Journal List > J Vet Sci > v.18(S1) > 1041575

Sun, Chun, Kim, Ahn, Kim, Hwang, Kwon, Hwang, and Lee: Molecular cloning and characterization of porcine ribosomal protein L21

Abstract

Ribosomal protein L21 (RPL21) is a structural component of the 60S subunit of the eukaryotic ribosome. This protein has an important role in protein synthesis and the occurrence of hereditary diseases. Pig is a common laboratory model, however, to the best of our knowledge, its RPL21 gene has not been cloned to date. In this study, we cloned and identified the full-length sequence of the pig RPL21 gene for the first time. In addition, we examined its expression pattern and function by using overexpression or knockdown approaches. As a result, we obtained a 604 bp segment that contains a 483 bp open reading frame encoding 160 amino acids. The pig RPL21 gene is located in the “+” strand of chromosome 11, which spans 2167 bp from 4199792 to 4201958. Pig RPL21 protein has nine strands and two helices in its secondary structure. Pig RPL21 is predominantly expressed in ovary and lung, at lower levels in kidney, small intestine, and skin, and at the lowest levels in heart and liver. Furthermore, RPL21 expression is closely connected with cell proliferation and cell cycle arrest. The results are intended to provide useful information for the further study of pig RPL21.

Introduction

Ribosomes are important organelles involved in protein synthesis. Eukaryotic ribosomes are composed of a small subunit (40S) and a large subunit (60S) that together form an 80S ribosome [43]. Both of these subunits include complexes of different types of rRNAs and ribosomal proteins (RP). There are now at least 80 RPs reported in mammals [2241] and 53 in Escherichia coli [40] that have been identified as part of a large ribosomal subunit. Additionally, these RPs are not only involved in regulating DNA transcription, DNA replication, DNA repair, and RNA splicing and modification [11], but they also have extraribosomal roles in regulating cell growth and metabolism [213839].
Ribosomal protein L21 (RPL21) is an RP with a homologous counterpart in archaea (RPL21e) and with a functional analog in bacteria (RPL27). Archaeal RPL21e is bound in a similar ribosomal location as that of bacterial RPL27 [1016]. The human RPL21 gene maps to chromosome 13q12.2 [46] and encodes a 160 amino acid protein. It is reported that RPL21 is involved in embryogenesis [2337], odontogenesis [42], and age-related cataracts in human [344]. More importantly, the RPL21 gene is considered to be the main cause of hypotrichosis simplex, a type of sustained hair loss occurring from early childhood to adulthood [46]. Therefore, more research into this gene is needed, but not only in humans. Pig, Sus scrofa, is a common laboratory model, however, to the best of our knowledge, its RPL21 gene has not been characterized in research published to date. In this study, we cloned and identified the full-length sequence of the pig RPL21 gene for the first time. We have also predicted its corresponding amino acid sequence and spatial structure. In addition, we analyzed the mRNA expression and molecular functions of RPL21. These results should provide a basis for further studies of the pig RPL21 gene and hypotrichosis simplex.

Materials and Methods

Total RNA extraction and 5′/3′ rapid amplification of cDNA ends (RACE) polymerase chain reaction (PCR)

Pig tissues were collected from a 3-month-old female Korean native pig. The animal procedures were approved by the Institutional Animal Care and Use Committee of the National Institute of Animal Science, Rural Development Administration (RDA) (approval No. NIAS2015-671). Total RNA was isolated from the different samples by using Trizol reagent (Invitrogen, USA) according to the manufacturer's protocol. The 5′ RACE was performed by using a 5′/3′ RACE kit (Roche Applied Science, Switzerland) and a variety of primers (Table 1). Briefly, first-strand cDNA was synthesized from total RNA extracted from the lung using primer 1. The first PCR was performed by using primers 2 and 3, with the A-tailed first-strand cDNA as a template. The nested PCR was performed by using primers 4 and 5 with the first PCR product diluted 1/20 as a template. The fragment obtained from 5′ RACE was subsequently cloned and sequenced. Similarly, 3′ RACE was performed by using the SMARTer RACE cDNA Amplification kit (Clontech, Japan). Primer 6 was used for synthesizing the first-strand cDNA, and a mix of primers 7 and 8 was used for the PCR reaction.

Characterization and annotation of the porcine RPL21 gene

The open reading frames (ORFs) from the cloned mRNAs were predicted by using the translate tool in ExPaSy [2]. Multiple sequence alignment was performed by using Clustal X 1.83 [5]. An evolutionary tree was constructed by using MEGA5.1 [33] with the neighbor-joining method and 1,000 bootstrap runs. InterProScan software ver. 5 [13] was used to analyze the secondary structure, protein domain motifs, and for recognition of families of RPL21. N-glycosylation sites were predicted by using NetNGlyc 1.0 (Center for Biological Sequence Analysis, Denmark). Protein structure modeling was conducted by using SWISS-MODEL workspace with modeler 1vx4.1.T [14] as a template. The amino acid sequences of the RPL21 protein from 13 other species that were used in constructing phylogenetic trees were obtained from the National Center for Biotechnology Information (USA). In addition to our real-time PCR data for pig, we also used data from a public gene expression database in BioGPS. The raw data for human RPL21 expression was extracted from probe sets 20012 at in the GeneAtlas U133A datasets [32]. The annotation information and experimental method for the human samples have been previously reported [32]. The relative expression level of RPL21 in each human tissue was normalized by that in kidney.

Subcloning of porcine RPL21 coding DNA sequence

The coding DNA sequence (CDS) region of RPL21 was amplified from the cloned vector mentioned above. We used primers 9 and 10 for the first PCR and the reaction was performed as follows: 94℃ initial denaturation for 3 min, 35 cycles of 94℃ for 30 sec, 65℃ for 30 sec, and 72℃ for 1 min, followed by a final extension at 72℃ for 5 min. The second PCR amplification was performed using the following schedule: 94℃ for 3 min, followed by 35 cycles of 30 sec at 94℃, 60℃ for 30 sec, and 72℃ for 1 min, followed by a final extension for 5 min at 72℃ with primers 11 and 12. The amplified RPL21 CDS with an XbaI site and a Kozak sequence at the 5′ end and a BsrGI site and a FLAG tag at the 3′ end was cloned into a TA vector. After sequencing, the newly cloned RPL21 CDS region was digested with XbaI and BsrGI from the cloned TA vector and inserted into the corresponding site in the pCAGGS-EGFP-puro vector (Addgene, USA) to construct the pCX-RPL21 vector.

Real-time PCR

The real-time PCR primers for the RPL21 gene (primers 15 and 16; Table 1) were designed according to the mRNA sequences cloned in this study. The cDNAs were synthesized from total RNA that was extracted from 7 different tissues (kidney, heart, liver, lung, ovary, intestine, and skin) and 3 types of cell lines (wild-type fibroblast, transient RPL21-overexpressed fibroblast, and RPL21-knockdown fibroblast) by using the TOPscript Reverse Transcriptase kit (Enzynomics, Korea). The RPL21 expression levels of the different pig tissues were compared by using a standard curve method as previously described [19]. Briefly, a standard curve was constructed with serial ten-fold dilutions of the pCX-RPL21 plasmid DNA by performing real-time PCR. Then the cycle threshold (Ct) value that was obtained from each sample was transformed into a copy number according to the standard curve. The PCR was performed with primers 15 and 16 by using the TOPreal One-step RT qPCR Kit (Enzynomics) with the following conditions: 40 cycles of 10 sec denaturation at 95℃, 15 sec annealing at 64℃ with a 0.1℃ decrease in each cycle for 30 cycles, and a 20 sec extension at 72℃. When comparing the RPL21 expression levels in the same tissue or cell line, we normalized the expression level against a housekeeping gene, GAPDH (primers 13 and 14).

Cell culture and transient transfection

A porcine ear skin fibroblast (PEF) cell line was isolated from a 10-day-old Messachusetts General Hospital pig [18] and maintained in Dulbecco's Modified Eagle's Medium (Welgene, Korea) supplemented with 20% fetal bovine serum (Gibco, USA), 100 units/mL of penicillin and 100 µg/mL of streptomycin (Gibco), 1× non-essential amino acids (Gibco), 55 µM β-mercaptoethanol (Gibco), and 1 mM sodium pyruvate (Gibco) at 37℃ in humidified air containing 5% CO2. The cells were fed every two days and transiently transfected with the constructed plasmid DNA by using Lipofectamine LTX (Invitrogen) according to the manufacturer's protocol. The cells were incubated for an additional 48 h after transfection and then harvested for downstream experiments.

Lentiviral vector construction and infection

A lentiviral vector for targeting exon 4 of pig RPL21 was constructed according to the Addgene plasmid 10878 protocol. Briefly, we synthesized a sense oligo (shRNA-F) with an AgeI site and an antisense oligo (shRNA-R) with an EcoRI site for targeting the pig RPL21 gene (NeoProbe, Korea). After annealing, the hairpin oligo was cloned into an AgeI/EcoRI double digested lentiviral vector (pLKO.1 TRC). The plasmids carrying the correct insert were screened out and sequenced. Lentiviral particles were produced by packaging the constructed shRNA vector with the psPAX2 and pMD2.G vectors in LentiX-293T cells. PEF cells were then infected with lentiviral particles for 24 h in the presence of 8 µg/mL Polybrene (Sigma-Aldrich, USA). Three days later, cells were harvested for quantitative PCR, western blotting, cell viability assays, and cell cycle assays. The empty pLKO.1 TRC vector containing a fragment of scrambled sequences was used as a negative control.

Immunofluorescent cytochemical (ICC) staining

ICC staining was performed to determine whether the tagged-RPL21 protein was functionally expressed in PEF cells. Briefly, 48 h after transfection, cells were fixed with 4% paraformaldehyde (Sigma-Aldrich) for 15 min at room temperature and permeabilized with 0.25% Triton X-100 (Promega, USA) in Dulbecco's Phosphate-Buffered Saline (DPBS; Welgene) for 15 min. Subsequently, cells were blocked with 1× blocking solution for 1 h at room temperature and incubated with a monoclonal anti-FLAG M2 primary antibody (Sigma-Aldrich) at 4℃ in 1× blocking solution overnight. After washing three times with DPBS containing 0.1% (v/v) Tween 20 (PBST; LPS Solution, Korea), the cells were incubated with Alexa Fluor 488 goat anti-mouse IgG (Invitrogen) secondary antibody for 2 h at room temperature followed by incubation for 5 min in 5 µg/mL Hoechst 33342 solution (Sigma-Aldrich). Cell images were captured by using an Axiovert 200M system (Carl Zeiss Light Microscopy, Germany).

Western blot

Transfected PEF cells were harvested by using a cell scraper after washing two times with DPBS. Harvested cells were lysed by sonication in RIPA lysis buffer (Biosesang, Korea) supplemented with protease inhibitor (Roche Applied Science) and centrifuged at 16,000 × g for 5 min at 4℃ to remove cell debris. Protein concentration was determined by using a BCA Protein Assay Kit (Bio-Rad Laboratories, USA). Equal amounts (80 µg) of protein were separated by using a 12% SDS-PAGE gel and then transferred to a polyvinylidene difluoride membrane (No. GF10600023; Millipore, Germany). Subsequently, the membranes were incubated separately with mouse anti-FLAG M2 primary antibody, rabbit anti-β-actin (13E5) monoclonal antibody (Cell Signaling Technology, USA), and rabbit anti-p53 polyclonal antibody or rabbit anti-p21 (Abcam, UK) polyclonal antibody (Abcam) overnight at 4℃. After washing three times with 1× Tris-buffered saline with Tween 20 (LPS Solution), the membranes were incubated with horseradish peroxidase-labeled secondary antibody (Santa Cruz Biotechnology, USA). Chemiluminescent detection was performed by using the ECL reagent (GE Healthcare Life Sciences, USA) and a luminescent image analyzer system (LAS-3000; Fujifilm, Japan).

Cell viability assay and cell cycle analysis

PEF cells that were infected with shRNA vectors for 3 days were used for cell viability and cell cycle assays. Viability assays were performed by using the EZ-CYTOX Cell Viability Assay Kit (DaeilLab Service, Korea) according to the manufacturer's protocol. Cell cycle phases were analyzed by using propidium iodide DNA staining and a flow cytometer equipped with the BD CellQuest Pro Software (BD Bioscience, USA). Briefly, PEF cells were dissociated with 0.25% Trypsin-EDTA (Gibco). The obtained cells were fixed with cold DPBS supplemented with 70% ethanol for 1 h on ice, followed by a single washing with cold DPBS, and incubation with 10 mg/ml RNase A for 1 h (Invitrogen). Finally, the DNA was stained with 1 mg/mL propidium iodide at 4℃ until analysis.

Statistical analysis

The relative quantitative PCR data were processed by applying the 2−ΔΔCt method with GAPDH as an internal control. Statistical significance was analyzed by using SPSS software (ver. 17.0, SPSS, USA). Data are presented as mean ± SEM values. Statistical significance is indicated by p < 0.05 (*) or p < 0.01 (**).

Results

Cloning and identification of the pig RPL21 gene

The full-length cDNA of the porcine RPL21 gene was cloned and identified in this study (GenBank accession No. KU891824). The porcine RPL21 gene is located on the “+” strand of chromosome 11 and spans 2167 bp from 4199792 to 4201958. It includes five exons (panel A in Fig. 1) that are 150 bp, 62 bp, 113 bp, 151 bp, and 128 bp in length. The corresponding introns behind each exon are 148 bp, 369 bp, 934 bp, and 114 bp in length, respectively. There are many termination codons that are found at intervals within the cloned sequences, but only one ORF of 483 bp in length that codes for 160 amino acids was identified. An “AAA (ATG) A” context and a typical “TTTTCT” oligopyrimidine tract was identified in the 83 bp 5′ noncoding region, where the pyrimidine residues accounted for up to 58% of the total sequences. With regard to the 38 bp 3′ noncoding region, as expected, an “AATAAA” cleavage-polyadenylation site was identified (panel B in Fig. 1).

Homology analysis and annotation of pig RPL21 amino acid

Amino acid sequences of the RPL21 protein from human, mouse, dog, cattle, rat, and zebrafish were aligned with our cloned pig RPL21. We found that the pig protein had a completely identical sequence with that of human and dog. Moreover, there was only 1 amino acid difference from that in the mouse sequence and 2 amino acids difference from the cattle and rat sequences (panel A in Fig. 2). Pig RPL21 shares 99.38% (159/160), 98.75% (158/160), and 98.75% (158/160) sequence similarity with the RPL21 of mouse, cattle, and rat, respectively. Even in the comparison with zebrafish, which is on a different branch of the evolutionary tree, pig had an approximately 85% (136/160) homology (panel B in Fig. 2).
In addition, conservation of the RPL21 N-terminal region is much higher than that in its C-terminal region. Given this, we checked the features in the vicinity of the pig RPL21 terminal region. We observed an SH3-like barrel topology structure in the amino acid sequence from 1 to 100 and an N-glycosylation site from 66 to 69 (shown in bold-red font in panel B in Fig. 1) at a probability of 76.3%. In addition, in porcine RPL21, there was a conserved β-strand, similar to that in archaeal RPL21e, and an extension unique to eukaryotes (panel C in Fig. 1).
To clarify the phylogenetic location of pig RPL21, a phylogenetic tree was constructed based on the amino acid sequences from 13 other species. As shown in panel B in Fig. 2, pig RPL21 was positioned on a branch of the mammalian sub-cluster and was most similar to that from human and dog (panel B in Fig. 2). The 1vx4.1.T modeler in the SWISS-MODEL template library was used as a template to predict the spatial structure of pig RPL21 because it had 99.38% (159/160 amino acids) similarity to our cloned sequences. As shown in panel B in Fig. 1, in total, nine strands and two helices were identified in the secondary structure of pig RPL21.

RPL21 is expressed widely in porcine tissues

Real-time quantitative PCR was performed to determine the expression patterns of RPL21 in various porcine tissues. A standard curve was constructed with serial ten-fold dilutions of the pCX-RPL21 plasmid DNA. As a result, a slope value of −3.2789 and a r-squared value of 0.9945 were derived; results that indicate that the efficiency of the amplification reaction was 101.84% and that the amount of product doubles in each cycle (panel A in Fig. 3). On this basis, we performed qPCR with an equivalent template cDNA and found that the pig RPL21 gene is predominantly expressed in the ovary and lung, with less expression in kidney, small intestine, and skin, and the lowest expression levels in heart and liver (panel A in Fig. 3). This expression pattern is generally consistent with that reported in human-based study (panel C in Fig. 3).

Overexpression of pig RPL21 in PEF

To confirm the predicted protein functionality, we inserted the CDS region of the pig RPL21 gene into a eukaryotic expression vector, pCAGGS-EGFP-Puro (panel A in Fig. 4). Two days after transfection, the expression level of RPL21 mRNA was significantly up-regulated (p < 0.05), more than 8-fold (panel B in Fig. 4), and a protein with molecular weight of approximately 18.5 kDa was detected in the western blot results from transfected cells. This result is consistent with that predicted by our assessment of cloned sequences (panel C in Fig. 4). In addition, we found a fluorescence signal of the FLAG-tagged RPL21 protein in both the cytoplasm and nuclei (panel D in Fig. 4).

Knockdown of RPL21 affects cell proliferation and cell cycle

To assess the effect of RPL21 down-regulation on cell growth, a vector that expressed shRNAs was infected into PEF cells. After transduction, the shRNA vector produced a significant decrease in the level of RPL21 expression (panel A in Fig. 5). More importantly, cell proliferation activity was significantly decreased (p < 0.01), by nearly 36%, in the knockdown group compared to those in wild-type PEF cells and PEF cells transfected with an empty pLKO.1 vector (panel B in Fig. 5). Hence, we checked the expression levels of 6 proteins that are related to the cell cycle and apoptosis. The results showed that the expression of p53 and p21 significantly increased (p < 0.05) (panel C in Fig. 5), but the caspase-3, cytochrome c, bax, and bcl-2 expression levels were unaffected (data not shown). To determine whether knockdown of RPL21 inhibited cell proliferation by influencing the cell cycle distribution pattern, the DNA content from wild-type PEF cells and lentiviral vector-infected PEF cells was analyzed. The results demonstrated that knockdown of RPL21 induces an obvious depletion of cells at the G0/G1 and S phases with a simultaneous accumulation of cells at the G2/M phase (panel D in Fig. 5).

Discussion

The mRNA and amino acid sequences of RPL21 in several species have been previously reported [2029]. However, there has been little reported on the pig RPL21 gene prior to this study. Herein, we report on our analysis of cloned sequences, the results of which showed that pig RPL21 has many typical features in both its mRNA and amino acid sequences. For example, we found that pig RPL21 mRNA consists of 5 exons, which is similar to that of the human gene [9]. However, pig RPL21 does not have the common Kozak sequence around the translation initiation site, a sequence that is thought to be important in the initiation of the translation process and always occurs in eukaryotic mRNAs [617]. Instead, pig, human, and rat share the same “AAAATGA” context, rather than the common “ACCATGG” in other species [917]. Many eukaryotic RP mRNAs are rich in pyrimidine residues in their 5′ UTR region, which is a common feature in other well-characterized RPs that play important roles in regulating transcription [824]. Therefore, we scanned the 5′ UTR region of pig RPL21 and found a “TTTTCT” oligopyrimidine tract, as expected. In addition to mRNA sequences, RPs appear to be well-conserved throughout evolution [37]. Thus, we analyzed pig RPL21 amino acid structure and observed an SH3-like domain in pig RPL21, which may indicate that pig RPL21 is an SH3 domaincontaining protein, as has been reported for RPL6, RPL14, and RPL16 [15].
Most ribosomal genes can be considered housekeeping genes because of their breadth of expression in almost all cell types [1225]. However, there are a few exceptions, such as the RPL19 [28], RPL3-like, and RPL39-like genes that are only expressed in a few tissues [35]. In this study, all 6 pig tissues showed detectable levels of RPL21 expression. Similar to RPL21 expression distribution in human tissues [35], the highest level of RPL21 expression in pig was in ovary. This may be because a high level of metabolism or protein synthesis is needed in ovary tissue.
Next, we studied the localization of pig RPL21 and found it was localized in both cytoplasm and nuclei, as has been reported for RPL5 [30]. However, our result is different from that for human RPL21, which is mainly localized in cytoplasm. There are three major potential causes of this difference: first, we used a FLAG oligomeric peptide to tag the RPL21 protein instead of using the RPL21 antibody directly; this may have led to a change in the normal localization pattern of the protein [31], second, many RPs need to be transported into the nucleus after their synthesis in the cytoplasm [26], and third, because an overabundance of tagged proteins is produced by overexpression, they may fail to incorporate into ribosomes and may become scattered across the nuclear region.
RPs have important roles in the process of cell growth. The abnormal expression of RPs can cause defective ribosome biogenesis and trigger ribosomal stress (also termed nucleolar stress), leading to p53-dependent cell cycle arrest or apoptosis [411]. Generally, an increased expression of p53 and p21 has been observed in cells that arrest at the G1 phase; however, in some cases, the induction of G2 arrest by p53 and p21 also has been reported [134]. In this study, knockdown of pig RPL21 induced an obvious accumulation of cells at the G2/M phase with a simultaneous up-regulation of p53 and p21. This likely due to knockdown of RPL21 affecting normal ribosome assembly. The unassembled RPs subsequently relocate from the nucleolus to the nucleoplasm where they can bind to Mdm2 and activate the expression of p53, p21, and other responsive factors that related to cell cycle arrest [745]. Certainly, the detailed regulatory mechanism between the p53 signaling pathway and RPs is very complex [36], and further research is needed.
Many fundamental investigations into pig RPL21 were included in this study, such as assessment of RPL21 conservation, sequence signature, spatial structure, expression pattern, and protein localization, among others. Although we did not perform a systematic study into the molecular mechanisms involved in pig RPL21 function, we did observe that the RPL21 expression level is closely associated with cell proliferation and cell cycle arrest. We anticipate that the results of this study may provide a basis for further study of the pig RPL21 gene and hypotrichosis simplex.

Figures and Tables

Fig. 1

Sequence analysis of the porcine ribosomal protein L21 (RPL21) gene and its inferred amino acid sequence. (A) The schematic representation of the porcine RPL21 gene mapped to chromosome 11. Blue boxes represent the gene's five exons; there are four intron regions between the exons. (B) Nucleotides and the inferred amino acid sequence of the pig RPL21 gene. Pink cylinders are helices, and yellow rectangles with an arrow represent strands in the deduced secondary structure. Blue lines represent coils. The start codon and stop codon are indicated by red boxes. A possible N-glycosylation site is shown in red letters. Sequences before the ATG refer to the noncoding region. The “A” in the initiation codon “ATG” is taken as +1. Numbers on the right side of panel B represent the deduced amino acid sequence. (C) The predicted three-dimensional structure of the pig RPL21 protein. Positions of the N and C termini are shown in capital letters.

jvs-18-531-g001
Fig. 2

Conservation and phylogenetic analysis of pig ribosomal protein L21 (RPL21) protein. (A) Multiple sequence alignment of the RPL21 amino acid sequences across various species. In total, twenty conserved regions were identified and are indicated by yellow shading. The mutation site reported to cause hypotrichosis simplex is indicated with a red box. (B) Phylogenetic analysis of porcine RPL21 protein with its 12 homologous counterparts has been published previously (accession Nos. in National Center for Biotechnology Information are presented in brackets). Pig, dog, human, mouse, cattle, and rat share more than 95% identity at the amino acid level. The 13 species are Sus scrofa (S.scrofa); Mus musculus (M.musculus); Bos taurus (B.taurus); Canis lupus familiaris (C.lupus); Rattus norvegicus (R.norvegicus); Danio rerio (D.rerio); Homo sapiens (H.sapiens); Xenopus tropicalis (X.tropicalis); Drosophila melanogaster (D.melanogaster); Caenorhabditis elegans (C.elegans); Saccharomyces cerevisiae S288c (S.cerevisiae), and Schizosaccharomyces pombe 972h (S.pombe).

jvs-18-531-g002
Fig. 3

The expression pattern of the ribosomal protein L21 (RPL21) gene in different tissues. (A) A standard curve was constructed with serial ten-fold dilutions of the pCX-RPL21 plasmid DNA by quantitative polymerase chain reaction. (B) The transcript abundance level of RPL21 mRNA in 7 pig tissues. RPL21 is relatively highly expressed in ovary and lung, less so in kidney, small intestine, and skin, and expressed at the lowest level in heart and liver. With the exception of kidney, this expression pattern is similar to that in human tissues (C). Data are presented as mean ± SEM values. Similar results were observed in more than two independent experiments.

jvs-18-531-g003
Fig. 4

Overexpression of pig ribosomal protein L21 (RPL21) in a pig fibroblast cell line. (A) Schematic diagram of the vector used for RPL21 overexpression. (B) There was more than an 8-fold change in the expression level of RPL21 mRNA after transfection with pCX-RPL21 vector. (C) The deduced protein with a molecular weight of approximately 18.5 kDa was confirmed by western blotting. (D) Pig RPL21 localized to both cytoplasm and nuclei as detected by double immunofluorescence staining. Beta-actin was used as an internal control for the western blot analysis. Glyceraldehyde 3-phosphate dehydrogenase was used as an internal control for the real-time polymerase chain reaction. Data are presented as mean ± SEM values. *p < 0.05 vs. normal. Similar results were observed in more than two independent experiments. Scale bars = 10 µm.

jvs-18-531-g004
Fig. 5

Knockdown of ribosomal protein L21 (RPL21) may inhibit the proliferation of porcine ear skin fibroblast (PEF) cells and induce cell cycle arrest. (A) Real-time polymerase chain reaction (PCR) results show a significant decrease in the level of RPL21 expression following RNA interference. (B) Knockdown of RPL21 significantly inhibited the proliferation of PEF cells. (C) The expression levels of p53 and p21 protein were investigated by western blotting. (D) Knockdown of RPL21 led to G2 arrest. Beta-actin was used as an internal control in the western blotting. Glyceraldehyde 3-phosphate dehydrogenase was used as an internal control for real-time PCR. Data are presented as mean ± SEM values. *p < 0.05, **p < 0.01 vs. normal. Similar results were observed in more than two independent experiments.

jvs-18-531-g005
Table 1

Oligonucleotide primers used in this study

jvs-18-531-i001

V = A, C or G. N = A, C, G, or T. RACE, rapid amplification of cDNA ends; ORF, open reading frame; PCR, polymerase chain reaction; GAPDH, glyceraldehyde 3-phosphate dehydrogenase; RPL21, ribosomal protein L21.

Acknowledgments

This work was carried out with the support of Next Generation Biogreen 21 (project No. PJ0110412016) of the Rural Development Administration and funded by the KRIBB Research Initiative Program, Republic of Korea.

Notes

Conflict of Interest The authors declare no conflicts of interest.

References

1. Agarwal ML, Agarwal A, Taylor WR, Stark GR. p53 controls both the G2/M and the G1 cell cycle checkpoints and mediates reversible growth arrest in human fibroblasts. Proc Natl Acad Sci U S A. 1995; 92:8493–8497.
crossref
2. Artimo P, Jonnalagedda M, Arnold K, Baratin D, Csardi G, de Castro E, Duvaud S, Flegel V, Fortier A, Gasteiger E, Grosdidier A, Hernandez C, Ioannidis V, Kuznetsov D, Liechti R, Moretti S, Mostaguir K, Redaschi N, Rossier G, Xenarios I, Stockinger H. ExPASy: SIB bioinformatics resource portal. Nucleic Acids Res. 2012; 40:W597–W603.
crossref
3. Bhavsar RB, Makley LN, Tsonis PA. The other lives of ribosomal proteins. Hum Genomics. 2010; 4:327–344.
crossref
4. Chakraborty A, Uechi T, Kenmochi N. Guarding the ‘translation apparatus’: defective ribosome biogenesis and the p53 signaling pathway. Wiley Interdiscip Rev RNA. 2011; 2:507–522.
crossref
5. Chenna R, Sugawara H, Koike T, Lopez R, Gibson TJ, Higgins DG, Thompson JD. Multiple sequence alignment with the Clustal series of programs. Nucleic Acids Res. 2003; 31:3497–3500.
crossref
6. De Angioletti M, Lacerra G, Sabato V, Carestia C. β+45 G → C: a novel silent β-thalassaemia mutation, the first in the Kozak sequence. Br J Haematol. 2004; 124:224–231.
crossref
7. Deisenroth C, Zhang Y. The ribosomal protein-Mdm2-p53 pathway and energy metabolism: bridging the gap between feast and famine. Genes Cancer. 2011; 2:392–403.
crossref
8. Devi KR, Chan YL, Wool IG. The primary structure of rat ribosomal protein S4. Biochim Biophys Acta. 1989; 1008:258–262.
crossref
9. Frigerio JM, Dagorn JC, Iovanna JL. Cloning, sequencing and expression of the L5, L21, L27a, L28, S5, S9, S10 and S29 human ribosomal protein mRNAs. Biochim Biophys Acta. 1995; 1262:64–68.
crossref
10. Harms J, Schluenzen F, Zarivach R, Bashan A, Gat S, Agmon I, Bartels H, Franceschi F, Yonath A. High resolution structure of the large ribosomal subunit from a mesophilic eubacterium. Cell. 2001; 107:679–688.
crossref
11. Hou YL, Ding X, Hou W, Song B, Wang T, Wang F, Li J, Zhong J, Xu T, Ma BX, Zhu HQ, Li JH, Zhong JC. Overexpression, purification, and pharmacologic evaluation of anticancer activity of ribosomal protein L24 from the giant panda (Ailuropoda melanoleuca). Genet Mol Res. 2013; 12:4735–4750.
crossref
12. Hsiao LL, Dangond F, Yoshida T, Hong R, Jensen RV, Misra J, Dillon W, Lee KF, Clark KE, Haverty P, Weng Z, Mutter GL, Frosch MP, MacDonald ME, Milford EL, Crum CP, Bueno R, Pratt RE, Mahadevappa M, Warrington JA, Stephanopoulos G, Stephanopoulos G, Gullans SR. A compendium of gene expression in normal human tissues. Physiol Genomics. 2001; 7:97–104.
crossref
13. Jones P, Binns D, Chang HY, Fraser M, Li W, McAnulla C, McWilliam H, Maslen J, Mitchell A, Nuka G. InterProScan 5: genome-scale protein function classification. Bioinformatics. 2014; 30:1236–1240.
crossref
14. Kiefer F, Arnold K, Künzli M, Bordoli L, Schwede T. The SWISS-Model Repository and associated resources. Nucleic Acids Res. 2009; 37:D387–D392.
crossref
15. Klinge S, Voigts-Hoffmann F, Leibundgut M, Arpagaus S, Ban N. Crystal structure of the eukaryotic 60S ribosomal subunit in complex with initiation factor 6. Science. 2011; 334:941–948.
crossref
16. Korobeinikova AV, Garber MB, Gongadze GM. Ribosomal proteins: structure, function, and evolution. Biochemistry (Mosc). 2012; 77:562–574.
crossref
17. Kozak M. Point mutations define a sequence flanking the AUG initiator codon that modulates translation by eukaryotic ribosomes. Cell. 1986; 44:283–292.
crossref
18. Kwon DJ, Jeon H, Oh KB, Ock SA, Im GS, Lee SS, Im SK, Lee JW, Oh SJ, Park JK, Hwang S. Generation of leukemia inhibitory factor-dependent induced pluripotent stem cells from the Massachusetts General Hospital miniature pig. Biomed Res Int. 2013; 2013:140639.
crossref
19. Lee C, Kim J, Shin SG, Hwang S. Absolute and relative QPCR quantification of plasmid copy number in Escherichia coli. J Biotechnol. 2006; 123:273–280.
crossref
20. Lin A, Chan YL, Jones R, Wool IG. The primary structure of rat ribosomal protein S12. The relationship of rat S12 to other ribosomal proteins and a correlation of the amino acid sequences of rat and yeast ribosomal proteins. J Biol Chem. 1987; 262:14343–14351.
crossref
21. Lindström MS. Emerging functions of ribosomal proteins in gene-specific transcription and translation. Biochem Biophys Res Commun. 2009; 379:167–170.
crossref
22. Liu JM, Ellis SR. Ribosomes and marrow failure: coincidental association or molecular paradigm. Blood. 2006; 107:4583–4588.
crossref
23. Loreni F, Francesconi A, Jappelli R, Amaldi F. Analysis of mRNAs under translational control during Xenopus embryogenesis: isolation of new ribosomal protein clones. Nucleic Acids Res. 1992; 20:1859–1863.
crossref
24. Loreni F, Ruberti I, Bozzoni I, Pierandrei-Amaldi P, Amaldi F. Nucleotide sequence of the L1 ribosomal protein gene of Xenopus laevis: remarkable sequence homology among introns. EMBO J. 1985; 4:3483–3488.
crossref
25. Nygard AB, Jørgensen CB, Cirera S, Fredholm M. Selection of reference genes for gene expression studies in pig tissues using SYBR green qPCR. BMC Mol Biol. 2007; 8:67.
crossref
26. Plafker SM, Macara IG. Ribosomal protein L12 uses a distinct nuclear import pathway mediated by importin 11. Mol Cell Biol. 2002; 22:1266–1275.
crossref
27. Plaks V, Gershon E, Zeisel A, Jacob-Hirsch J, Neeman M, Winterhager E, Rechavi G, Domany E, Dekel N. Blastocyst implantation failure relates to impaired translational machinery gene expression. Reproduction. 2014; 148:87–98.
crossref
28. Rebouças EL, Costa JJN, Passos MJ, Passos JRS, van den Hurk R, Silva JRV. Real time PCR and importance of housekeepings genes for normalization and quantification of mRNA expression in different tissues. Braz Arch Biol Technol. 2013; 56:143–154.
crossref
29. Rosendahl G, Andreasen PH, Kristiansen K. Structure and evolution of the Tetrahymena thermophila gene encoding ribosomal protein L21. Gene. 1991; 98:161–167.
30. Rosorius O, Fries B, Stauber RH, Hirschmann N, Bevec D, Hauber J. Human ribosomal protein L5 contains defined nuclear localization and export signals. J Biol Chem. 2000; 275:12061–12068.
crossref
31. Snapp E. Design and use of fluorescent fusion proteins in cell biology. Curr Protoc Cell Biol. 2005; Suppl 27. Unit 21.4.
crossref
32. Su AI, Wiltshire T, Batalov S, Lapp H, Ching KA, Block D, Zhang J, Soden R, Hayakawa M, Kreiman G, Cooke MP, Walker JR, Hogenesch JB. A gene atlas of the mouse and human protein-encoding transcriptomes. Proc Natl Acad Sci U S A. 2004; 101:6062–6067.
crossref
33. Tamura K, Peterson D, Peterson N, Stecher G, Nei M, Kumar S. MEGA5: Molecular Evolutionary Genetics Analysis using maximum likelihood, evolutionary distance, and maximum parsimony methods. Mol Biol Evol. 2011; 28:2731–2739.
crossref
34. Taylor WR, Stark GR. Regulation of the G2/M transition by p53. Oncogene. 2001; 20:1803–1815.
crossref
35. Thorrez L, Van Deun K, Tranchevent LC, Van Lommel L, Engelen K, Marchal K, Moreau Y, Van Mechelen I, Schuit F. Using ribosomal protein genes as reference: a tale of caution. PLoS One. 2008; 3:e1854.
crossref
36. Wang W, Nag S, Zhang X, Wang MH, Wang H, Zhou J, Zhang R. Ribosomal proteins and human diseases: pathogenesis, molecular mechanisms, and therapeutic implications. Med Res Rev. 2015; 35:225–285.
crossref
37. Warner JR. Synthesis of ribosomes in Saccharomyces cerevisiae. Microbiol Rev. 1989; 53:256–271.
38. Warner JR, McIntosh KB. How common are extraribosomal functions of ribosomal proteins. Mol Cell. 2009; 34:3–11.
crossref
39. Weisberg RA. Transcription by moonlight: structural basis of an extraribosomal activity of ribosomal protein S10. Mol Cell. 2008; 32:747–748.
crossref
40. Wool IG. The structure and function of eukaryotic ribosomes. Annu Rev Biochem. 1979; 48:719–754.
crossref
41. Wool IG, Chan YL, Glück A. Structure and evolution of mammalian ribosomal proteins. Biochem Cell Biol. 1995; 73:933–947.
crossref
42. Xie M, Kobayashi I, Kiyoshima T, Nagata K, Ookuma Y, Fujiwara H, Sakai H. In situ expression of ribosomal protein L21 in developing tooth germ of the mouse lower first molar. J Mol Histol. 2009; 40:361–367.
crossref
43. Yusupova G, Yusupov M. High-resolution structure of the eukaryotic 80S ribosome. Annu Rev Biochem. 2014; 83:467–486.
crossref
44. Zhang W, Hawse J, Huang Q, Sheets N, Miller KM, Horwitz J, Kantorow M. Decreased expression of ribosomal proteins in human age-related cataract. Invest Ophthalmol Vis Sci. 2002; 43:198–204.
45. Zhang Y, Lu H. Signaling to p53: ribosomal proteins find their way. Cancer Cell. 2009; 16:369–377.
crossref
46. Zhou C, Zang D, Jin Y, Wu H, Liu Z, Du J, Zhang J. Mutation in ribosomal protein L21 underlies hereditary hypotrichosis simplex. Hum Mutat. 2011; 32:710–714.
crossref
TOOLS
Similar articles