cDNA microarray를 이용하여 한우의 근육과 지방조직의 유전자 발현 패턴 분석 및 bovine customer cDNA chip 구성 연구

Construction of Ovine Customer cDNA Chip and Analysis of Gene Expression Patterns in the Muscle and Fat Tissues of Native Korean Cattle

Abstract

소의 질을 평가하기 위해서는 중요한 인자인 근육내 지방(또는 마블링)을 조절하는 분자를 연구해야 한다. cDNA microarray를 사용하여 등지방 조직과 최장근의 유전자발현 차이를 비교하였다. 이 연구를 통해, 우리는 한우의 지방조직에 1211개, 근육조직에서 1346개의 특이 유전자를 확인하였다. bovine chip은 지방조직의 920개 유전자와 근육조직의 760개 유전자로 이루어진 1680개의 특이 유전자로 구성되어있다. 이 실험에서 Microarray 분석은 등지방조직(Cy3)과 최장근(Cy5)의 유전자 발현에 있어서 큰 차이를 보여준다. 차이를 보이는 많은 특이유전자 중에서, 12-리폭시게나아제 유전자와 프로스타글란딘 D 합성효소는 근육내 지방의 축적을 조절하는 중요한 효소이다. 본 연구에서, 일반적으로 발현되지만 한우의 근육과 지방 조직에서 차이를 보이는 많은 유전자를 hybridization 분석을 통해 발견하였다. 선택된 유전자의 발현 수준은 반정량적 RT-PCR을 통해 확인하였고, 그 결과는 cDNA microarray와 유사하였다.

To investigate the molecular events of controlling intramuscular fat (or marbling), which is an important factor in the evaluation of beef quality, we performed cDNA microarray analyses using the longissimus dorsi muscle and back fat tissues. For this study, we constructed normalized cDNA libraries: fat tissues in native Korean cattle (displaying 1,211 specific genes), and muscle tissues in native Korean cattle (displaying 1,346 specific genes). A bovine cDNA chip was constructed with 1,680 specific genes, consisting of 760 genes from muscle tissues and 920 genes from fat tissues. The microarray analysis in this experiment showed a number of differentially expressed genes, which compared the longissimus dorsi muscle (Cy5) with back fat tissue (Cy3). Among many specific differentially expressed genes, 12-lipoxygenase (oxidizing esterified fatty acids) and prostaglandin D synthase (differentiation of fibroblasts to adipocytes) are the key candidate enzymes that should be involved in controlling the accumulation of intramuscular fat. In this study, differentially and commonly expressed genes in the muscle and fat tissues of native Korean cattle were found in large numbers, using the hybridization assay. The expression levels of the selected genes were confirmed by semi-quantitative RT-PCR, and the results were similar to those of the cDNA microarray.

Introduction

Intramuscular fat (or marbling) is an important factor for the evaluation of beef quality, and therefore is often regarded as a direct economic index. Marbling not only assists in preventing moisture loss during cooking, but also stimulates flavor and juiciness during eating. Research studies conducted on consumers’ taste preferences have consistently shown that marbling has a strong influence on the enjoyment of beef through its effects on flavor, juiciness, and tenderness. As such, improving the marbling score of beef is a top priority for the livestock industry and producers who wish to compete with imported beef and other types of meats. One of the few choices for achieving such a goal is doing research on molecular mechanisms and the signaling pathways involved in fat and muscle synthesis. Not only is the molecular mechanism of intramuscular fat tissue not well understood, but the genomes of livestock have not been as well studied as those of humans or mice. Our tissue-specific libraries will facilitate bovine functional genomics and proteomics. Microarray-based studies have uncovered broad patterns of genetic activity, providing new understanding of gene functions; they have sometimes generated unexpected, (but valuable) insights into transcriptional processes and biological mechanisms. Identifying key genes that regulate differential expression in muscle and fat tissues of native Korean cattle can be greatly facilitated with the use of microarray. In particular, an awareness of the dynamics of where, when, and how much a given gene is expressed is often vital to understanding its biological function. For this reason we designed a study that would allow us to see differential gene expression in longissimus dorsi muscle (sirloin, intramuscular fat randomly distributed in muscle) compared to back fat tissue (mostly consisting of fat tissue) using cDNA microarray.

 

Materials and methods

Preparation of samples

Native Korean steers (n=26) were slaughtered at different time points. The steers were slaughtered in accordance with standard Korean industry-practice guidelines for the ethical treatment of animals. The carcasses, with weights ranging from 550 to 600 kg, were dressed in a commercial slaughter-house. Longissimus dorsi muscles and back fat tissues were obtained from the eighth through the thirteenth thoracic rib sections. The samples were quickly frozen in liquid nitrogen (−196℃) soon after being processed.

Total RNA and mRNA isolation

Total RNA isolation was carried out with TRIzolTM reagent (Gibco BRL, USA) according to modified manufacturer’s instruction. mRNA isolation from total RNA was performed by using PolyATtractR mRNA isolation systems (Promega, Madison, WI, USA).

cDNA library construction

cDNA libraries of bovine muscle and fat tissue were constructed using a SuperScript plasmid system for cDNA synthesis and plasmid cloning (Gibco BRL, USA). Each library was synthesized in pSPORT 1 vector using Not I and Sal I adapters. Transformation with ligated cDNA into E. coli Top 10F´ was carried out.

Screening of bovine clones

White colonies on LB / X-Gal (20mg/ml stock; 40 μl/plate) and IPTG (0.5 M stock; 8 μl /plate) plate were transferred onto other LB agar plates using tooth-picks, and incubated overnight at 37℃.

To remove cDNA clones smaller than 300 bp in each library, a PCR master mix for each 20 μl reaction was prepared for direct PCR with the following reagents: 2 μl of 10× PCR reaction buffer, 2 μl of MgCl2 (25 mM), 0.5 μl of dNTP mix (10 mM), 0.5 μl of forward PCR primer (10 μM), 0.5 μl of reverse PCR primer (10 μM), 0.2 μl of Taq polymerase mix (Promega, Madison, WI, USA), and 14.3 μl of sterile H2O. Twenty microliters of the master mixture was aliquoted into each reaction tube. After picking up the white colony, they were streaked on the master plate and dipped in each reaction tube. PCR was immediately incubated at 94℃ for 2 min and subjected to 27 cycles of denaturation at 94℃ for 30 sec, annealing at 60℃ for 30 sec, and extension at 72℃ for 1.5 min (Bio-Rad, Hercules, USA). The PCR products (10 μl) were electrophoresed from each reaction on a 0.8% agarose gel prepared in 1× TAE buffer and stained with 5 μl /ml ethidium bromide (EtBr).

Plasmid preparation was carried out by Wizard plus SV Minipreps DNA Purification System (Promega, Madison, WI, USA).

Sequencing of selected clones

DNA was sequenced by using ABI 377 automatic sequencer (Applied Biosystems, USA) or on multi-capillary electrophoresis using ABI 3700 automatic sequencer (Applied Biosystems, USA). Sequencing results were searched with other sequences on the Genbank by using the Advanced BLAST search program (http://www.ncbi.nlm.nih.gov/BLAST/).

cDNA microarray

PCR amplification

A PCR master mix for each 100 μl reaction was prepared with the following reagents: 10 μl of 10× PCR reaction buffer (Clontech, Mountain View, CA, USA), 8 μl of dNTP mix (2.5 mM), 0.4 μl of M13 forward PCR primer (100 pM), 0.4 μl of M 13 reverse PCR primer (100 pM), 10 μl of MgCl2 (25 mM), 1 μl of Taq polymerase (Clontech, Mountain View, CA, USA), 1 μl of template DNA (0.2 μg/μl), and 69.2 μl of sterile H2O. 100 μl of master mix was aliquoted into each reaction well of 96-well plates. PCR was immediately incubated at 94℃ for 2 min and subjected 27 cycles of denaturation at 94℃ for 30 sec, annealing at 60℃ for 30 sec, and extension at 72℃ for 1.5 min (MWG Biotech, USA). The PCR products (100 μl) were electrophoresed on a 1 % agarose gel prepared in 1× TAE buffer, and the gel was stained with 0.5 mg/ml EtBr. Subsequently, PCR products were purified as follows: transfer PCR reactions to the 96-well U-bottom tissue culture plates; add 1/10 volume of 3M sodium acetate (pH 5.2) and same volumes of isopropanol; then store PCR product at −70℃ for 1 hr; centrifuge at 3,000 rpm for 1 hr; add 100 μl of ice-cold 70% ethanol and centrifuge again for 1 hr; dry the pellets for 10 min at room temperature; resuspend DNA in 10 μl of 3× SSC; transfer 10 μl aliquots to 384-well plates. Microarrays were printed on poly-lysine treated slides (Sigma, USA) using a PixSys 5500 arrayer (Cartesian Technologies, USA). To reduce non-specific binding of strongly negatively charged target on microarray slides, the positively charged amine groups on poly-L-lysine coated slides were passivated by reaction with succinic anhydride.

Direct labeling and hybridization

Sample total RNA was labeled by incorporation of either Cy3-dCTP or Cy5-d CTP during a reverse transcription. We prepared the samples as follows: heat probe at 65℃ for 10 min and cool on ice; add 10 μl of reaction mixture to Cy3 and Cy5 reactions prepared with the following reagents: 13.4 μl of total RNA (40 μg/13.4 μl), 2 μl of Oligo-dT (18 mer) (2 μg/2 μl), 6 μl of 5× first-strand buffer, 3 μl of 0.1M DTT, 0.6 μl of unlabeled dNTPs, 3 μl of Cy3 or Cy5 (1 mM, Amersham), and 2 μl of superscript II (200 U/μl). Incubate at 42℃ for 2 hr; degrade RNA by adding 1 μl of 1.5 M NaOH and 1.2 μl of 25 mM EDTA, and incubate at 65℃ for 10 min. Neutralize by the addition of 1 μl of 1 M HCl, and bring the volume to 500 μl with TE buffer (pH 8.0); spin in Microcon-30 for 8 min at 14,000 rpm. Hybridize the micro-arrays with different total RNA probes (longissimus dorsi muscle: Cy5; back fat tissue: Cy3); mix each sample (Cy3 and Cy5) (12 μl); add 2.5 μl of 20× SSC and 0.6 μl of 10% SDS. Denature the probe by heating for 2 min at 100℃. hybridize on spotted slide (15 μl) and cover with cover slide; hybridize at 62℃ for 8 hr in a slide chamber with humidity maintained by a small reservoir of 3× SSC (spot around 3 μl 3× SSC at each corner of the slide, as far away from the array as possible). Ready the washing solution: 1.5 l volume (2× SSC [wash I] with 0.2% SDS [add this to the wash first]), followed by 1.5 l volume 0.05× SSC (wash II: prepare two of these chambers). Place arrays, singly, in a rack, inside the wash I chamber (maximum four arrays at a time). Agitate for 15 sec; wash arrays by submersion and agitation for 5 min. Wash arrays in wash II chamber for 1 min; spin dry by centrifugation in a slide rack at 500 rpm for 2 min. Scan arrays immediately (Axon Instruments, Foster City, CA, USA).

Microarray scanning & Image analysis and normalization

Microarrays were scanned using a confocal laser scanner GenePix 4000B Array Scanner (Axon Instruments, Foster City, CA, USA) containing a 532 nm (20 mW) laser for Cy3 measurement and 635 nm (15 mW) laser for Cy5 measurement.

The global normalization procedure consisted of two steps. First, a signal intensity threshold was set. Second, we also eliminated spots where the difference between the Cy5/Cy3 ratios of duplicate spots was higher than half their mean value.

Cloning for transcriptional factors of adipogenesis

RT-PCR

After assessing the quality of the RNA template by gel electrophoresis, cDNA synthesis was performed by using MMLV reverse transcriptase (Promega, Madison, WI, USA).

PCR master mix for each 20 μl reaction was prepared as follows; 2 μl 10× PCR buffer (with 15 mM MgCl2), 1 μl forward primer, 1 μl reverse primer, 0.2 μl Ex Taq DNA polymerase (Takara, Japan), ddH2O to 17 μl, and 3 μl of cDNA first strand products. The samples were cycled according to the following profile, which had been optimized for thermal cyclers with heated lids (Bio-Rad, Hercules, CA, USA). PCR was incubated at 94℃ for 2 min and subjected 40 cycles of denaturation at 95℃ for 30 sec, annealing at 48℃ for 30 sec, and extension at 72℃ for 1.5 min (Bio-Rad, Hercules, CA, USA). The PCR products (20 μl) were electrophoresed from each reaction on 1% agarose gel prepared in 1× TAE buffer and stained with 5 μg /ml EtBr.

TA cloning

Each partial length of C/EBP α, C/EBP β, C/EBP δ, PPAR γ1, and SREBP-1C/ADD cDNA was electrophoresed on 1.0% agarose gel. The specific DNA bands were eluted and purified from the gel by using the agarose gel extraction kit (Bio101, Canada). Taq A-tailed eluted cDNA was ligated into a pGEM-T easy vector exhibiting a 3’ T-overhang on each strand (Promega, Madison, WI, USA) that possessed a lacZ gene for blue/clear color selection. The ligation was mediated by T4 DNA ligase (MBI Fermentas, Amherst, NY, USA), and the ligation was continued overnight at 16℃. The ligated product was transformed into E-coli Top10F´ and clones were selected. Each sequence of adipogenic genes were verified by sequencing analysis and confirmed by BLAST search.

 

Results

Total RNA isolation

Total RNA from the Longissimus dorsi muscles and back fat tissues were extracted by TRIzolTM reagent. 5 μg of total RNA per each sample was electrophoresed on 1.2% formaldehyde agarose gel under denaturing condition.

Bovine muscle and fat tissue cDNA library construction

cDNA libraries were constructed in pSPORT 1 vector using synthesized double strand cDNA from longissimus dorsi muscles and back fat. The number of primary cDNA transformants was 4×105 pfu/ml; this indicated that expressed clones were abundant regardless of their identities.

Screening of bovine clones

Recombinant vector was transformed into electro-competent E-coli TOP10F´ cells by electroporator. We performed direct PCR to check the size of the insert from each clone. 10 μl of PCR product was electrophoresed on a 0.8% agarose gel containing 5 μg /ml of EtBr. cDNA clones (which were not available for the cDNA microarray experiment) were removed, and sizes larger than 300 bp were selected for further experimentation.

With the selected clones, we carried out plasmid preparation with 1,680 clones for bovine fat tissue and 1,500 clones for bovine muscle tissue. We performed PCR to confirm the purity of plasmids with randomly selected clones. 10 ng of each selected PCR product was electrophoresed on a 0.8% agarose gel prepared containing 5 μg/ml of EtBr.

Construction of bovine cDNA microarray

1,680 selected clones from bovine fat tissue and 1,500 clones from bovine muscle tissue were partially sequenced with ABI 377 or ABI 3700 automatic sequencers. Through homology searches of sequencing results in the Advanced BLAST search program, we have constructed cDNA library of native Korean cattle containing 1,211 genes from fat tissue and 1,346 genes from muscle tissue. Fig. 1-A shows the composition of cDNA clones from fat tissues. Among the 1,211 cDNA clones, 161 bovine genes (13.3%), 347 human ortholog genes (28.6%), 142 ortholog genes from other species (12.2%), 211 EST (18%) and 40 novel genes (3%) were classified based on BLAST search. It is worth noting that the 40 novel genes were obtained from fat tissues; further investigation is needed to obtain novel genes from muscle tissue. As shown in Fig. 1-B, 1,346 cDNA clones were obtained from bovine muscle tissues. Based on sequencing analysis and BLAST search, 108 bovine genes (14%), 368 human ortholog genes (48%), 103 ortholog genes from other species (14%), 134 EST (18%), and 42 novel genes (6%) were identified. There are 42 novel genes that are waiting to be studied further. Several redundant genes (295/1,211 and 582/1,346) were found in the fat and muscle tissues, respectively.

Fig. 1.Composition of cDNA clones from bovine fat and muscle tissue.

Cloning for transcriptional factors of adipogenesis

Five genes of potential interest on function and differentiation in adipogenesis were identified. Partial cDNAs of C/EBP α, C/EBP β, C/EBP δ, PPAR γ1, and SREBP-1C/ADD were cloned through PCR amplification and TA cloning. Each clone was confirmed using sequencing analysis and BLAST search.

cDNA microarray analysis

Discounting 877 overlapping genes or non-amplified PCR products in libraries, the bovine chip was constructed with 1,680 specific genes from muscle and fat. In these experiments, genes were considered to be differentially expressed only if the change was ＞2.0-fold. Fig. 2 illustrates corresponding portions of arrays, in which longissimus dorsi muscle (labeled Red, Cy5) was compared with back fat tissues (labeled Green, Cy3). In addition, the fluorescence levels of expressed genes were plotted. The expression levels of several genes were altered as a result of these hybridizations. According to hybridization (longissimus dorsi muscle versus back fat tissue), 592 genes were increased (＞2.0-fold) and 310 genes were decreased (＜−2.0- fold). Only 97 genes (0.07%) were similarly expressed (＞0.9-fold, ＜1.1-fold) in both control and test (Table 1).

Fig. 2.Gene expression monitored on a microarray and scatter plot between longissimus dorsi muscle and back fat tissue. The array contains 1,680 specific bovine cDNAs and housekeeping genes (GAPDH and β-actin). Fluorescent scans represented in a pseudocolor scale correspond to expression levels. The pseudocolored image represents portions of a microarray with reference target; longissimus dorsi muscle is in red (Cy5) and back fat tissue is in green (Cy3).

Table 1. A) Up-regulationaThe ratio expression values for the average expression values of each gene between longissimus dorsi Muscle (Cy5) and back fat tissue (Cy3). This list only represents 30 genes out of 592 genes that were up-regulated between Cy5 and Cy3.

Table 1. B) Down-regulationaThe ratio expression values for the average expression values of each gene between longissimus dorsi muscle (Cy5) and back fat tissue (Cy3). This list only representats 30 genes out of 310 genes that were down-regulated between Cy5 and Cy3.

Expression of genes by microarray analysis

The expression levels of selected genes were confirmed by semi-quantitative RT-PCR. The results showed that the expression levels measured by microarray were similar to those measured by quantitative RT-PCR (Fig. 3).

Fig. 3.RT-PCR was used to confirm the differential gene expression of five genes by microarray analysis. Each panel contains a gene name; pictures of the actual dots represent that gene from microarrays and electrophoresis pictures of RT-PCR, and a bar graph represent the intensity values from RT-PCR. Band intensities were measured using multi-analyst software, normalized against corresponding background. L= Longissimus dorsi muscle; R= rump tissue; B= back fat tissue; M= marker. Beta actin used as a control.

 

Discussion

Microarray technology promises not only to simultaneously monitor differential expression of hundreds of genes but also to make possible a whole new experimental approach in molecular biology. There have been no reports on differential gene expression profiles of bovine muscle and fat tissues, however. In this study, a large number of differentially expressed genes and commonly expressed genes from muscle and fat tissues of native Korean cattle were found in hybridization.

Only with hybridization will longissimus dorsi muscle (Cy5) versus back fat tissue (Cy3) possibly not predict main candidate genes to regulate molecular events in muscle and fat tissue. There are 902 differential expression genes between longissimus dorsi muscle tissue (Cy5) and back fat tissue (Cy3). It is difficult to define which genes really function to synthesize muscle or fat. We thus made different designs to hybridize between longissimus dorsi muscle (Cy5) and rump tissue (Cy3). According to this and previous hybridization, 43 genes turned out to be commonly up-regulated (that is, more than two-fold in the ratio of Cy5/Cy3). Seven genes were commonly down-regulated (＜−2-fold, Cy5/Cy3) on each hybridization (data are not shown). It is probable that 50 genes might be specifically expressed as candidate genes to elucidate molecular mechanisms in longissimus dorsi muscle tissue. This result agrees with other studies, which have shown that cysteine and glycine-rich protein 3 is a novel essential regulator of myogenesis and is a promoter of myogenic differentiation [1]. Other studies have shown that myosin light chain-2 plays a role in the regulation of cardiogenic development [4], and tropomyosin 1 (TPM1) acts to stabilize actin microfilaments [10]. Carbonic anhydrase III is highly expressed in muscle and fat tissue, where it constitutes up to 25% of the soluble protein [5]. A number of studies have shown the tissue-specific expression of genes. For instance, alpha-actinin-2-associated LIM protein (ALP) was expressed at a high level only in differentiated skeletal muscle [12]. Nebulin has a function as a giant filamentous protein specific for vertebrate skeletal muscles [6]. Other studies have found genes that are involved in certain functions. Cardiac alpha tropomyosin is a regulatory protein associated with the thin filament in vertebrate-striated muscle [7], and myosin heavy chain dictates contractile velocity and contraction force. It is almost certain that commonly expressed genes within both hybridizations were involved in muscle metabolism, energy metabolism, growth and development in the longissimus dorsi muscle. It is clear that 43 genes from the longissimus dorsi muscle were up-regulated at least two-fold compared to rump tissue or back fat tissue. On the other hand, seven genes were down-regulated in the longissimus dorsi muscle. These genes thus must be involved in signaling pathways as well as functions. Although in our study there were 50 genes for which the molecular mechanism was not well known, these genes could be important candidate genes to regulate the formation of muscle and fat in longissimus dorsi muscle. These genes were differentially expressed, and they might be involved in forming the characteristics of longissimus dorsi muscle tissue.

In this study, 344 genes were specifically expressed in this hybridization. Although the genes originated from back fat tissue, 219 out of the 344 genes were up regulated (＞2-fold, Cy5/Cy3). When genes were derived from the longissimus dorsi muscle, 125 out of 344 genes were down regulated (＜2-fold, Cy5/Cy3) between muscle and fat. The specifically expressed genes that were found in this experiment were also partially studied by other groups. Galactose-binding lectin plays an important role in embryogenesis, oncogenesis, adhesion and proliferation of the cells, mRNA splicing, bacterial colonization, apoptosis, and the modulation of the immune response [11]. Creatine kinase is an essential transcription factors in skeletal myogenesis [9]. In our study, the activities of a number of enzymes, such as the 12-lipoxygenase gene and prostaglandin D synthase, were differentially expressed; this result agrees with other studies. For example, the 12-lipoxygenase gene is capable of directly oxidizing esterified fatty acids in lipoproteins and phospholipids [3]. In this study, the 12-lipoxygenase gene was expressed 16 times higher in the longissimus dorsi muscle than in back fat tissue. Also, prostaglandin D synthase is responsible not only for the differentiation of fibroblasts to adipocytes but also for the regulation of activated macrophages [8]. In our study, it is interesting to note that prostaglandin D synthase had five times higher expression in longissimus dorsi muscle. This result suggests that prostaglanding D synthase is capable of trans-differentiating muscle tissue into intramuscular fat. Based on these observations with supporting results from other studies, it is probable that differentially expressed 344 genes might be involved in muscle, lipid, or energy metabolism, signal transduction, antioxidant defencse, proliferation, differentiation, and transcription initiation.

Stearoyl-CoA desaturase (SCD), a rate-limiting enzyme in the biosynthesis of unsaturated fatty acids, catalyzes the desaturation of stearic acid and palmitic acid into oleic acid and palmitoleic acid, respectively [2]. In addition, it plays an important role in the regulation of fat cell metabolism. Fig. 3 shows the expression level of SCD by microarray and RT-PCR. Although rump tissue mostly consists of muscle tissue, the expression level of SCD was higher in the rump tissue than in the longissimus dorsi muscle. The SCD gene thus could be used as a model to study mechanisms of cellular differentiation and the pattern of tissue-specific gene expression

In the present study, the results of cDNA microarray, which scanned thousands of genes simultaneously, revealed a complex genotype between muscle and fat tissues of native Korean cattle. Profiles of differentially expressed genes were listed based on the results of each hybridizations. Even though some genes had already been found and their functions studied, the overall molecular mechanism of longissimus dorsi muscle has not yet been exposed. To elucidate the basic mechanisms of intramuscular fat and intercellular communication, many candidate genes were found in the current study using microarray analysis. It is clear that further experiments are needed to explain the relationship among differentially expressed genes from the longissimus dorsi muscle of native Korean cattle with known genes, ESTs, and novel genes.

In conclusion, the comparison of differential gene expression in the fat and muscle tissues from native Korean cattle showed that a substantial number of genes were displayed. Certain genes were expressed to a high level in the designated tissue, as was expected. For instance, myosin light chain-2, nebulin, and creatine kinase were shown to be highly specific to longissimus dorsi muscle. We also observed, however, that a few genes, such as prostaglandin D synthase and 12-lipoxygenase gene, expressed in both tissues unexpectedly; this type of gene could be a good candidate gene to study the mechanisms and signaling pathways for the synthesis of intramuscular fat.