO1. Plant Mol Biol 42: 719–730[CrossRef][Web of Science][Medline]

Sheen J (2002) A transient expression assay using Arabidopsis mesophyll protoplasts. http://genetics.mgh.harvard.edu/sheenweb/ (September 15, 2004)

Sheldon CC, Conn AB, Dennis ES, Peacock WJ (2002) Different regulatory regions are required for the vernalization-induced repression of FLOWERING LOCUS C and for the epigenetic maintenance of repression. Plant Cell 14: 2527–2537[Abstract/Free Full Text]

Staiger CJ, Goodbody KC, Hussey PJ, Valenta R, Drøbak BK, Lloyd CW (1993) The profilin multigene family of maize: differential expression of three isoforms. Plant J 4: 631–641[CrossRef][Web of Science][Medline]

Valenta R, Duchene M, Pettenburger K, Sillaber C, Valent P, Bettelheim P, Breitenbach M, Rumpold H, Kraft D, Scheiner O (1991) Identification of profilin as a novel pollen allergen; IgE autoreactivity in sensitized individuals. Science 253: 557–560[Abstract/Free Full Text]

Valenta R, Ferreira F, Grote M, Swoboda I, Vrtala S, Duchene M, Deviller P, Meagher RB, McKinney E, Heberle-Bors E, et al (1993) Identification of profilin as an actin-binding protein in higher plants. J Biol Chem 268: 22777–22781[Abstract/Free Full Text]

Vidali L, Perez HE, Lopez VV, Noguez R, Zamudio F, Sanchez F (1995) Purification, characterization, and cDNA cloning of profilin from Phaseolus vulgaris. Plant Physiol 108: 115–123[Abstract]

Vitale A, Wu RJ, Cheng Z, Meagher RB (2003) Multiple conserved 5' elements are required for high-level pollen expression of the Arabidopsis reproductive actin ACT1. Plant Mol Biol 52: 1135–1151[Medline]

Yu LX, Nasrallah J, Valenta R, Parthasarathy MV (1998) Molecular cloning and mRNA localization of tomato pollen profilin. Plant Mol Biol 36: 699–707[Medline]

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