PASS 2008 8.0.10 serial key or number

Induction of RNAi:

To induce RNAi targeting of the aadA mRNA, we transformed 19-P[1030] cells, which stably express the aadA mRNA and form colonies on TAP agar plates containing 800 μg/ml spectinomycin (spc800/TAP plate) (data not shown), with a linearized silencer/pSP124S plasmid carrying an inverted repeat of aadA, as well as the ble gene as a marker for cotransformation (Figure 1A). Potential cotransformants were selected on medium with zeocin. Transformants in which the aadA mRNA was reduced by the silencer construct were identified by slow growth on spc800/TAP plates.

The growth rate of 59 randomly chosen zeocin-resistant transformants was assayed on various spectinomycin concentrations. When tested on spc250/TAP plates, 40 of 59 transformants showed slower growth than the parental 19-P[1030] strain. All of these 40 transformants survived on spc100/TAP plates on which wild-type cells cannot grow. We selected four transformants that showed slow growth on spectinomycin plates. These strains could not be distinguished from the parent strain under nonselective conditions that included TAP or TAP without acetate (TMM, Tris-minimal-medium) plates. These four strains could not survive on spc400/TAP plates on which parental strain 19-P[1030] grows as well as on TAP plates (Figure 1B). These four transformants were promising candidates for RNAi-induced transformants and we named them RNAi-13, -17, -18, and -37, respectively. Southern hybridization to analyze the copy number of the integrated silencer plasmid and PCR analyses confirmed that the entire silencer construct was integrated in the genome. RNAi-17 and -18 carried three and four copies of the plasmid, respectively. In contrast, RNAi-37 carried a single intact silencer construct and also the ble marker gene (data not shown). Therefore, RNAi-37 was used for further experiments to confirm the existence of siRNA, silencer transcript, and aadA hairpin RNA.

Using a sense aadA RNA probe, we detected a double band (most probably due to incomplete denaturation of the hairpin RNA) from total RNA of RNAi-37. The lower major band was ∼1.6 kb in length (Figure 1C), which is consistent with the expected intact transcript of the silencer construct. We also detected siRNA from the small-sized RNA fraction by the sense-aadA RNA probe (Figure 1D). Therefore, we concluded that reduction of spectinomycin resistance observed for RNAi-37 was due to induction of RNAi that successfully targeted the aadA mRNA.

To determine the genomic locus of the integrated plasmid, we amplified the flanking genomic region of the plasmid by the restriction enzyme site-directed amplification–PCR method (Gonzalez-Ballesteret al. 2005). BLAST searches using the sequence obtained from the RESDA–PCR products showed that the plasmid inserted in the proximity of several genes between nucleotide positions 1,422,072 and 1,422,078 of Scaffold_3 (JGI website: http://genome.jgi-psf.org/Chlre3/Chlre3.home.html; Merchantet al. 2007). Therefore, the silencer DNA construct most likely integrated into a euchromatic region of the genome.

Fluctuation of spectinomycin resistance during successive mitotic cell divisions:

We noted that colonies arising from liquid cultures of RNAi-37 and their subclones spread on spc100/TAP plates varied in size (Figure 2A). This observation was remarkably different from that of the parental strain 19-P[1030], which formed colonies of fairly uniform size on similar plates (Figure 2A).

Spotting test procedures for fluctuating spectinomycin resistance of subclones originated from a single RNAi-37 colony. (A) Growth of 19-P[1030] and RNAi-37 cells on spectinomycin-containing agar plates. Cells were spread on 100 μg/ml spectinomycin-containing agar plates and incubated for 10 days. (B) Flow chart of clonal analysis. After >100 mitotic cell divisions, RNAi-37 was spread on a TAP plate, and then six colonies were isolated and their spectinomycin resistance was analyzed using plates containing various concentrations of spectinomycin (phase-I spotting). Each RNAi-37 clone was subjected to additional cell divisions (>20 times) and then spread on TAP plates. Ten randomly chosen subclones for each of the 6 RNAi-37 clones (total of 60 subclones) were spotted on various spectinomycin plates (phase II spotting). Tenfold dilution of the cell culture was used for spotting. (C) Results of phase-I and -II spotting tests for RNAi-37 subclones. Tenfold dilution of the cell culture was used for spotting. (D) Results of phase-II spotting test for 19-P[1030]. Ten randomly chosen subclones were used.

To examine whether various levels of growth appear specifically on spectinomycin-containing plates and the observed growth rate is genetically stable, we randomly picked six RNAi-37 single colonies grown on nonselective TAP-plates. Phase I of the spotting test was carried out as follows (Figure 2B): each of the six clones was grown to stationary phase in nonselective liquid TAP-medium independently, and then a 10-fold dilution (5 μl) of each culture was spotted on spc50/TAP, spc100/TAP, spc200/TAP, spc300/TAP, TAP plates, and TMM plates and incubated for 10 days. Various greenish colors were observed for the spots on spc50/TAP, spc100/TAP, and spc200/TAP-plates, while their growth showed no prominent difference on the TAP and TMM plates (Figure 2C). They were arranged by their sensitivity to spectinomycin, as clones 1–6, from the highest to the lowest on the phase-I spotting plate. Then, each remaining sample for the phase-I spotting test was subjected to an approximate total of 20 mitotic cell divisions in liquid TAP medium by successive transfers at midlogarithmic growth phase (Figure 2B). Afterward, a second round of colony isolation was carried out by spreading a small portion of the culture on TAP plates. After 10 days, 10 colonies for each clone were randomly picked and cultured in 2 ml of TAP medium until reaching stationary phase. Then, a total of 60 subclones (10 subclones from each of the six types of RNAi-37 clones) were subjected to the spotting test, using plates containing various concentrations of spectinomycin (spc50/TAP, spc100/TAP, spc200/TAP, and spc300/TAP).

As expected, none of the 60 subclones showed substantial growth difference on TAP, zeo50/TAP, zeo200/TAP, and TMM plates (data not shown). Growth differences among the 10 subclones were observed in the presence of spectinomycin from each starting colony. Some of the subclones (clone 2) showed variation on lower concentrations (spc100/TAP) while others showed variation among the clones on higher concentrations (spc200/TAP for clone 5) (phase-II spotting test, Figure 2C). Subclones could become more resistant or more sensitive than the starting parental clone. Subclones of the parental strain, 19-P[1030], which were subjected to treatments similar to those for RNAi-37, showed no detectable difference among growth rates tested on any concentration of spectinomycin (e.g., Figure 2D).

The analysis shows that spectinomycin resistance of the subclones fluctuated multiple times throughout mitotic cell divisions. Southern hybridization analysis was carried out, and we confirmed, for all of the 60 subclones, that no extensive rearrangements occurred inside or in regions bordering the aadA gene or the silencer construct (supplemental Figure 1). This suggested that the fluctuating spectinomycin resistance was due to epigenetic effects.

In addition to the epigenetic change in spectinomycin sensitivity, genetic changes leading to recovery of spectinomycin resistance were also detected, albeit rarely. Cells bearing such changes were easily distinguishable from those exhibiting epigenetic effects, because these genetic revertants showed the spectinomycin resistance to the level of the parental cell 19-P[1030], i.e., 800 μg/ml spectinomycin resistance. Four clones grew on spc800/TAP plates, following successive liquid cultures in TAP medium. Southern hybridization analysis following digestion with EcoT14I showed that one of these clones had acquired new EcoT14I restriction sites and consequently additional DNA fragments originating from the silencer construct while the others had completely lost the silencer region (supplemental Figure 1).

To correlate various growth rates of RNAi-37 subclones with the amount of remaining aadA mRNA, we carried out quantitative analyses of aadA mRNA levels by real-time RT–PCR using aadA-specific primers, one of which specifically hybridizes to the boundary region between the RbcS2 promoter and the aadA ORF coded in the P-679 plasmid (Ceruttiet al. 1997a). This experiment showed that the relative level of aadA mRNA decreased to ∼38% of 19-P[1030] for a strong spectinomycin-resistant RNAi-37 subclone, while it decreased to as low as ∼9% of 19-P[1030] for a weak spectinomycin-resistant RNAi-37 subclone and it was ∼25% for an intermediate-resistance subclone (supplemental Figure 2). This supports our idea that the RNAi efficiency is reflected by the growth rates of the transformants on spc/TAP plates.

Inverse correlation between the level of spectinomycin resistance and the amount of accumulated hairpin RNA and siRNA:

We performed Northern blot analyses to compare the relative amounts of hairpin RNA and siRNA for three newly reisolated RNAi-37 subclones of low spectinomycin resistance (nos. 1–3 in Figure 3A) and three of high spectinomycin resistance (nos. 4–6 in Figure 3A), all of which are different from clones shown in Figure 2. Using the DIG-labeled sense aadA RNA as a probe, we detected the expected IR transcript from all of the subclones at the position corresponding to ∼1.6 kb as a double band, presumably due to incomplete denaturation of the hairpin structure. It was noteworthy that the 1.6-kb signal detected from the highly resistant subclones (nos. 4–6) was consistently weaker than that from the less resistant ones (nos. 1–3) (Figure 3B). By treating the samples with RNase A/T1 mixture to digest single-stranded RNA molecules or single-stranded regions in the dsRNA, the 1.6-kb band shifted to the position corresponding to half of the original molecular weight (data not shown). This demonstrated that the 1.6-kb RNA in the cytosol indeed had formed a hairpin structure with a short loop in the middle. The small-sized RNA fraction was separated on a 15% polyacrylamide gel and a sense-aadA RNA probe was used to detect the presence of the siRNA. A much stronger signal for the siRNA was detected from the weaker resistant subclones (nos. 1–3) than from the stronger resistant subclones (nos. 4–6) (Figure 3B).

Northern blot analyses to compare the relative amount of aadA hairpin RNA and siRNA for RNAi-37 subclones with various levels of spectinomycin resistance. (A) Evaluation of spectinomycin resistance for six RNAi-37 clones. Three strongly silenced subclones (nos. 1–3) and weakly silenced subclones (nos. 4–6) were spotted on various kinds of plates after serial dilutions of 10⁻¹, 10⁻², and 10⁻³. (B) Northern blot analyses to detect aadA hairpin RNA and siRNA. A sense-aadA RNA probe was used to detect the hairpin RNA and siRNA. Total RNA was loaded on a 1% agarose/formaldehyde gel and a small-sized RNA fraction was resolved on a 15% polyacrylamide gel containing 8 m urea. Ethidium bromide staining and detection of the RbcS2 mRNA were performed to confirm that the amount of RNA loaded was almost equal. Hybridization using the RbcS2 RNA probe was carried out last, since complete stripping of the probe was difficult.

On the basis of the fact that the amount of siRNA and the amount of the hairpin RNA are positively correlated, it suggests that the primary limiting factor for RNAi efficiency is the amount of silencer hairpin RNA in the cytoplasm.

Analysis of 5-methylcytosine in the inverted repeat DNA region:

Our observation suggests that the fluctuating RNAi effect among subclones is primarily due to the varied amounts of the silencer hairpin RNA, which most likely depends on the transcriptional frequency of the IR construct in the cytoplasm. Since it is known that DNA methylation affects the transcriptional efficiency (Rountree and Selker 1997; Lorinczet al. 2004), we performed Southern blot analyses and genomic bisulfite sequencing (Liuet al. 2004) to analyze the frequency of 5-methylcytosine (*C) in the strongly silenced and weakly silenced subclones, therefore to determine the correlation between the frequency of *C and the amount of the IR transcript.

To assess the *C frequency in the CCGG sequences located in the silencer DNA construct, we prepared total DNA from two strongly silenced and two weakly silenced subclones, which were newly isolated from the RNAi-37 strain. First, we completely cleaved the genomic DNA with EcoT14I to generate DNA fragments of appropriate sizes. Complete digestion of the genomic DNA by this enzyme was confirmed by Southern hybridization, using a full-length aadA probe (supplemental Figure 1). Subsequently, the DNA sample was divided into two equal volumes. One sample was further digested with HpaII and the other with MspI. Both enzymes recognize CCGG, with HpaII inhibited by methylation of either cytosine (C*CG and *CCGG) and MspI inhibited by methylation only of the outer cytosine (*CCGG). The existence of *CpG in CCGG sites of the RbcS2 promoter regions, which were located upstream of the ble and also the aadA genes, was assayed by the P probe (Figure 4A). Alternatively, the C probe was utilized to detect *CpG in the CCGG sites located within the aadA gene and the aadA IR region (Figure 4A).

Analysis of methylated CpG frequency by Southern hybridization with methylation-sensitive restriction enzymes. (A) Schematic restriction maps for the ble marker gene and the inverted repeat silencer construct. The aadA gene is represented by shaded boxes and the ble gene is represented by solid boxes. The first intron of RbcS2 inserted into the ble gene is indicated by dotted lines. Open boxes indicate the RbcS2 promoter and the RbcS2 terminator. The positions where P and C probes hybridize are shown by horizontal bars. Horizontal lines correspond to the detected signals in B and C. ×5 demonstrates five closely located restriction sites for HpaII/MspI at the arrowhead position. The asterisk shows the position of the GGCCGG sequence. (B) Result of hybridization by the P probe. Weak, the weakly silenced RNAi-37 clones; strong, the strongly silenced clones. Gathered fragments, unresolved small DNA fragments; *, unknown band. M, MspI; H, HpaII. (C) Result of hybridization by the C probe. Labels are the same as in B.

According to the DNA sequence, seven DNA fragments, with lengths of 482, 116, 84, 82, 74, 73, and 62 bp, respectively, should be detected by the P probe, when all CCGG sites in the RbcS2 promoters and the aadA IR are completely digested. If *CCGG or C*CGG sites were accumulated abundantly in the RbcS2 promoter region, HpaII digestion should result in larger fragments with combined lengths of the neighboring fragments. However, we could not detect these bands by the P probe. Only the 482-bp fragment, which corresponds to the completely digested RbcS2 promoter in the aadA IR construct, was observed irrespective of the strength of RNAi (Figure 4B). This indicated that existence of *CCGG and C*CGG sites, if present, was undetectable in the RbcS2 promoter region in the IR construct by our method. On the other hand, irrespective of the RNAi efficiency, the 482-bp signal detected in MspI-digested samples was consistently stronger than that in HpaII-digested samples. This indicated C*CGG accumulated slightly in the promoter region, but the frequency of this modification appeared to occur similarly in clones irrespective of the silencing strength.

We carried out analysis of *C accumulation at the restriction sites in the aadA gene, using the C probe (Figure 4A). According to the DNA sequence, a 520-bp fragment should be detectable when the aadA gene is digested completely by HpaII or MspI. In all of the samples, the fact that the only fragment detected was 520 bp in length demonstrated that very few, if any, C*CGG or *CCGG sites were present in the gene. In addition, the strength of the signal had no detectable difference regardless of the restriction enzymes used or the origin of the genomic DNA, i.e., DNA prepared from the strongly silenced clones or the weakly silenced ones (Figure 4C). Taken together, these data proved there was no detectable accumulation of *C in the CCGG sites of the targeted aadA gene.

According to the DNA sequence, a 372-bp fragment should be detected by the C probe when the aadA IR DNA is completely digested by HpaII or MspI. For two strongly silenced clones, the density of the signal corresponding to the 372-bp fragment was the same irrespective of the restriction enzymes used. However, for two weakly silenced clones, the signal was notably stronger in MspI-digested samples than in HpaII-digested ones (Figure 4C). This suggested significant and specific accumulation of C*CGG in the weakly silenced clones. Moreover, the significant accumulation of C*CGG in the aadA IR region of the weakly silenced subclones resulted in a signal that corresponds to two unresolved 553- and 605-bp bands that were specifically detected in HpaII-digested samples (Figure 4C).

A 424-bp band was also detected specifically in the weakly silenced clones. Given the DNA sequence of the aadA IR region and the result of the bisulfite genomic sequencing (see below), the 424-bp band was likely caused by slow digestion by MspI caused by the GGC*CGG sequence, but not by the existence of *CCGG. Altogether, Southern blot analyses showed very slight accumulation of C*CGG in the RbcS2 promoter region and significant accumulation of C*CGG in the aadA IR silencer region.

Detection of methylated cytosine by the bisulfite genomic sequencing method:

We analyzed the frequency and location of the *C in the upper strand of the first half of the aadA IR region by the bisulfite genomic sequencing method (Figure 5A). Methylated cytosines were detected within the context of CpG sequences. Of the 59 analyzed CpG sites in the first half of the aadA IR region, the *CpG frequency was 15.3% for the strongly silenced clones but 53.4% for weakly silenced clones on average (Figure 5, B and C). Clear inverse correlation was detected between the *CpG frequency in the aadA IR region and the amount of accumulated hairpin RNA; however, it is not clear whether *CpG accumulation is the cause or the effect of repressive transcription of the IR region. Further investigation is essential to address this issue.

Analyses of methylated cytosine in the inverted repeat region of the silencer. (A) A schematic map of the silencer DNA construct. Annealing sites for the degenerate primers are indicated by arrows. (B and C) The CpG methylation patterns of a strongly silenced subclone and a weakly silenced subclone, respectively. Methylated cytosines were detected by the bisulfite sequencing method. Promoter region, −23 to −1; 5′-truncated aadA ORF region, +1 to +786; loop constructing intron, +787 to +800. Annealing sites for nested primers (see supplemental Table 5) are underlined. CpG dinucleotide positions are marked by stacked circles on the sequence. Each horizontal set of circles represents the methylation pattern of a cloned PCR product. Ten PCR clones obtained from a strongly silenced RNAi-37 subclone and 8 PCR clones obtained from a weakly silenced RNAi-37 subclone were sequenced. Solid circles indicate methylated cytosines and open circles indicate unmethylated cytosines. Each horizontal set of circles represents the methylation patterns of a single cloned PCR product.

We applied the same method to the equivalent region of the aadA gene that encodes the target mRNA. The genomic DNA from six weakly silenced RNAi-37 clones and four strongly silenced RNAi-37 clones was analyzed. The original sequence of the PCR amplicon contained 96 non-CpG sites and 35 CpG sites. In total, we detected 1308 C to T converted sites and two nonconverted C sites. Moreover, these two nonconverted C sites were located in non-CpG sequence. However, we cannot exclude the possibility that these nonconverted C sites are due to incomplete chemical reactions in the bisulfite method. Therefore, the aadA gene may contain *C in the non-CpG sequence with extremely low frequency (<0.2%) or it may not contain any *C in the non-CpG sequence at all. No or very rare *C in the target aadA gene implies that C. reinhardtii probably does not have a siRNA-mediated trans-acting cytosine methylation pathway that targets the complementary DNA region. It is notable that distribution of *CpG was strongly enriched in the region close to the RbcS2 promoter and had the tendency to decrease gradually in the direction of its transcription (Figure 5, B and C).

Relationship between the accumulation of *CpG and aadA IR transcription:

To determine whether accumulation of *CpG in the aadA IR region depends on transcription, we made an aadA IR DNA construct bearing no promoter and no terminator, while retaining the other regions as they were in the original silencer plasmid. This construct was introduced into 19-P[1030]. We selected two transformants, both carrying a single intact promoterless aadA IR construct. Northern hybridization analysis showed that transcription of the promoterless aadA IR was below detection level, which suggests that the construct was not driven by neighboring endogenous promoters at the insertion sites in these transformants (data not shown). The level of aadA mRNA in these transformants was not significantly different from that of the recipient strain 19-P[1030], as determined by the real-time RT–PCR analyses (data not shown). In addition, these two transformants showed no significant growth difference on spc400/TAP plates as compared to that of the recipient strain 19-P[1030]. These observations reinforce the idea that the aadA IR construct is not transcribed at significant levels from a neighboring endogenous promoter.

In these transformants, the frequencies of *C in the CpG sites of the promoterless aadA IR were 20.1 and 18.7%, respectively. These frequencies were comparable to the average frequency of *CpG in the strongly silenced RNAi-37 clones (15.3%). This indicated that a negligible amount of the IR transcript is enough to cause *CpG accumulation or the IR transcript is not necessary at all. Instead, the intrinsic IR structure may be the primary determinant of the CpG methylation in the aadA IR region.

In the C. reinhardtii genome, there are many endogenous microRNA coding genes that bear long perfect inverted repeat sequences (Molnáret al. 2007). To determine whether cytosines within the sequences were methylated, we analyzed regions of six microRNA coding genes, which are coded in the clusters numbered cr.01795, cr.01848, cr.02116, cr.02386, cr.02466, and cr.02798 (Molnáret al. 2007), by the bisulfite method. In spite of the fact that each of these genes has a >150-bp-long perfect inverted repeat, no methylated cytosine was detected in the analyzed regions (data not shown). Moreover, HpaII/MspI analysis showed the 5S rRNA gene cluster of C. reinhardtii has no prominent *CpG (data not shown). Therefore, it is possible that, due to unknown mechanisms, endogenous IR structures can escape DNA methylation in C. reinhardtii. Further investigation is essential to uncover the conditions required for induction of DNA methylation in the IR, e.g., minimum length of the IR and specific location of the IR within the genome.

Analyses of histone H3 N-terminal modifications:

Considering the recent reports that nucleosomes unfold completely in a transcriptionally active promoter in Saccharomyces cerevisiae (Boegeret al. 2003; Reinke and Horz 2003), we first investigated the nucleosome occupancy at several regions to assess the H3 modification levels of interest in C. reinhardtii. These regions include the long terminal repeat (LTR) of TOC1 retrotransposon, the promoter region of active endogenous gene ribosomal protein S3 (RPS3), the IR promoter, and the aadA IR. Relative nucleosome occupancy at a specific region was estimated through analyses of the histone H3 levels using a modification-insensitive anti-H3 antibody (Figure 6A).

ChIP assays using antibodies against histone H3, monomethylated H3K4, monomethylated H3K9, and acetylated H3K9/14. Solid bars and Shaded bars indicate relative amounts of the PCR fragments amplified from immunoprecipitated chromatins of strongly silenced RNAi-37 subclones and weakly silenced subclones, respectively. (A) The PCR-amplified regions of the inverted repeat silencer are indicated as horizontal bars under the illustration. Specific primers are listed in supplemental Table 6. (B) H3 occupancy levels normalized with respect to the input DNA level in the TOC1 LTR, the RPS3 promoter, the IR promoter, and the aadA IR regions were determined by immunoprecipitation with a modification-insensitive anti-histone H3 antibody. (C) H3K9me1 levels normalized with respect to histone H3 levels in the same regions were determined by immunoprecipitation with an anti-H3K9me1 antibody. (D) H3K4me1 levels normalized with respect to histone H3 levels in the same regions were determined by immunoprecipitation with an anti-H3K4me1 antibody. (E) Acetyl histone H3 levels normalized with respect to histone H3 levels in the same regions were determined by immunoprecipitation with an anti-acetyl histone H3 antibody.

The histone H3 occupancy rate is most likely to reflect the transcription frequency. Compared to the transcriptionally inactive TOC1 LTR, the RPS3 promoter had about only half of the histone H3 occupancy, irrespective of the difference in aadA silencing efficiency (Figure 6B). On the other hand, a prominent occupancy difference was observed between the strongly and weakly silenced clones at the IR promoter and the aadA IR regions. In a weakly silenced clone, H3 occupancy rate at the IR promoter was almost the same as that at the inactive TOC1 LTR; while in a strongly silenced clone, the rate at the same region was almost equal to that at the active RPS3 promoter. In a weakly silenced clone, H3 occupancy rate at the aadA IR was about twice of that at the TOC1 LTR; while in a strongly silenced clone, the rate was only slightly higher than that at the TOC1 LTR (Figure 6B). Therefore, to estimate the H3 modification frequency in these regions, normalization with histone H3 levels was carried out.

Differences in the H3 modification pattern were most prominent at the IR promoter between the strongly and weakly silenced RNAi-37 subclones. In a weakly silenced subclone, H3K9me1 was extremely (Figure 6C) enriched and H3K4me1 was moderately (Figure 6D) increased in this region. In contrast, the acetylation level of H3 was extremely high in a strongly silenced subclone in the same region (Figure 6E). Furthermore, in the aadA IR region, a similar tendency was observed with moderate bias between the two types of RNAi-37 subclones. Altogether, modifications of H3 suggested that aadA IR in a weakly silenced subclone is less actively transcribed than in a strongly silenced one.

Effect of TSA treatment on the accumulation of hairpin RNA and siRNA:

It has been reported that *CpG induces heterochromatin formation and deacetylated histones in various kinds of eukaryotes (for a review, see Klose and Bird 2006). Since there is a clear inverse correlation between the frequency of *CpG and the amount of accumulated hairpin RNA, we explored the relationship between the transcriptional activity for the aadA IR construct and histone modification using TSA, a histone deacetylase inhibitor. One strongly silenced and one weakly silenced RNAi-37 subclone were treated with TSA (50 ng/ml) during the logarithmic growth phase in liquid culture. Equal amounts of liquid culture were withdrawn periodically during the treatment, and the changing quantities of hairpin RNA and siRNA in the samples were monitored by Northern blot analysis.

After 20–40 min of TSA treatment, a distinct increase in the amount of hairpin RNA was observed in both subclones (Figure 7A). Upregulation of the hairpin RNA reached the maximum after incubating with TSA for 40 min in the strongly silenced subclone. However, in the weakly silenced subclone, the increase of the hairpin RNA was very slow and it reached the maximum after 120–180 min incubation (data not shown).

Effects of TSA treatment on the accumulation of hairpin RNA and siRNA. (A) Time course of hairpin RNA accumulation after TSA treatment. Samples were isolated at various time points after TSA inoculation and Northern blot analyses were carried out using a DIG-labeled sense-aadA RNA probe. Detection of the RbcS2 mRNA was also carried out to confirm equal loading of RNA. (B) Time course of siRNA accumulation after TSA treatment. A DIG-labeled sense-aadA RNA probe was used to detect the siRNA from small-sized RNA fractions isolated at different time points after TSA treatment. Ethidium bromide staining of RNA was used to confirm equal loading. +180: cells were first inoculated in TSA–TAP medium for 180 min, followed by a recovery period of 180 min in fresh TAP medium.

Contrasting with the prominent effect on the increased aadA IR transcript, no obvious effect of TSA was detected for the transcript of the endogenous RbcS2 gene (Figure 7A). Therefore, the increased aadA IR transcript was most likely the result of specifically enhanced transcriptional activity that had been repressed by histone deacetylation-related mechanisms.

We also examined the effect of TSA on the production of siRNA. Total RNA was prepared from the cells cultured in the TSA-containing TAP medium after a treatment period of 1.5 hr (1.5 hr TSA) and 3 hr (3 hr TSA) and also from the cells that were cultured for 3 hr in the TSA-containing TAP medium and subsequently washed and recultured for an additional 3 hr in TAP medium without TSA (3 hr TSA/3 hr TAP). A continuous increase of siRNA was observed for both types of subclones; however, it was much greater for strongly silenced cells (Figure 7B). The amount of siRNA detected from 3 hr TSA/3 hr TAP-treated cells greatly exceeded that detected from 1.5 hr TSA and 3 hr TSA-treated ones for both types of subclones (Figure 7B). Furthermore, the increase of siRNA had an ∼1-hr delay compared to that of the hairpin RNA.

Effect of TSA treatment on the accumulation of *CpG in the silencer construct:

We examined the *CpG frequency change for a strongly silenced RNAi-37 subclone and a weakly silenced one by the TSA treatment: both types of subclones were cultured for 2 hr in the TSA-containing TAP medium and subsequently washed and recultured for an additional 14 hr in TAP medium (i.e., enough time to experience a mitotic cell division) without TSA (2 hr TSA/14 hr TAP cell). Then *CpG frequency was estimated by the HpaII/MspI-Southern hybridization method described above, using the C probe and the P probe. No significant *CpG frequency changes were detected in the promoter and the IR region of the silencer construct for both types of subclones (data not shown). This suggests that the increased IR transcript by TSA treatment is not due to the change of *CpG frequency in the IR region but rather to conformational change of the aadA IR-containing chromatin region, which is likely induced by the generation of hyperacetylated nucleosomes.

We also treated RNAi-37 subclones with a DNA methylation inhibitor 5-aza-deoxycytidine to ask whether *CpG contributes to repression of IR transcription in C. reinhardtii. 19-P[1030] cells and RNAi-37 subclones were treated with a DNA methylation inhibitor 5-aza-deoxycytidine (5adc). Previous experiments suggest that 50 μm 5adc is fully effective for blocking DNA methylation in the C. reinhardtii chloroplast (Umen and Goodenough 2001). Cells were grown on TAP agar plates containing 200 μm of 5adc for 5 days. Subsequently, we transferred cells to TAP liquid medium containing a 200-μm concentration of 5adc and cultured them for 10 days. During the period of liquid cultivation, TAP medium containing 5adc was renewed every 48 hr. As a control, the same process was carried out using TAP medium not containing 5adc. No prominent change in the *CpG pattern or the genetic composition of the aadA IR region was observed for the 5adc-treated subclones (data not shown). As expected, there was no significant difference in spectinomycin resistance or the amount of the hairpin RNA between the 5adc-treated cells and untreated cells (data not shown).

Effect of TSA on the elongation step of IR transcription:

Two nonmutually exclusive mechanisms are plausible for the aadA IR repression: (i) initiation of transcription is repressed or (ii) the elongation step of transcription is repressed. To assess the extent of the latter effect, we carried out Northern hybridization using sense and antisense aadA RNA probes to detect complete transcripts and prematurely terminated transcripts. Northern hybridization analyses were carried out for five newly isolated RNAi-37 subclones of which RNAi efficiencies were widely diverse (Figure 8A).

Analyses of complete and incomplete silencer transcripts. (A) Five RNAi-37 clones (nos. 1–5), which show distinctive silencing efficiencies, were chosen. A spotting test was carried out using plates containing various concentrations of spectinomycin. (B) Detection of the silencer transcripts. In Northern blot analyses, a membrane was first hybridized with the 5′-terminal sense-aadA RNA probe, which recognized the almost completely transcribed products (top). The probe was stripped and a second hybridization with the 3′-terminal antisense-aadA RNA probe, which hybridized with complete and incomplete transcripts of the silencer DNA, was carried out (middle). Finally, the same membrane was hybridized with a ble probe to ensure equal loading of total RNA (bottom).

When hybridization was carried out using a sense-aadA RNA probe (750 bases long), which hybridizes to most of the second half of the hairpin transcript, a weak smeared signal corresponding to 1.0- to 1.5-kb-long incomplete transcripts was detected in addition to the 1.6-kb-long complete hairpin RNA (Figure 8B). Using the same membrane, another hybridization was carried out with an antisense-aadA RNA probe (620 bases long), which hybridizes to most of the first half of the hairpin transcript and 3′ region of the target aadA