Full-Length Sequence of Mouse Acupuncture-Induced 1-L (<i>Aig1l</i>) Gene Including Its Transcriptional Start Site

Ohta, Mika; Sugano, Aki; Goto, Shuji; Yusoff, Surini; Hirota, Yushi; Funakoshi, Kotaro; Miura, Kenji; Maeda, Eiichi; Takaoka, Nobuo; Sato, Nobuko; Ishizuka, Hiroshi; Arizono, Naoki; Nishio, Hisahide; Takaoka, Yutaka

doi:https://doi.org/10.1093/ecam/nep121

Evidence-Based Complementary and Alternative Medicine

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Abstract Introduction Methods Results Discussion Acknowledgments References Copyright Related Articles

Original Article | Open Access

Volume 2011 | Article ID 249280 | https://doi.org/10.1093/ecam/nep121

Full-Length Sequence of Mouse Acupuncture-Induced 1-L (Aig1l) Gene Including Its Transcriptional Start Site

Mika Ohta,^1,2Aki Sugano,¹Shuji Goto,³Surini Yusoff,⁴Yushi Hirota,⁵Kotaro Funakoshi,¹Kenji Miura,¹Eiichi Maeda,¹Nobuo Takaoka,⁶Nobuko Sato,²Hiroshi Ishizuka,⁷and Naoki Arizono⁸ et al.

Received21 Nov 2008

Accepted21 Jul 2009

Published17 Feb 2011

Abstract

We have been investigating the molecular efficacy of electroacupuncture (EA), which is one type of acupuncture therapy. In our previous molecular biological study of acupuncture, we found an EA-induced gene, named acupuncture-induced 1-L (Aig1l), in mouse skeletal muscle. The aims of this study consisted of identification of the full-length cDNA sequence of Aig1l including the transcriptional start site, determination of the tissue distribution of Aig1l and analysis of the effect of EA on Aig1l gene expression. We determined the complete cDNA sequence including the transcriptional start site via cDNA cloning with the cap site hunting method. We then analyzed the tissue distribution of Aig1l by means of northern blot analysis and real-time quantitative polymerase chain reaction. We used the semiquantitative reverse transcriptase-polymerase chain reaction to examine the effect of EA on Aig1l gene expression. Our results showed that the complete cDNA sequence of Aig1l was 6073 bp long, and the putative protein consisted of 962 amino acids. All seven tissues that we analyzed expressed the Aig1l gene. In skeletal muscle, EA induced expression of the Aig1l gene, with high expression observed after 3 hours of EA. Our findings thus suggest that the Aig1l gene may play a key role in the molecular mechanisms of EA efficacy.

1. Introduction

Traditional Eastern medicine, such as acupuncture, moxibustion and Chinese herbal medicine, originated in ancient China and has developed unique forms in East Asian countries (mainly Japan, China and Korea). These practices are called traditional Japanese medicine (Kampo), Chinese medicine and traditional Korean medicine [1]. Electroacupuncture (EA) is a well-known acupuncture technique used in East Asia. EA utilizes stimulation of acupuncture needles with a low-frequency microcurrent [2].

Comprehensive analysis of changes in gene expression is called transcriptome analysis, which has provided a number of findings to medical science. cDNA microarray and GeneChip array methods allow such comprehensive gene expression analysis [3, 4]. Certain research groups have reported investigations of gene expression in EA-treated animals in which they used cDNA microarrays. Kim et al. [5] reported that 30 minutes of EA applied every 16 hours for 2 days induced a change in expression of genes related to natural killer cell activity in the spleen. Ko et al. [6] showed that gene expression of mitogen-activated protein kinase II (MAPK II), Fas-AP and LIM increased in spinal cord after 3 weeks of daily application of EA for 30 minutes. Chae et al. [7] reported research on acupuncture-treated humans that they analyzed by using a cDNA microarray; after correlating gene expression with responses to acupuncture stimulation, they found individual differences in acupuncture analgesia.

We have also analyzed the effect of EA at the gene transcriptional level [2]. In that study, we found that EA stimulation caused myostatin gene suppression leading to satellite cell proliferation in skeletal muscle. During that study, we discovered a previously unknown gene that was induced by EA in mouse skeletal muscle and named it Aig1l. We found high expression of this gene after EA stimulation in mouse skeletal muscle. This finding agrees with clinical observations that the effect of acupuncture appears some time after stimulation, and it led us to further analysis of this gene.

In the study described here, we used cDNA cloning with the cap site hunting method [8] to determine the full-length cDNA sequence of Aig1l, the full-length sequence consisting of the transcriptional start site to the poly(A) tail. Complete full-length cDNA sequencing is important for functional analysis of the gene; knowing the transcriptional start site makes it possible to evaluate the transcriptional regulatory domain by bioinformatics analyses. Indeed, we used bioinformatics to analyze the transcriptional regulatory domain of Aig1l. We also analyzed the full-length cDNA sequence by bioinformatics analysis and detected functional domains of Aig1l. Finally, we examined Aig1l expression in each tissue by using northern blot analysis and real-time quantitative polymerase chain reaction (real-time PCR). For the relation between the Aig1l gene and EA, we investigated Aig1l expression via semiquantitative reverse transcriptase polymerase chain reaction (RT-PCR) at different times after EA stimulation of muscle.

2. Methods

2.1. Animals and EA Conditions

Inbred C57BL/6 male mice, 8 weeks old, were purchased from Charles River Laboratories (Yokohama, Japan). For EA stimulation, we used stainless-steel acupuncture needles (40 mm long and 0.16 mm in diameter; Seirin, Shizuoka, Japan). We inserted the needles into five anesthetized mice to a depth of 5–7 mm and then stimulated the needles with an electrical stimulator (Kyushu Ryoudoraku, Fukuoka, Japan). Hindleg muscles of mice received EA stimulation at points corresponding to the acupoints BL36 and BL59 (for details, see our web site: http://bionano.med.kobe-u.ac.jp/adss/) for 15 minutes with 1.2 Hz repetitions, according to our previous study [2]. We similarly anesthetized a control group of five mice but did not treat them with EA.

This research was performed according to the Standards Relating to the Care and Management, and so forth. of Experimental Animals (Ministry of the Environment, Tokyo, Japan) [9]. This study was approved by the Committee for Safe Handling of Living Modified Organisms of Kobe University (Permission number 17–21) and was carried out according to the guidelines of the Committee.

2.2. RNA Extraction and cDNA Synthesis

We extracted total RNA from various tissues (brain, skeletal muscle, heart, lung, spleen, liver and kidney) obtained from non-EA-treated mice by using the TRIzol reagent (Invitrogen, Carlsbad, CA, USA) method.

To extract total RNA, we prepared skeletal muscles (gastrocnemius, soleus, biceps femoris and gluteus) from EA-treated mice at the time points of immediately after EA (0 hours) and then 1, 3 and 24 hours after EA (n = 5 for each time point). We chose these time points on the basis of our clinical experience and observations during acupuncture treatment, which we classified into two groups: “rapid effect" for immediately (0 hours) and 1 and 3 hours after EA, and “late effect" for 24 hours after EA. We similarly extracted total RNA from skeletal muscles from the control group. For each PCR analysis, we reverse transcribed total RNA (5 μg) into cDNA by using the SuperScript First-Strand Synthesis System for RT-PCR (Invitrogen), according to the manufacturer's instructions.

2.3. Northern Blot Analysis

We subjected the denaturated total RNA (1 μg) to electrophoresis on 1.2% agarose/2% formaldehyde gel and then transferred the samples to a positively charged nylon membrane. To generate anti-sense RNA probes, we cloned a 509 bp of Aig1l cDNA fragment (nucleotide positions 3720–4228) derived from the PCR amplification by using the TOPO TA cloning kit (Invitrogen). We prepared digoxigenin-labeled RNA probes with DIG RNA Labeling Mix (Roche Diagnostics GmbH, Mannheim, Germany). The membrane was hybridized with DIG-labeled RNA probes just described in DIG Easy Hyb (Roche Diagnostics) at 68^∘C overnight. Then, excess probe was washed away: 2× SSC/0.1% SDS was used twice at RT, and then 0.1× SSC/0.1% SDS was used twice at 68^∘C. Hybridized DIG-labeled RNA was detected by means of alkaline phosphatase-conjugated anti-DIG antibody (Roche Diagnostics), after which CSPD Substrate was added and the membrane was exposed to X-ray films to obtain signals. The membrane was rehybridized with the DIG-labeled mouse glyceraldehyde-3-phosphate dehydrogenase (G3PDH) RNA probe (Genostaff, Tokyo, Japan) as an internal control.

2.4. Real-Time Quantitative PCR and Semiquantitative RT-PCR

Real-time quantitative PCR was performed by using SYBR Green I and a LightCycler (Roche Diagnostics), according to the manufacturer's instructions. The reaction mixture consisted of 2 μl of FastStart DNA Master SYBR Green I (Roche Diagnostics), 2 mM MgCl₂, 2 μl of cDNA and each primer at 10 pmol, plus water to a final volume of 20 μl. The PCR conditions were 95^∘C for 10 minutes followed by 40 cycles in three steps: 95^∘C for 15 s, 58^∘C for 10 s and 72^∘C for 25 s and then 60^∘C for 10 s. The primers used for real-time PCR were as follows: for Aig1l, sense: 5′-TTGAAGCCAGCTCTTTGGAG-3′ and antisense: 5′-TTTGCCTACGGTTCCTGAAG-3′; for G3PDH, which served as an internal control [10], sense: 5′-GGAAAGCTGTGGCGTGATG-3′ and antisense: 5′-CTGTTGCTGTAGCCGTATTC-3′.

For semiquantitative RT-PCR, for which we used a thermal cycler (GeneAmp PCR System 9700; Applied Biosystems, Foster City, CA, USA), the reaction mixture (20 μl) contained 5 pmol primers, 0.4 unit AmpliTaq Gold DNA polymerase (Perkin-Elmer/Cetus, Tokyo, Japan), 1× PCR buffer and 200 μl/l dNTPs. We analyzed the Aig1l gene expression pattern after the EA stimuli by means of RT-PCR with primers as follows: sense: 5′-ACTGGGATACACTCGTGAGC-3′; antisense: 5′-GACACAGGAAGGTCACCACCA-3′. Primers of G3PDH for RT-PCR were the same as the ones used for real-time PCR. We then performed 28 cycles of amplification (one cycle: denaturation at 94°C for 60 s, annealing at 55^∘C for 60 s and extension at 72^∘C for 60 s), and we analyzed 449 bp PCR products from Aig1l by using 1.5% agarose gel electrophoresis. After electrophoresis, we determined the densitometric values of these PCR bands by the same procedure that we reported in our previous study [2], using the ImageJ program (Wayne Rasband, National Institutes of Health, Bethesda, MD, USA).

2.5. Full-Length cDNA Sequencing and Bioinformatics Analysis

We amplified a partial sequence of Aig1l by use of two primers—forward, 5′-ACTGGGATACACTCGTGAGC-3′, and reverse, 5′-GACACAGGAAGGTCACCACCA-3′—as probes. The Aig1l probe served to screen the mouse brain cDNA library (Stratagene, La Jolla, CA, USA). We screened with the labeled probe by means of the AlkPhos Direct system (Amersham Biosciences Corp., Piscataway, NJ, USA), according to the manufacturer's protocol. We isolated and purified positive clones. We then performed automated DNA sequencing analysis by using the ABI Prism 377 with the BigDye Terminator Cycle Sequencing Reaction Kit (Applied Biosystems). We confirmed sequencing results with both strands.

We determined the transcriptional start site of the Aig1l gene by using the cap site hunting method with mouse skeletal muscle and brain cap site cDNA (Nippon Gene, Toyama, Japan), according to the manufacturer's instructions. The procedure for synthesis of cap site cDNA was reported previously [8] as follows: we removed the cap structure of mRNA with tobacco acid pyrophosphatase. We then ligated a synthetic oligoribonucleotide to the decapped mRNAs with T4 RNA ligase. We converted the ligated mRNA to cDNA by using reverse transcriptase, with oligo(dT) as a primer. In this study, we first performed PCR with the cap site cDNA and then performed nested PCR. Figure 1 shows the primer sets for those PCRs. We amplified samples of the first PCR for 35 cycles under the following conditions: denaturation for 20 s at 95^∘C, annealing for 20 s at 60^∘C and extension for 90 s at 72^∘C. We used aliquots of the first PCR reaction as the template in the nested PCR reaction, performed under the same conditions. We then excised PCR products from the low-melting-temperature 1.5% agarose gel, inserted them into the TA vector, and sequenced them. After we sequenced the full-length cDNA, we performed bioinformatics analysis of Aig1l by using the Pfam database (http://pfam.sanger.ac.uk/). Then, to analyze the transcriptional control regions of Aig1l genes (upstream from the ascertained transcriptional starting point), we used SHAFT (https://suzume.med.kobe-u.ac.jp/SHAFT/), an automated application of the search and choice analyses for transcription factors that we previously developed [2].

Figure 1

PCR primer sets for the cap site hunting method analysis of the Aig1l gene. The cap site hunting method allowed detection of the transcriptional start site of the gene. Horizontal arrows indicate positions of the primer pairs. In the first PCR, we prepared primer sets for the brain (RDT1 and R4) and skeletal muscle (RDT1 and R3). In the nested PCR, we prepared primer sets for the brain (RDT2 and R2) and skeletal muscle (RDT2 and R1). The vertical arrow points to the transcriptional start site. Underlining shows the start codon atg. Italic letters designate the synthetic rOligo sequence ligated to the mRNA.

3. Results

3.1. Cloning of the Full-Length cDNA Sequence of Aig1l and Bioinformatics Analysis of the Gene

We determined the full-length cDNA sequence of the Aig1l gene via cDNA cloning and use of the mouse brain cDNA library, because the brain showed high expression of the gene. We ascertained the transcriptional starting point of the gene by means of the cap site hunting method with cap site cDNAs from mouse brain and from mouse skeletal muscle, because the transcriptional start site is not included in the usual cDNA libraries. We obtained the same transcriptional start site from cap site cDNA of both mouse brain and muscle. After we determined the complete cDNA sequence of Aig1l, we registered it with the GenBank genome database (GenBank accession no. DQ167195). The full-length cDNA sequence was 6073 bp long, and the putative protein consisted of 962 amino acids (Figure 2). Bioinformatics analysis performed via the Pfam database indicated that Aig1l includes CUB and Sushi domains. The transcriptional control region, near the transcriptional start site, of the Aig1l gene has Sp1, CP2 and MZF1 binding motifs that we detected by using the SHAFT program.

Figure 2

Nucleotide and deduced amino acid sequences of the Aig1l gene. The lowercase upper letters correspond to the nucleotide sequence. The capital letters refer to the deduced amino acid sequence. The numbers at the ends of the lines indicate nucleotide positions. Underlining shows the initiation codon atg. The closed boxes with white letters designate the CUB domain; the open boxes with black letters indicate the Sushi domain. An asterisk indicates the stop codon (taa). A double underline identifies the poly(A) signal sequence.

3.2. Tissue Distribution of the Aig1l Gene and Characteristics of Gene Expression Induced by EA

All tissues, brain, skeletal muscle, spleen, heart, lung, kidney and liver, expressed the Aig1l gene as determined by semiquantitative RT-PCR: the highest expression was found in the brain (data not shown). Northern blot analysis performed in the normal sensitivity mode showed high Aig1l gene expression in the brain (Figure 3(a)); the northern blot analysis performed in the high sensitivity mode revealed very weak gene expression in the heart, lung and spleen (data not shown). In addition, real-time quantitative PCR analysis also indicated that the brain had the highest Aig1l gene expression and all other tissues had very weak gene expression (Figure 3(b)).

(a)

(b)

(c)

Figure 3

Tissue distribution and effect of EA on Aig1l gene expression. (a) Tissue distribution of Aig1l as detected by northern blot analysis in the normal sensitivity mode. (b) Tissue distribution of Aig1l as detected by real-time quantitative PCR analysis (n = 5). (c) Semiquantitative RT-PCR analysis of Aig1l gene expression in skeletal muscle after EA. Lanes are as follows: C: no EA stimulation (control); 0: EA-treated sample just after stimulation; 1, 3 and 24: EA-treated samples at 1, 3 and 24 hours after stimulation, respectively; NC: negative PCR control containing no cDNA template in the PCR mixture; G3PDH served as a loading control. The following tissues expressed the Aig1l gene in (a) and (b): brain, B; muscle, M; heart, H; lung, Lu; spleen, S; liver, L and kidney, K. NC indicates negative control.

We then analyzed the effect of EA on Aig1l expression in skeletal muscle by using semiquantitative RT-PCR. EA induced expression of Aig1l at each time point. We found the highest expression after 3 hours of EA (Figure 3(c)).

4. Discussion

In this research, we determined the full-length cDNA sequence of the mouse Aig1l gene, which EA stimulation induced in mouse skeletal muscle, and analyzed its expression. Because skeletal muscle expressed the Aig1l gene after EA stimulation, this gene may be involved in the molecular mechanism of the effectiveness of EA therapy.

We performed full-length cDNA cloning of the Aig1l gene, including the transcriptional start site. We determined this site via the cap site hunting method (Figure 1). The complete cDNA sequence was 6073 bp long and mapped to chromosome 5 in the mouse genome database. The mouse Aig1l gene is a homologue of the human SEZ6L gene [11]. The coding sequences of these genes showed 79% homology. The human SEZ6L gene is a homologue of the mouse Sez6 gene, which research on seizures has detected [12, 13]. The coding sequences for Aig1l and the mouse Sez6 showed 54.8% homology. This finding may reflect the effect of EA stimulation on the brain and nervous system in view of the relation among the gene Aig1l and the seizure-related genes Sez6 and SEZ6L.

Our investigation of the tissue distribution of Aig1l gene expression revealed the greatest expression in the brain, as evidenced by semiquantitative RT-PCR (data not shown), northern blot analysis (Figure 3(a)) and real-time quantitative PCR analysis (Figure 3(b)). All other tissues evaluated—skeletal muscle, heart, lung, spleen, liver and kidney—had much weaker Aig1l expression than the brain (Figures 3(a) and 3(b)). The human SEZ6L gene was also reportedly detected in various tissues [11].

Bioinformatics analysis of Aig1l near the transcriptional control region showed Sp1, CP2 and MZF1 binding motifs. Sp1 and CP2 are ubiquitously expressed transcription factors. Sp1 functions in development and differentiation [14, 15], and CP2 operates in regulation of erythroid genes [16, 17]. MZF1 is involved in proliferation and differentiation [18]. These bioinformatics results agree with findings on the tissue distribution of Aig1l gene expression.

Our analysis with the Pfam database showed that Aig1l has CUB and Sushi domains (Figure 2). CUB domains occur almost exclusively in extracellular and plasma membrane-associated proteins, and in proteases [19–21]. Those proteins reportedly participate in a wide range of biological functions: developmental processes [22–25], neurotransmission [26], cell signaling [27], hemostasis [20], tumor suppression [28], inflammation [29] and complement activation [21]. Sushi domains are known as complement control protein modules, or short consensus repeats, found in complement and adhesion proteins [30]. Sushi domain-containing proteins operate in regulation of the complement system and in blood clotting. Involvement of these proteins in cell adhesion [30], embryogenesis [31] and blood coagulation [32] has also been reported. In addition, the human SEZ6L and mouse Sez6 genes, the homologous genes of Aig1l, have both CUB and Sushi domains [11–13]. The Sez6 gene is reportedly important for neuronal information transfer, which Gunnersen et al. [33] determined on the basis of analysis using Sez6 knockout mice. Their report showed that Sez6 proteins are important for normal dendritic arborization of cortical neurons and for development of appropriate excitatory synaptic connectivity. All these reports suggest that Aig1l may be associated with neurotransmission and protein-protein interaction. In view of the relation between those domains of Aig1l and the effect of EA, further analysis of Aig1l focused on neurotransmission and protein-protein interaction may reveal the functional importance of this gene.

In addition, we examined chronological changes in Aig1l gene expression to verify the effect of EA stimulation of skeletal muscle on gene expression. We found that EA did induce Aig1l gene expression, with the highest expression measured after 3 hours of EA (Figure 3(c)). This result suggests that the Aig1l gene is related to the rapid effect of EA stimulation.

During the process of Aig1l gene detection, we utilized transcriptome and histochemical analyses and discovered that EA induced a satellite cell-related proliferative reaction in skeletal muscle [2]. Certain other research groups have also reported transcriptome analysis of EA, which revealed the efficacy of EA stimulation: Kim et al. [5] showed that EA increased natural killer cell activity with high efficacy, and Ko et al. [6], by using cDNA microarray analysis, reported that the opioid receptor was involved in analgesic processes of EA. Thus, transcriptome analysis may be one of the most effective approaches for research in complementary and alternative medicine.

In conclusion, we determined the full-length cDNA sequence of the Aig1l gene and its expression in various tissues (mainly brain). We showed chronological changes in gene expression, with the greatest expression induced after 3 hours of EA. However, the biochemical function of the Aig1l gene is not as yet fully explained. Additional investigations of the Aig1l gene, including the relation between this gene and EA, are warranted.

Funding

20th Grant-in-aid of the Nakatomi Foundation in the fiscal year 2007.

Acknowledgments

The authors thank Mr Hitoshi Nagano, LAc, Msc (Koujin Acupuncture Clinic, Kobe 657-0028, Japan), Mr Tomoyuki Ishido, LAc (Sho-undo Acupuncture Clinic, Soja, Okayama 719-1154, Japan) and Dr Kunihiko Takamatsu (Kobe Tokiwa College), for their helpful comments.

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Copyright © 2011 Mika Ohta et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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