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Plant Cell Physiol. 46(5): 797–802 (2005) doi:10.1093/pcp/pci075, available online at www.pcp.oupjournals.org JSPP © 2005 Short Communication Transcriptional Activity of Male Gamete-specific Histone gcH3 Promoter in Sperm Cells of Lilium longiflorum Takashi Okada 1, Prem L. Bhalla and Mohan B. Singh 2 Plant Molecular Biology and Biotechnology Laboratory, ARC Centre of Excellence for Integrative Legume Research, Institute of Land and Food Resources, The University of Melbourne, Parkville, Victoria 3010, Australia ; associated with the linker DNA connecting nucleosomal cores, termed linker histones. Histone genes can be subdivided into three major groups according to their gene expression profile, replication-dependent, replication-independent and tissue-specific histones (Witt et al. 1996). Many plant histone genes have been studied, and several transcriptional regulatory elements coupled with cell proliferation have been identified (Meshi et al. 1998, Meshi et al. 2000). The OCT motif in the histone promoter has been identified as a cis-acting element involved in proliferation-coupled and S phase-specific expression. Almost all plant histone gene promoters in the genome databases contain at least one OCT motif in their proximal regions (Meshi et al. 2000). During mammalian spermatogenesis, testis-specific histone variants that show preferential expression in spermatogonia, spermatid or sperm during spermatogenic development have been reported (Grimes et al. 1990, Lim and Chae 1992, Witt et al. 1996, Zalensky et al. 2002). The mammalian testisspecific linker histone H1t gene is transcriptionally active in pachytene primary spermatocytes and repressed in all other germinal and non-germinal cell types. The TE1, GC box 1 and TG box have been identified as transcriptional activators that interact with a nuclear protein leading to up-regulation of H1t gene expression in spermatocytes. In contrast, GC box 2, RE and TE2 have been reported as repressor elements that also interact with nuclear proteins involved in silencing of the H1t gene in non-germinal cells (Clare et al. 1997, Grimes et al. 2003). Therefore, H1t gene expression is controlled by upregulation in germline cells and suppression in non-germline cells mediated by several transcriptional regulators. In flowering plants, we previously have reported male gamete-specific histone variants, gcH2A and gcH3, expressed in lily generative cells (Xu et al. 1999a), and other variants gH2A, gH2B and gH3 in lily have also been reported (Ueda and Tanaka 1995, Ueda et al. 2000). The expression profile of these genes is similar to that of mammalian testis-specific histone genes; up-regulation in male gametic cells and silencing in sporophytic tissues. These observations led us to hypothesize that plants might have a similar mechanism to regulate male gametic cell-specific gene expression of histone variant genes. Histones are essential for packaging of eukaryotic genomic DNA in nucleosomes, and histone gene expression is normally coupled with DNA synthesis. Some of the flowering plant histone genes show strictly male gamete-specific expression. However, mechanisms underlying their male gamete-specific expression have not been elucidated so far. Here we report the isolation of the male gamete-specific histone gcH3 promoter from Lilium longiflorum and its activity in the male gametic cell of the flowering plant. The OCT motif, which is well conserved in plant histone promoters regulating S phase-specific expression, is not conserved in the gcH3 promoter. Instead sequence motifs identical to GC box 1 and GC box 2, the transcriptional activator and suppressor for mammalian testis-specific histone H1t, are present in the gcH3 promoter, suggesting that plants and animals share the mechanism which governs the specificity of gene expression in male gametic cells. Male gamete-specific activation of the gcH3 promoter has been confirmed by microprojectile bombardment in lily pollen. The sperm cell carrying gold particles showed reporter gene expression, while green fluorescent protein (GFP) was absent in the other sperm cell which had no particles, confirming that the gcH3 promoter is activated in the male gametic cell, and sperm cells have transcriptional and translational machinery that is independent of the vegetative cell of pollen. Keywords: Generative cell — GFP — Histone H3 — Male gamete — Promoter — Sperm cell. Abbreviations: DAPI, 4′,6-diamidino-2-phenylindole; GFP, green fluorescent protein; SC, sperm cell. The nucleotide sequence reported in this paper has been submitted to the GenBank under accession number AB195654. The basic structural unit of chromatin is the nucleosome, about 140 bp of DNA wrapped around a protein octamer containing two copies of each histone H2A, H2B, H3 and H4, designated core histones. In addition, histone H1 proteins are 1 2 Present address: CSIRO Plant Industry, PO Box 350, Glen Osmond, SA 5064, Australia. Corresponding author: E-mail, [email protected]; Fax, +61-3-8344-5051. 797 798 Transcriptional activity of gcH3 in sperm cells Fig. 1 (A) Nucleotide sequence alignment of the proximal promoter region of gcH3 and rat testis-specific histone H1t. Transcriptional regulatory elements of the H1t promoter identified previously are shown above the sequence. (B) Conservation of mammalian testis-specific transcriptional elements, GC box 1 and GC box 2, in plant male gamete-specific gene promoters. (C) Two possible silencer elements conserved in the gcH3 promoter and the putative suppressor-binding domain of the LGC1 promoter. However, no plant male gamete-specific histone promoter has been investigated so far. Our previous study regarding the LGC1 gene promoter is the only report of a flowering plant male gamete-specific gene promoter, and our analysis suggested that germline cell-specific expression is achieved by suppression of the LGC1 gene in sporophytic cells as found in the animal H1t gene (Singh et al. 2003). Here, we report the isolation of the 5′-flanking region of the lily male gametespecific histone gcH3 and its activity in male gametic cells of flowering plants. To compare cis-regulatory elements in the male gametespecific histone gcH3 promoter with the somatic histone H3 promoter, we cloned the 5′-flanking region of the gcH3 gene by TAIL-polymerase chain reaction (PCR) as described (Terauchi and Kahl 2000). The combination of four nested gcH3-specific primers (H3-RV1, CAATATCCTAATAGCATCCTCC; H3RV2, TCAGTTACCTCCTCAAGTGG; H3-RV3, GCAGATGTGTCTTCAAGTCC; and H3-RV4, ACCAGCCCTTGGAATGGCAG) and 10mer arbitrary primers was used to amplify the promoter region of gcH3 from genomic DNA. The PCR products were cloned into pGEM-T Easy vector (Promega) and the DNA sequence was determined. The longest fragment obtained in this experiment was 1.3 kb including 1 kb of 5′flanking region from the initiation codon. This genomic DNA fragment shows 98% identity to gcH3 cDNA and contains an 84 bp intron. Comparing the gcH3 promoter sequence with known ciselements of the histone promoter manually and by a PLACE database search (http://www.dna.affrc.go.jp/PLACE/), we found several motif sequences in the promoter region. There are three domains showing similarity to the NONA motif at –446, –422 and –145 from the putative transcription initiation site. The NONA motif is present in more than half of the plant histone promoters and is considered as a modulator element, by increasing the activity of Oct-containing composite elements dependent on the proliferative state and/or the position of cells in plants (Meshi et al. 2000). The NON motif, a similar modulator element to NONA, and the CAT motif, which is involved in promoter strength in the maize histone H3C4 promoter (Meshi et al. 2000), were also found at –358 and –559, respectively. The OCT motif has been identified as a histone promoter cis-acting element involved in proliferation-coupled and S phase-specific expression. This motif is well conserved in plant histone promoters, and almost all histone gene promoters, >40 genes examined by Meshi et al. (2000), in the database contain at least one OCT motif in their proximal regions. However, there is no significant region similar to the OCT motif in the gcH3 promoter. The OCT motif is necessary for S phase-specific histone gene expression, while cell cycle of lily mature pollen generative cell is arrested at G2/M stage where the gcH3 is expressed; thus the OCT motif may not be necessary for the expression of gcH3 in the generative cell. In rat testis-specific histone H1t, several transcription activator and repressor elements in the proximal region of the H1t promoter have been reported (reviewed by Grimes et al. 2003). Among these regulatory elements, GC box 1 and GC box 2 are present in the lily gcH3 promoter (Fig. 1A). GC box 1 contains a consensus binding site for members of the Sp family of transcription factor and it has been demonstrated that Sp1 and Sp3 are expressed in testis cells and show binding activity to GC box 1 (Wilkerson et al. 2002a, Wilkerson et al. 2002b). Furthermore, overexpression of Sp1 and Sp3 enhances H1t promoter activity in a sequence-specific manner and methylation of GC box 1 inhibits the binding of Sp1 and Sp3, thus GC box 1 is a transcriptional activator for the H1t gene in mammalian testis (Wilkerson et al. 2002a, Wilkerson et al. 2002b). This GC box 1 is not only found in the gcH3 promoter but also in the LGC1 promoter that is also male gamete-specific (Xu et al. 1999b, Singh et al. 2003) and shows almost a perfect match with the consensus sequence (Fig. 1B). GC box 2, which is located just downstream of the TATA box, has been shown to bind a nuclear protein, and fusion of the GC box 2 motif onto the somatic histone H1d promoter resulted in suppression of promoter activity in cultured cells by transient gene expression assay (Clare et al. 1997). In addition, it has been shown that GC box 2-binding proteins are only expressed in somatic cells but not in testis; thus it has been proposed that the silencer element GC box 2 represses the expression of H1t in somatic cells. A similar cytosine-rich sequence is found downstream of a putative TATA box of the gcH3 promoter (Fig. 1B). Although the number of cytosine nucleotides is less than that of GC box 2 in H1t and gcH3, the LGC1 promoter also contains a cytosine-rich sequence just downstream Transcriptional activity of gcH3 in sperm cells of the TATA box. Finding these mammalian type testis-specific histone H1t regulatory elements in male gamete-specific gene promoters suggests that plants and animals may share the mechanism which governs specific gene expression in male germline cells by similar transcriptional regulators. In our previous study, deletion of a 43 bp DNA sequence from the LGC1 promoter led to loss of the generative cell specificity, resulting in activation of this promoter in sporophytic tissues (Singh et al. 2003). This 43 bp putative silencer fragment of this promoter region has been shown to bind a nuclear protein of lily petal, leading us to conclude that the male gamete specificity of the LGC1 gene seems to be regulated by factors that suppress its activation in other plant cells. We compared the putative silencer sequence of the LGC1 promoter with the gcH3 promoter sequence to evaluate whether two different male gamete-specific genes share regulatory sequences. Two regions showed significantly high sequence similarity between the LGC1 and gcH3 promoter (Fig. 1C). These two domains are possible cis-regulatory elements that might be common in male gametic genes and function to suppress gene expression in sporophytic tissues. Together with these results, male gametic genes of flowering plants are likely to be controlled by several transcriptional regulators to maintain the silenced state in sporophytic cells and up-regulation in male gametic cells. To investigate the promoter activity of the gcH3 gene in male gametic cells of lily, we fused 1 kb of the 5′flanking region including the 5′-untranslated region (5′-UTR) with a reporter gene GFP. The promoter of gcH3 was amplified with primers attached by restriction enzyme site (H3 pro 5′-HindIII, TTTGAAGCTTGAGGTGATTTTGTATGAG; H3 pro 3′-BamHI, ACGGGATCCCGGAGCGACGGATTTCTTCTC) and the digested fragment was inserted 5′ upstream of sGFP to generate gcH3–green fluorescent protein (GFP) (Chiu et al. 1996). As in the case of the other generative cell-specific gene LGC1 promoter (Singh et al. 2003), a transient gene expression assay was carried out by microprojectile bombardment. A cauliflower mosaic virus (CaMV) 35S-GFP plasmid (Chiu et al. 1996) was used in a control experiment. Onion epithelium and lily mature pollen grains were placed on top of a nylon membrane on the Murashige and Skoog (MS) medium. DNA-coated gold particles were introduced into plant tissues using a Bio-Rad He-particle gun as described (Singh et al. 2003). After the delivery of DNA, sample tissues were placed under dark conditions at 25°C for 5 h to overnight. Samples were assessed by incident light fluorescent microscopy BX60 (Olympus, NSW, Australia) using a UV filter and blue filter combination. The number of cells in which GFP expression was observed was counted and images were recorded using a DP11digital camera (Olympus, NSW, Australia). GFP expression in onion epithelium carrying 35S–GFP and gcH3–GFP is shown in Fig. 2A and B, respectively. Strong expression of GFP induced by the 35S promoter was observed, whereas a much weaker fluorescent signal was observed in a 799 few gcH3–GFP-transformed cells. The number of cells that showed GFP expression induced by gcH3–GFP was 10-fold less than that by 35S–GFP. Futhermore, our previous data revealed that the endogenous gcH3 gene shows generative cell specific expression with no expression detected in other vegetative tissues (Xu et al. 1999a). Therefore, the expression of GFP induced by the gcH3 promoter in onion epithelium is most likely to be an ectopic expression caused by excess foreign DNA. In mature pollen of lily, significant GFP expression was observed in gcH3–GFP pollen. An intense spot of green fluorescence revealed expression of GFP in generative cells assessed by 4′,6-diamidino-2-phenylindole (DAPI) staining (Fig. 2C–E). Following the germination of lily pollen tube on the medium, pollen tubes were assessed under the fluorescent microscope. Since the gcH3 promoter is expected to be active only in generative cells, successful penetration of gold particles into generative cells would be a very rare event. Indeed, expression of GFP in pollen grains and pollen tubes was rarely seen. Among hundreds of thousands of pollen and pollen tubes, only 65 pollen grains or pollen tubes revealed GFP expression induced by the gcH3 promoter, while none of the pollen and pollen tubes showed GFP expression induced by the 35S–GFP construct, confirming previous findings of very low activity of the 35S promoter in pollen (Twell et al. 1991, Okada and Toriyama 2001). Use of pollen vegetative cell-specific promoters such as LAT52 (Twell et al. 1990) and Bra r 1 (Okada and Toriyama 2001) resulted in a much higher ratio of GFP expressed pollen (T. Okada unpublished data). Together with these results, GFP expression observed in gcH3–GFP pollen is most likely to be the result of gcH3 promoter activity in male gametic cells of pollen. A typical type of green fluorescence in pollen tubes is shown in Fig. 2F. The fluorescent signal was observed throughout the pollen tube cytoplasm with an intense fluorescent region. In a bright field image, two sperm cell (SC)-like membrane-surrounded structures were identified in this pollen tube (Fig. 2G) and the left one showed an intense fluorescent signal, relatively stronger than that in pollen tube cytoplasm, and there was a lack of fluorescence in the right one, resulting in a black region in the pollen tube (Fig. 2F). Furthermore, localization of gold particles was only seen in the left structure (Fig. 2G, arrowhead). A vegetative nucleus-like dispersed structure was found in the bottom left of the pollen tube. Together with these results, the intense fluorescent region is most likely to be one SC showing GFP expression induced by the gcH3 promoter. The fluorescent signal observed in pollen tube cytoplasm might be due to two possibilities; the excessive GFP in SC induced by high copy of gcH3–GFP may have been leaked from the membrane pore created by particle penetration. The second possibility is ectopic expression in pollen vegetative cells induced by high copy of gcH3–GFP. In either case, in our transient gene expression assay, we believed there would be some pollen showing significant GFP expression only in male 800 Transcriptional activity of gcH3 in sperm cells Fig. 2 Transient gene expression assay of gcH3–GFP in onion epidermal cells, lily pollen grains and pollen tubes. Expression of GFP in onion epithelium carrying 35S–GFP (A) and gcH3–GFP (B). (C–E) GFP expression was confined to the generative cell of mature pollen. An intense spot of GFP fluorescence was observed (C), and the incident light microscope image (D) and DAPI staining (E) indicate the localization of the fluorescent spot in the generative cell. (F and G) Intense fluorescence in one SC and its absence in the other SC was observed. GFP was also localized throughout the pollen tube cytoplasm. (H–K) Specific GFP expression was observed only in one SC (H), which had gold particles inside of the nucleus assessed by bright field image (I) and DAPI staining (J). The presence of many gold particles on the surface of the original pollen grains of the pollen tube shown in (H–J) is another piece of evidence for successful transformation (K). (L–Q) Another clear example of specific GFP expression only in one SC. Weak fluorescence was confined only in one SC (top) and absent in the other SC (bottom) as shown in (L) and (M). Magnified images clearly revealed that the GFP is accumulated in the SC nucleus and less in the cytoplasm (N), and gold particles were found only in the SC which showed fluorescence (O) and not in the other SC (P) and vegetative nucleus (Q). Arrowheads indicate the localization of gold particles. VN, vegetative nucleus; GC, generative cell; SC, sperm cell. Bars in (A)–(M) = 50 µm and in (N)–(Q) = 20 µm. Transcriptional activity of gcH3 in sperm cells gametic cells, which is consistent with the result of in situ hybridization (Xu et al. 1999a). Indeed, our careful observation of hundreds of thousands of pollen tubes enabled us to find two pollen tubes that showed GFP expression only in male gametic cells without any GFP expression in pollen tube cytoplasm. Fig. 2H revealed weak GFP expression in one SC (middle) and its absence in the other SC (bottom). SC nuclei were visualized by DAPI staining for this pollen tube after the GFP photograph was taken, because DAPI staining causes the diffusion of the GFP signal. Although the pollen tube has been slightly moved by application of the DAPI solution onto the slide, the pollen tube still stayed at the same location on the slide and two SC nuclei were confirmed in this pollen tube (Fig. 2J). Again, gold particles were found only in SCs in which GFP expression was observed (Fig. 2I). The original pollen grain of this pollen tube shown in Fig. 2H– J was checked and many gold particles were found on the surface of the pollen grain (Fig. 2K), indicating that gold particles were undoubtedly transferred by bombardment, and fortunately two particles could have penetrated into the generative cell of mature pollen. Then these particles were eventually separated into two SCs when the second pollen mitosis occurred in the pollen tube, and two particles were transferred to one SC by chance. Another example is more obvious and shown in Fig. 2L–Q. Two SC-like structures and a vegetative nucleus were clearly identified in the bright field image (Fig. 2M) and only one SC showed GFP expression (Fig. 2L, top). A magnified image enabled us to recognize the SC structure by GFP fluorescence (Fig. 2N). Since GFP tends to be accumulated in the nucleus as observed in onion epidermal cells (Fig. 2A), relatively higher fluorescence was observed in the large central part of SC, and weaker signals in the remaining regions. This observation is applicable to the feature of SC structure, where a relatively large portion of the volume is nucleus and a small portion is cytoplasm. The distribution pattern of GFP was consistent with that observed in onion cells, i.e. intense fluorescence in the nucleus and relatively low fluorescence in the cytoplasm. A vegetative nucleus would not show this clear cell-like structure; normally a stretched structure is observed. Therefore, GFP is expressed only in one SC and also accumulated in its nucleus. Indeed, we found three gold particles in an SC nucleus (Fig. 2O) but not in other SCs (Fig. 2P) and the vegetative nucleus (Fig. 2Q). From these results, we conclude that the gcH3 promoter is active for transcription in male gametic cells in a cell-specific manner. Although it has been reported that the transcript of LGC1 is confirmed in two SCs of lily pollen tube (Xu et al. 1999b) and male gametic histone proteins (gH2A, gH2B and gH3) are localized in two SCs (Ueda et al. 2000), it was unclear whether the SC is active in transcription or transcripts derived from the generative cell are translated in the SC. The fact that GFP expression was observed only in one SC that had gold particles points towards transcriptional and translational activities of SC. 801 We have isolated the promoter region of gcH3, a histone variant specifically expressed in male gametes of L. longiflorum. Comparison of the gcH3 promoter sequence with the lily male gamete-specific gene LGC1 promoter located shared regulatory motifs. Intriguingly GC box 1 and GC box 2 found in mammalian testis-specific histone H1t are also observed in the proximal promoter of gcH3 and LGC1, leading to the suggestion that flowering plants and animals may share a regulatory mechanism for germline cell-specific gene expression. The Sp family transcription factors, Sp1 and Sp3, have been shown to bind to GC box 1 and to up-regulate H1t promoter activity in mammalian germline cells (Wilkerson et al. 2002a, Wilkerson et al. 2002b). A search for transcription factors in Lilium male gametes that interact with GC box 1 and GC box 2 type sequences and comparison of their structure with that of the Sp family of mammalian transcription factors would be the next step towards understanding the mechanism of male gametic cell-specific gene expression. Acknowledgments We gratefully acknowledge financial support provided by the Australian Research Council (ARC) for this project. 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Chem. 277: 43474–43480. (Received December 7, 2004; Accepted February 14, 2005)