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.
1. Introduction
Arginine methylation is a common posttranslational modification of proteins, playing an essential role in several biological processes, such as mRNA splicing, DNA repair, transcription regulation, and signal transduction [1–4]. In mammals, arginine methylation is catalyzed by protein arginine methyltransferases (PRMTs) through transferring methyl groups from S-adenosylmethionine to the specific arginine residues of protein substrates [5]. Currently, nine PRMTs have been characterized and classified into type I, type II, and type III PRMTs according to the type of catalyzed arginine methylation reaction. Among these three types of PRMTs, type I PRMTs which contain PRMT1, PRMT2, PRMT3, PRMT4/CARM1 (coactivator associated arginine methyltransferase 1), PRMT6, and PRMT8 catalyze the formation of monomethylarginine and asymmetric dimethylarginine. Type II PRMTs which contain PRMT5 and PRMT9 catalyze the formation of monomethylarginine and symmetric dimethylarginine, whereas type III PRMT7 can only catalyze the formation of monomethylarginine [6–8].
Most PRMTs tend to methylate glycine- and arginine-rich motifs in proteins [9]. For example, PRMT1, PRMT3, and PRMT6 target glycine- and arginine-rich motifs, which are related to the regulation of nucleic acid and protein interactions [9–13]. PRMT4 (also known as CARM1) methylates proline-, glycine-, and methionine-rich motifs located on splicing and transcription elongation factors, which can affect alternative splicing [14]. PRMT5 can methylate glycine- and arginine-rich motifs as well as proline-, glycine-, and methionine-rich motifs [14, 15]. However, PRMT7 can specifically methylate a motif in lysine- and arginine-rich regions, which contains a pair of arginine residues separated by one residue [16, 17]. To date, the known substrates methylated by PRMT7 include the core histones (H2A, H2B, H3, and H4), the Wnt signaling molecule Dishevelled3, and the transcription factor C/EBP-β, implying that PRMT7 could be involved in a wide range of cellular processes both in normal and disease states [8, 18–20]. In this review, we mainly focus on the roles of PRMT7 in stem cells and in murine and human development. By summarizing the functions of PRMT7 in mouse embryonic stem cells (ESCs), induced pluripotent stem cells (iPSCs), muscle stem cells (MuSCs), and cancer stem cells, we found that PRMT7 was crucial for the pluripotency, proliferation, and differentiation of stem cells. By summarizing the phenotypes of PRMT7 deficiency or mutation in mice and humans, we concluded that PRMT7 was important for the development of skeletal muscle, neurons, bone, adipose tissues, and male reproduction. This review is aimed at providing information for the development of strategies for the in-depth research of PRMT7 and stem cells as well as their applications in life sciences and medicine.
2. The Roles of PRMT7 in Stem Cells
2.1. The Role of PRMT7 in ESCs
Mouse ESCs are the main type of pluripotent cells that have attracted considerable research interest since they were defined [21–23]. However, the mechanisms underlying their functions are still being explored. In 2008, given the pluripotent characteristics of mouse ESCs and embryonic germ cells, Buhr et al. performed nuclear proteome analysis to identify the nuclear proteins potentially associated with pluripotency. Finally, they discovered a new protein, PRMT7, which behaved as a candidate protein related to pluripotency [24].
The further functional study revealed that PRMT7 depletion in mouse ESCs using shRNA led to spontaneous differentiation and G1 arrest of the cell cycle, suggesting the crucial role of PRMT7 in stemness maintenance [25]. The mechanistic analysis in this study discovered that PRMT7 played an inhibitory role in the expression of miR-24-2 gene-encoding miR-24-3p and miR-24-2-5p. Overexpression of miR-24-3p/miR-24-2-5p can induce ESC differentiation similar with PRMT7 depletion. Moreover, inhibition of miR-24-3p/miR-24-2-5p can reverse ESC differentiation induced by PRMT7 depletion. In addition, as the key pluripotency factors, Oct4, Nanog, Klf4, and c-Myc were also detected [26–29]. It turned out that the expression of Oct4, Nanog, Klf4, and c-Myc was repressed after PRMT7 depletion or miR-24-3p/miR-24-2-5p overexpression. Overall, these results demonstrate that PRMT7 is crucial for the maintenance of ESC stemness by repressing miR-24-3p and miR-24-2-5p as well as pluripotency factors Oct4, Nanog, Klf4, and c-Myc.
Later, to gain deeper insight into the molecular mechanism underlying how PRMT7 regulated the pluripotency of mouse ESCs, additional miRNAs were identified to be involved in the maintenance of mouse ESC stemness. As a result, miR-221 gene-encoding miR-221-3p and miR-221-5p were discovered as negative regulators for the maintenance of mouse ESC stemness through their direct repression by PRMT7 [30]. The study demonstrated that miR-221-3p and miR-221-5p not only downregulated the expression of Oct4, Nanog, and Sox2 but also induced spontaneous differentiation of mouse ESCs, which is similar to the results from PRMT7 depletion experiments. Further, inhibition of miR-221-3p and miR-221-5p can block PRMT7 depletion-induced differentiation of mouse ESCs. Therefore, these results demonstrate that besides miR-24-3p and miR-24-2-5p, PRMT7 also mediates the repression of miR-221-3p and miR-221-5p which can target and downregulate Oct4, Nanog, and Sox2, thus playing crucial roles in maintaining the stemness of mouse ESCs.
Notably, both mouse mature oocytes and ESCs can reprogram somatic cells to a pluripotent state through somatic cell nuclear transfer and cell fusion, respectively [31–35]. Therefore, to survey reprogramming factors, a proteome analysis of mouse mature oocytes and ESCs was performed. PRMT7 was identified as a candidate reprogramming factor common to mouse mature oocytes and ESCs [36]. To better determine the role of PRMT7 in inducing pluripotency, each one of the four general reprogramming factors, namely, Oct4, Sox2, Klf4, and c-Myc, used to generate mouse iPSCs was replaced by PRMT7. Results showed that PRMT7 can replace Sox2 to establish iPSCs in combination with Oct4, Klf4, and c-Myc [37, 38]. Taken together, these findings suggest that PRMT7 is a pivotal regulator of the pluripotency of both mouse ESCs and iPSCs.
2.2. The Role of PRMT7 in MuSCs
MuSCs are responsible for muscle growth and repair by sustained self-renewal and differentiation [39, 40]. vanLieshout et al. discovered that PRMT1, PRMT4, PRMT5, and PRMT7 were the most abundantly expressed PRMTs in human muscle, implying the potential role of these four PRMTs in muscle development [41].
Thereafter, PRMT5 was first studied in skeletal MuSCs. The results demonstrated that PRMT5 could control the proliferation of adult mouse MuSCs by directly silencing the cell cycle inhibitor p21 [42]. Similarly, Blanc et al. found that PRMT7-deficient MuSCs also underwent cell cycle arrest with increased p21 levels [43]. Further analysis revealed that PRMT7 was preferentially expressed and colocalized with Pax7, a marker of quiescent skeletal muscle stem cells [44, 45], in the nuclei of MuSCs. In the process of differentiation, when the majority of wild-type MuSCs underwent differentiation, PRMT7-/- MuSCs displayed defects in differentiation. RNA sequencing analysis revealed that PRMT7 was a cell cycle regulator. Subsequently, the immunoblotting assay confirmed the elevated levels of the cell cycle inhibitor p21 in PRMT7-/- MuSCs. As a known repressor of p21, the expression of DNMT3b usually is inversely correlated with that of p21 [46]. So, the expression of DNMT3b in PRMT7-deficient MuSCs was assessed, which showed that PRMT7 deficiency reduced the expression of DNMT3b in MuSCs. In addition, given that elevated expression of p21 is a cellular senescence marker [47, 48], further experiments revealed that PRMT7-deficient MuSCs or myoblast cell line existed senescence. Restoring DNMT3b expression can rescue the senescence and decline p21 expression induced by PRMT7 deficiency. These discoveries demonstrate that PRMT7 plays a vital role in skeletal muscle development by regulating the proliferation and differentiation of MuSCs through the DNMT3b/p21 pathway.
2.3. PRMT7 in Human Cancer and Cancer Stem Cells
Through a meta-analysis of gene expression in more than 120 breast tumors, PRMT7 was identified as a potential metastasis-promoting gene in breast cancer [49]. In cancer, epithelial-to-mesenchymal transition (EMT) could cause metastasis, and loss of E-cadherin expression is a hallmark of EMT [50, 51]. PRMT7 was reported to be highly expressed in breast carcinoma cells in which it inhibited E-cadherin expression, consequently mediating breast cancer metastasis. Silencing PRMT7 can restore E-cadherin expression [52]. Accordingly, PRMT7 was also overexpressed in breast cancer tissues and invasive breast cancer cells. Reduced expression of PRMT7 inhibited breast cancer cell invasion both in vitro and in vivo. Further mechanistic study revealed that PRMT7 promoted breast cancer cell invasion by regulating MMP9 (matrix metalloproteinase 9) which is a famous mediator of breast cancer metastasis [53]. Moreover, as a methyltransferase, PRMT7 mediated E-cadherin expression through PRMT7 automethylation, which consequently triggered EMT [54]. In addition to direct inhibition and automethylation, a recent study discovered that PRMT7 promoted the metastasis of human breast cancer by methylating the arginine of SHANK2 (SH3 and multiple ankyrin repeat domains 2), consequently activating endosomal FAK (focal adhesion kinase) signaling [55], which led to cancer cell growth to a malignant phenotype [56]. These findings demonstrate that PRMT7 plays a pivotal role in breast cancer metastasis through downregulating E-cadherin, upregulating MMP9, and activating FAK. Targeting PRMT7 expression or enzyme activity could be a therapeutic strategy for human breast cancer.
Similar function of PRMT7 has also been reported in human non-small-cell lung cancer (NSCLC). An online database analysis indicated that lung cancer tissues exhibited higher PRMT7 expression than healthy tissues [57]. The functional study demonstrated that overexpression of PRMT7 promoted NSCLC cell invasion and colony formations. The coimmunoprecipitation assay against PRMT7 combined with mass spectrometry analysis with two types of NSCLC cell lines, namely, A549 and SPC-A1, discovered 19 shared target proteins. Among these in-common targets, HASP5 (heat shock protein 5) and EEF2 (eukaryotic translation elongation factor 2) were validated interacting with PRMT7. Both HASP5 knockdown and EEF2 knockdown can significantly restore PRMT7 overexpression-induced NSCLC invasion, indicating that PRMT7 promoted metastasis in NSCLC likely through interacting with HSPA5 and EEF2, which provides information on the mechanism of lung cancer metastasis and a candidate target gene in lung cancer. In addition to breast cancer and lung cancer, it was recently found that PRMT7 expression was increased in clear cell renal cell carcinoma tissues as well. There was a close correlation between increased PRMT7 expression and poor prognosis of clear cell renal cell carcinoma [58]. Further assays discovered that PRMT7 promoted the proliferation of renal cell carcinoma both in vitro and in vivo. Mechanistically, PRMT7 upregulated c-Myc expression, which was blocked by knocking down β-catenin. PRMT7 kept β-catenin stabilization by methylating β-catenin and thus inhibiting its ubiquitination as well as degradation. Overall, PRMT7 also serves as an oncogene in renal cell carcinoma via the β-catenin/c-Myc pathway.
As abovementioned, PRMT7 maintained mouse ESC stemness by repressing miR-24-2 gene-encoding miR-24-3p and miR-24-2-5p [25]. We noticed that miR-24-2 was also associated with human tumorigenesis, but it had both tumor suppressive and oncogenic effects on different cancer types. For example, it promoted the development of gastric cancer and esophageal squamous cell carcinoma [59, 60] but decreased the tumorigenicity of MCF-7 breast cancer cells and served as a negative biomarker of colorectal cancer [61, 62]. Liver cancer as one of the most common cancers can cause a high mortality rate, which is mainly attributed to liver cancer stem cells (hLCSCs). The hLCSCs exhibit the properties of stem cells, namely, self-renewal and differentiation, which have been considered a therapeutic target of liver cancer [63]. Therefore, Wang and colleagues explored the roles and relationship between miR-24-2 and PRMT7 in hLCSCs [64]. Similar to the findings in mouse ESCs, miR-24-2 also targeted the 3
3. The Roles of PRMT7 in Development
3.1. Phenotypes of PRMT7 Deficiency in Mice and Humans
An optimal way to better understand the roles of a gene at an individual level is to study the effects of a gene’s loss-of-function. In 2015, Ying et al. generated PRMT7-/- mice with a C57/bl6-129sv background. However, most PRMT7-/- mice died within 5~10 days after birth, indicating the essential role of PRMT7 in normal development [65]. Moreover, when PRMT7 was deleted in C57BL6/J mice, these mice were subviable as only 45% of the expected number of PRMT7-/- pups were obtained at postnatal day 14. At postnatal day 10, the PRMT7-/- pups displayed reduced body size and weight, as well as skeletal defects. The adult PRMT7-/- mice showed limb bone anomalies, reduced length, and increased fat mass [66]. However, Blanc and colleagues revealed that PRMT7-/- mice were viable, but smaller at birth than wild-type mice. Although the weight difference was sustained only up to 3 months of age, necropsy of 8-month-old PRMT7-/- mice exhibited less skeletal muscle mass and more epididymal fat. Muscles derived from PRMT7-/- mice displayed decreased oxidative metabolism [67]. In addition, Lee and colleagues reported that PRMT7-/- mice showed hyperactivity as well as social interaction defects [68]. These findings demonstrate that PRMT7-/- mice have defects in bone and skeletal muscle mass, delayed or impaired neuronal development, increased adipogenesis, and possibly also reduced male fertility.
Regarding the phenotypes in PRMT7-mutated humans, Akawi and colleagues found recessive causation of PRMT7 in 4125 families following cosegregation studies and performed a more in-depth clinical assessment. After identifying 6 affected females from 3 families with PRMT7 mutation, they observed that the associated clinical phenotype was similar to the phenotype of pseudohypoparathyroidism, namely, Albright hereditary osteodystrophy. The individuals exhibited obesity, mild intellectual disability, symmetrically shortened digits, metatarsals, and posterior metacarpals [66]. Later, a male child was confirmed as PRMT7 null in function, and the child exhibited severe intellectual disability, seizures, short stature, microcephaly, facial dysmorphism, brachydactyly, and cryptorchidism [69]. In the same year, Agolini and colleagues reported 3 additional patients with PRMT7 mutation. The phenotype they exhibited was defined as a novel intellectual disability syndrome, namely, SBIDDS (short stature, brachydactyly, intellectual developmental disability, and seizures) [70]. Whole exome sequencing analysis identified a homozygous private nonsense change in exon 4 and a sibling-shared homozygous missense variant in exon 13 of PRMT7. Thereafter, another patient with SBIDDS was reported additionally displaying psychomotor delay and hearing loss, and two PRMT7 mutations were identified through the patient’s whole exome sequencing [71]. In addition, Birnbaum et al. investigated PRMT7-related syndrome at prenatal and postnatal stages in two male siblings who were homozygous for a mutation in PRMT7 [72]. Both of them displayed intrauterine growth restriction due to the defects in long bone. The first child was terminated, and autopsy findings showed eye tumor, whereas the second child exhibited postnatal growth restriction, skeletal involvement, hypotonia, sensorineural hearing loss, strabismus, genitourinary, and global developmental delay, which provided additional pathological and clinical data and expanded the phenotypes of PRMT7 mutations [72]. These findings indicate that PRMT7 mutations could lead to severe developmental defects in skeletal muscle, neurons, bones, and possibly male reproduction, similar to the phenotypes of PRMT7-/- mice.
3.2. PRMT7 in Skeletal Muscle Development
We have introduced the role of PRMT7 in MuSCs and the skeletal muscle-related phenotypes of PRMT7 mutations in mice and humans. Here, we further summarize the studies on the role of PRMT7 in skeletal muscle development. Through qRT-PCR analysis of adult mouse tissues, including the liver, small intestine, stomach, lung, kidney, spleen, pancreas, heart, skeletal muscle, and white and brown adipose tissues, it is shown that PRMT7 was most abundant in the skeletal muscle. Furthermore, with the qRT-PCR assay and immunofluorescence analysis, it is found that PRMT7 deficiency caused a significantly reduced expression of oxidative fiber markers MyhI and MyhIIa, as well as a substantially increased expression of glycolytic fiber markers MyhIIx and MyhIIb, compared with the wild type [67]. Moreover, PRMT7 expression was lower in obese mice compared with normal mice. Mice with PRMT7 deficiency exhibited less skeletal muscle mass, and PRMT7-/- muscle displayed decreased oxidative metabolism and reduced expression of oxidative metabolism-related genes, such as PGC-1α. Mechanistic studies using PRMT7-/- myoblasts revealed that PRMT7 regulated oxidative metabolism in muscles by activating the p38MAPK/ATF2/PGC-1a pathway. In addition, PRMT7 was also involved in myoblast differentiation since depletion of PRMT7 in myoblasts impaired cell cycle withdrawal and subsequent myogenic differentiation [73]. The underlying mechanism involved PRMT7-mediated methylation of p38MAPK on arginine 70 to activate p38MAPK, which further enhanced MyoD activity to mediate myoblast differentiation [73, 74]. Furthermore, PRMT7 was found to serve as downstream of apigenin (a natural flavone abundant in many plant-derived foods, such as parsley and celery), thus enhancing skeletal muscle hypertrophy and myoblast differentiation by regulating the PGC-1α/GPR56 pathway and the p38MAPK-myoD pathway, respectively [75, 76]. Taking these together, PRMT7 participates in skeletal muscle development by involving in skeletal muscle oxidative metabolism, myoblast differentiation, and hypertrophy through p38MAPK/ATF2/PGC-1a, p38MAPK/myoD, and PGC-1α/GPR56 pathways, respectively.
3.3. PRMT7 in Neuronal Development
Notably, patients with PRMT7 mutations displayed neuron-deficient phenotypes, such as cognitive deficits, brain abnormalities, and seizures, suggesting PRMT7 may play crucial roles in neural development [70]. Dhar and colleagues once used pluripotent human embryonal carcinoma cell line NTERA-2 clone D1 cells to investigate the role of MLL4 (mixed-lineage leukemia 4) in neuronal differentiation. They found that PRMT7, but not PRMT5, antagonized MLL4-mediated neuronal differentiation by repressing MLL4 target genes [77]. Genome-wide association studies and PrediXcan (a gene-based association method) for schizophrenia and bipolar disorder identified that PRMT7 was significantly correlated with schizophrenia. Further analysis showed that PRMT7 was highly expressed in the CA1 field of the hippocampus, and PRMT7-/- mice displayed defects in social behaviors [78]. Recent studies further revealed that PRMT7-/- CA1 neurons exhibited HCN (hyperpolarization-activated, cyclic-nucleotide-gated) channel current dysfunction, which might be attributed to the decreased HCN protein levels mediated by SHANK3 downregulation [68, 79]. These findings provide insights into the role and the underlying mechanisms of PRMT7 functioning in neuronal development.
4. The Roles of PRMT7 in Adipogenesis
Obesity was observed in many patients with PRMT7 mutations [70]. PRMT7 was found expressed in brown and white adipose tissues of mouse, and PRMT7-/- mice at middle age developed obesity with excessive body fat accumulation [67]. Hu and colleagues used C3H10T1/2 mesenchymal cells to investigate the role of PRMT7 in adipogenic differentiation. They found that PRMT7 expression was stable during the adipogenic differentiation process. Neither PRMT7 knockdown nor PRMT7 overexpression affected lipid accumulation or adipogenic gene expression [80]. However, in a recent study, PRMT7-deleted 3T3-L1 preadipocytes or PRMT7-knocked out mouse embryonic fibroblasts displayed increased adipogenesis. In contrast, when PRMT7 was overexpressed, adipogenesis was attenuated. Further analysis discovered that PRMT7 suppressed adipogenesis by interacting with and methylating C/EBP-β [20, 81], which indicates a suppressive role of PRMT7 in adipogenesis.
5. The Roles of PRMT7 in B Cell Development
PRMT7 was also highly expressed in adult lymphoid tissues, including bone marrow and spleen, suggesting its possible roles in immunity [65]. B cells, which are derived from hematopoietic progenitor cells in bone marrow, are critical components of immunity by producing antibodies against pathogens in the human body. Deficient B cell development can cause reduced antibody production, allergy, and malignancy [82]. Therefore, Ying et al. generated B cell-specific PRMT7 conditional knockout mice (PRMT7-CKO mice) for identifying the role of PRMT7 in B cell development [65]. These PRMT7-CKO mice exhibited significant splenomegaly, and their splenic cells showed decreased mature marginal zone B cells and increased follicular B cells, which indicated that PRMT7 deficiency impaired late B cell differentiation and promoted germinal center hyperplasia [82, 83]. In addition, the expression of germinal center gene Bcl6, a master regulator of germinal center B cell program [84, 85], was repressed in PRMT7-CKO mice. The inhibition of Bcl6 expression was attributed to PRMT7 directly binding to its promoter [65]. These findings demonstrate that PRMT7 is important for the germinal center formation during B cell development in immunity through repressing Bcl6 expression.
6. The Roles of PRMT7 in Male Reproduction
Based on the presence of more epididymal fat in PRMT7-/- mice and cryptorchidism in male patients with PRMT7 mutations [67, 70], it is expected that PRMT7 may have a function in male reproduction. Jelinic et al. discovered that PRMT7 was expressed in germ cells of newborn and adult mouse testes [18]. Moreover, PRMT7 interacted with the testis-specific factor CTCFL (CCCTC-binding factor (zinc finger protein)-like), and both were expressed during embryonic male germ cell development. Further analysis revealed that CTCFL functioned as an accessory protein for stimulating PRMT7 activity [18, 86]. A loss-of-function of PRMT7 study demonstrated that PRMT7 was determined as a critical factor for the development of mouse male germ cells during embryonic stages [87]. The size and weight of testes, the diameter of seminiferous tubules, and the number of germ cells were reduced in PRMT7 knockout male mice compared with control mice. Mechanistic analyses revealed that PRMT7 impeded male germ cell proliferation, which was possibly attributed to the TGF-β signaling pathway. In addition, our recent work also discovered that PRMT7 regulated the proliferation of male mouse germ cells (unpublished data). These discoveries imply that PRMT7 has important roles in male reproduction.
7. The Roles of PRMT7 in Cellular Stress and Senescence
Recently, to identify the interactome and potential substrates of PRMT7, Haghandish et al. performed quantitative mass spectrometry experiments and identified eIF2α as a novel substrate of PRMT7. They further discovered that PRMT7 regulated eIF2α-dependent stress granule formation in response to various cellular stresses through methylation and subsequent phosphorylation on Ser51 of eIF2α [88]. Moreover, when PRMT7 was inhibited or knocked out, the levels of arginine monomethylated HSP70 proteins were significantly decreased. Further, PRMT7 can give rise to the methylation of HSP70 on the location of R649 [89]. Given the discoveries that eIF2α as a nonhistone substrate of PRMT7 plays a functional role in cellular stress response and HSP70 family members are associated with stress response [90], it is likely that PRMT7 serves as a crucial mediator in cellular stress response pathways.
Furthermore, PRMT7 was also found to be associated with cellular senescence. Mouse embryonic fibroblasts with PRMT7 knockout underwent premature cellular senescence which was accompanied by increased expression of p16 and p21, two known cell cycle inhibitors [91, 92]. Further results revealed that PRMT7 positively interacted with GLI2 (glioma-associated oncogene 2) and methylated GLI2 to enhance GLI2-mediated sonic hedgehog signaling activity, which reportedly is a signaling associated with cellular senescence [93, 94]. Overall, these data demonstrate that PRMT7 functions to prevent cellular senescence, suggesting the potential role of PRMT7 in antiaging.
8. Conclusions
PRMT7 has been the subject of extensive researches over the past two decades. Genetic deficiency of PRMT7 causes a range of abnormalities in mice and humans. PRMT7-/- mice showed reduced body size, shortened metatarsal bones, and declined survival rate shortly after birth, while surviving adult mice showed increased fat mass. The phenotypes of PRMT7 mutations in humans are mainly represented as SBIDDS syndrome. The common or similar phenotypes of PRMT7-/- mice and humans with PRMT7 mutations demonstrated the crucial roles of PRMT7 in the development of skeletal muscle, neurons, bone, adipose tissues, and male reproduction.
Here, we reviewed the recent research findings regarding the biological functions of PRMT7 (Figure 1). In particular, we discussed in detail the roles of PRMT7 in stem cells, including mouse ESCs, iPSCs, and MuSCs, the development of skeletal muscle and neurons, and the process of adipogenesis. Future work should also be aimed at identifying the specific substrates and functions of PRMT7, as well as the underlying molecular mechanisms. However, a few challenges prevent the identification of specific substrates of PRMT7. First, the substrates of PRMT7 and other PRMTs may overlap, and the interaction between PRMTs is complex, challenging systematic studies on PRMT7 substrates. Second, current studies drew inconsistent conclusions regarding the formation of monomethylarginine or symmetric dimethylarginine mediated by PRMT7, which may be due to contamination by other PRMTs, especially PRMT5. In addition, there is a lack of specific chemical probes and small molecule inhibitors for PRMT7, which has hindered its potential application in disease therapy. Last but not least, clarifying the roles of PRMT7 in male reproduction and the underlying mechanisms, which are the aims of our research group, will further expand our understanding of the biological roles of PRMT7 in human life and disease.
[figure omitted; refer to PDF]Authors’ Contributions
Bingyuan Wang and Mingrui Zhang contributed equally to this work.
Acknowledgments
This work was financially supported by the National Science Foundation of China (31702083), the Special Fund of Chinese Central Government for Basic Scientific Research Operations in Commonweal Research Institutes (2020-YWF-YB-06), the National Transgenic Breeding Project (2016ZX08006001), and the Agricultural Science and Technology Innovation Program (ASTIP-IAS05).
Glossary
Abbreviations
CARM1:Coactivator associated arginine methyltransferase 1
CTCFL:CCCTC-binding factor (zinc finger protein)-like
EEF2:Eukaryotic translation elongation factor 2
EMT:Epithelial-to-mesenchymal transition
ESCs:Embryonic stem cells
FAK:Focal adhesion kinase
GLI2:Glioma-associated oncogene 2
HASP5:Heat shock protein 5
HCN:Hyperpolarization-activated, cyclic-nucleotide-gated channel
hLCSCs:Human liver cancer stem cells
iPSCs:Induced pluripotent stem cells
MLL4:Mixed-lineage leukemia 4
MMP9:Matrix metalloproteinase 9
MuSCs:Muscle stem cells
NSCLC:Non-small-cell lung cancer
PRMT:Protein arginine methyltransferase
PRMT7-CKO:PRMT7 conditional knockout
SBIDDS:Short stature, brachydactyly, intellectual developmental disability, and seizures
SHANK2/3:SH3 and multiple ankyrin repeat domains 2/3.
[1] F. M. Boisvert, U. Déry, J. Y. Masson, S. Richard, "A new role for arginine methylation in DNA repair," Medical Science (Paris), vol. 21 no. 6-7, pp. 579-581, DOI: 10.1051/medsci/2005216-7579, 2005.
[2] M. Tini, H. Naeem, J. Torchia, "Biochemical analysis of arginine methylation in transcription," Methods in Molecular Biology, vol. 523, pp. 235-247, DOI: 10.1007/978-1-59745-190-1_16, 2009.
[3] B. T. Schurter, F. Blanchet, O. Acuto, "Protein arginine methylation: a new frontier in T cell signal transduction," Advances in Experimental Medicine and Biology, vol. 584, pp. 189-206, DOI: 10.1007/0-387-34132-3_14, 2006.
[4] M. T. Bedford, S. G. Clarke, "Protein arginine methylation in mammals: who, what, and why," Molecular Cell, vol. 33 no. 1,DOI: 10.1016/j.molcel.2008.12.013, 2009.
[5] A. Di Lorenzo, M. T. Bedford, "Histone arginine methylation," FEBS Letters, vol. 585 no. 13, pp. 2024-2031, DOI: 10.1016/j.febslet.2010.11.010, 2011.
[6] Y. Morales, T. Cáceres, K. May, J. M. Hevel, "Biochemistry and regulation of the protein arginine methyltransferases (PRMTs)," Archives of Biochemistry and Biophysics, vol. 590, pp. 138-152, DOI: 10.1016/j.abb.2015.11.030, 2016.
[7] K. Jain, S. G. Clarke, "PRMT7 as a unique member of the protein arginine methyltransferase family: a review," Archives of Biochemistry and Biophysics, vol. 665, pp. 36-45, DOI: 10.1016/j.abb.2019.02.014, 2019.
[8] C. I. Zurita-Lopez, T. Sandberg, R. Kelly, S. G. Clarke, "Human protein arginine methyltransferase 7 (PRMT7) is a type III enzyme forming ω - N G -monomethylated arginine residues," The Journal of Biological Chemistry, vol. 287 no. 11, pp. 7859-7870, DOI: 10.1074/jbc.M111.336271, 2012.
[9] Y. Yang, M. T. Bedford, "Protein arginine methyltransferases and cancer," Nature Reviews. Cancer, vol. 13 no. 1, pp. 37-50, DOI: 10.1038/nrc3409, 2013.
[10] Z. Yu, T. Chen, J.́. Hébert, E. Li, S. Richard, "A MousePRMT1Null allele defines an essential role for arginine methylation in genome maintenance and cell proliferation," Molecular and Cellular Biology, vol. 29 no. 11, pp. 2982-2996, DOI: 10.1128/MCB.00042-09, 2009.
[11] R. Swiercz, D. Cheng, D. Kim, M. T. Bedford, "Ribosomal protein rpS2 is hypomethylated in PRMT3-deficient mice," The Journal of Biological Chemistry, vol. 282 no. 23, pp. 16917-16923, DOI: 10.1074/jbc.M609778200, 2007.
[12] D. Hyllus, C. Stein, K. Schnabel, E. Schiltz, A. Imhof, Y. Dou, J. Hsieh, U. M. Bauer, "PRMT6-mediated methylation of R2 in histone H3 antagonizes H3 K4 trimethylation," Genes & Development, vol. 21 no. 24, pp. 3369-3380, DOI: 10.1101/gad.447007, 2007.
[13] E. Guccione, C. Bassi, F. Casadio, F. Martinato, M. Cesaroni, H. Schuchlautz, B. Lüscher, B. Amati, "Methylation of histone H3R2 by PRMT6 and H3K4 by an MLL complex are mutually exclusive," Nature, vol. 449 no. 7164, pp. 933-937, DOI: 10.1038/nature06166, 2007.
[14] D. Cheng, J. Côté, S. Shaaban, M. T. Bedford, "The arginine methyltransferase CARM1 regulates the coupling of transcription and mRNA processing," Molecular Cell, vol. 25 no. 1, pp. 71-83, DOI: 10.1016/j.molcel.2006.11.019, 2007.
[15] T. L. Branscombe, A. Frankel, J. H. Lee, J. R. Cook, Z. Yang, S. Pestka, S. Clarke, "PRMT5 (Janus kinase-binding protein 1) catalyzes the formation of symmetric dimethylarginine residues in proteins ∗," The Journal of Biological Chemistry, vol. 276 no. 35, pp. 32971-32976, DOI: 10.1074/jbc.M105412200, 2001.
[16] Y. Feng, R. Maity, J. P. Whitelegge, A. Hadjikyriacou, Z. Li, C. Zurita-Lopez, Q. al-Hadid, A. T. Clark, M. T. Bedford, J. Y. Masson, S. G. Clarke, "Mammalian protein arginine methyltransferase 7 (PRMT7) specifically targets R X R sites in lysine- and arginine-rich regions ∗," The Journal of Biological Chemistry, vol. 288 no. 52, pp. 37010-37025, DOI: 10.1074/jbc.M113.525345, 2013.
[17] T. B. Miranda, M. Miranda, A. Frankel, S. Clarke, "PRMT7 is a member of the protein arginine methyltransferase family with a distinct substrate specificity ∗," The Journal of Biological Chemistry, vol. 279 no. 22, pp. 22902-22907, DOI: 10.1074/jbc.M312904200, 2004.
[18] P. Jelinic, J. C. Stehle, P. Shaw, "The testis-specific factor CTCFL cooperates with the protein methyltransferase PRMT7 in H19 imprinting control region methylation," PLoS Biology, vol. 4 no. 11, article e355,DOI: 10.1371/journal.pbio.0040355, 2006.
[19] R. K. Bikkavilli, S. Avasarala, M. Vanscoyk, M. Sechler, N. Kelley, C. C. Malbon, R. A. Winn, "Dishevelled3 is a novel arginine methyl transferase substrate," Scientific Reports, vol. 2 no. 1,DOI: 10.1038/srep00805, 2012.
[20] Y. E. Leem, J. H. Bae, H. J. Jeong, J. S. Kang, "PRMT7 deficiency enhances adipogenesis through modulation of C/EBP- β," Biochemical and Biophysical Research Communications, vol. 517 no. 3, pp. 484-490, DOI: 10.1016/j.bbrc.2019.07.096, 2019.
[21] S. J. Morrison, N. M. Shah, D. J. Anderson, "Regulatory mechanisms in stem cell biology," Cell, vol. 88 no. 3, pp. 287-298, DOI: 10.1016/S0092-8674(00)81867-X, 1997.
[22] I. L. Weissman, "Stem cells: units of development, units of regeneration, and units in evolution," Cell, vol. 100 no. 1, pp. 157-168, DOI: 10.1016/S0092-8674(00)81692-X, 2000.
[23] M. Ramalho-Santos, H. Willenbring, "On the origin of the term "stem cell"," Cell Stem Cell, vol. 1 no. 1, pp. 35-38, DOI: 10.1016/j.stem.2007.05.013, 2007.
[24] N. Buhr, C. Carapito, C. Schaeffer, E. Kieffer, A. Van Dorsselaer, S. Viville, "Nuclear proteome analysis of undifferentiated mouse embryonic stem and germ cells," Electrophoresis, vol. 29 no. 11, pp. 2381-2390, DOI: 10.1002/elps.200700738, 2008.
[25] S. H. Lee, T. Y. Chen, S. S. Dhar, B. Gu, K. Chen, Y. Z. Kim, W. Li, M. G. Lee, "A feedback loop comprising PRMT7 and miR-24-2 interplays with Oct4, Nanog, Klf4 and c-Myc to regulate stemness," Nucleic Acids Research, vol. 44 no. 22, pp. 10603-10618, DOI: 10.1093/nar/gkw788, 2016.
[26] Y. Babaie, R. Herwig, B. Greber, T. C. Brink, W. Wruck, D. Groth, H. Lehrach, T. Burdon, J. Adjaye, "Analysis of Oct4-dependent transcriptional networks regulating self-renewal and pluripotency in human embryonic stem cells," Stem Cells, vol. 25 no. 2, pp. 500-510, DOI: 10.1634/stemcells.2006-0426, 2007.
[27] V. Heurtier, N. Owens, I. Gonzalez, F. Mueller, C. Proux, D. Mornico, P. Clerc, A. Dubois, P. Navarro, "The molecular logic of Nanog-induced self-renewal in mouse embryonic stem cells," Nature Communications, vol. 10 no. 1,DOI: 10.1038/s41467-019-09041-z, 2019.
[28] Y. Nakatake, N. Fukui, Y. Iwamatsu, S. Masui, K. Takahashi, R. Yagi, K. Yagi, J. I. Miyazaki, R. Matoba, M. S. H. Ko, H. Niwa, "Klf4 cooperates with Oct3/4 and Sox2 to activate the Lefty1 core promoter in embryonic stem cells," Molecular and Cellular Biology, vol. 26 no. 20, pp. 7772-7782, DOI: 10.1128/MCB.00468-06, 2006.
[29] C. H. Lin, C. Lin, H. Tanaka, M. L. Fero, R. N. Eisenman, "Gene regulation and epigenetic remodeling in murine embryonic stem cells by c-Myc," PLoS One, vol. 4 no. 11, article e7839,DOI: 10.1371/journal.pone.0007839, 2009.
[30] T. Y. Chen, S. H. Lee, S. S. Dhar, M. G. Lee, "Protein arginine methyltransferase 7-mediated microRNA-221 repression maintains Oct4, Nanog, and Sox2 levels in mouse embryonic stem cells," The Journal of Biological Chemistry, vol. 293 no. 11, pp. 3925-3936, DOI: 10.1074/jbc.RA117.000425, 2018.
[31] A. Ogura, K. Inoue, T. Wakayama, "Recent advancements in cloning by somatic cell nuclear transfer," Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences, vol. 368 no. 1609,DOI: 10.1098/rstb.2011.0329, 2013.
[32] C. Gouveia, C. Huyser, D. Egli, M. S. Pepper, "Lessons learned from somatic cell nuclear transfer," International Journal of Molecular Sciences, vol. 21 no. 7,DOI: 10.3390/ijms21072314, 2020.
[33] S. Yamanaka, H. M. Blau, "Nuclear reprogramming to a pluripotent state by three approaches," Nature, vol. 465 no. 7299, pp. 704-712, DOI: 10.1038/nature09229, 2010.
[34] O. L. Serov, N. M. Matveeva, A. A. Khabarova, "Reprogramming mediated by cell fusion technology," International Review of Cell and Molecular Biology, vol. 291, pp. 155-190, DOI: 10.1016/B978-0-12-386035-4.00005-7, 2011.
[35] K. M. Foshay, T. J. Looney, S. Chari, F. F. Mao, J. H. Lee, L. Zhang, C. J. Fernandes, S. W. Baker, K. L. Clift, J. Gaetz, C. G. di, A. P. Xiang, B. T. Lahn, "Embryonic stem cells induce pluripotency in somatic cell fusion through biphasic reprogramming," Molecular Cell, vol. 46 no. 2, pp. 159-170, DOI: 10.1016/j.molcel.2012.02.013, 2012.
[36] M. J. Pfeiffer, M. Siatkowski, Y. Paudel, S. T. Balbach, N. Baeumer, N. Crosetto, H. C. A. Drexler, G. Fuellen, M. Boiani, "Proteomic analysis of mouse oocytes reveals 28 candidate factors of the "reprogrammome"," Journal of Proteome Research, vol. 10 no. 5, pp. 2140-2153, DOI: 10.1021/pr100706k, 2011.
[37] K. Takahashi, S. Yamanaka, "Induction of pluripotent stem cells from mouse embryonic and adult fibroblast cultures by defined factors," Cell, vol. 126 no. 4, pp. 663-676, DOI: 10.1016/j.cell.2006.07.024, 2006.
[38] B. Wang, M. J. Pfeiffer, H. C. Drexler, G. Fuellen, M. Boiani, "Proteomic analysis of mouse oocytes identifies PRMT7 as a reprogramming factor that replaces SOX2 in the induction of pluripotent stem cells," Journal of Proteome Research, vol. 15 no. 8, pp. 2407-2421, DOI: 10.1021/acs.jproteome.5b01083, 2016.
[39] S. Tajbakhsh, "Skeletal muscle stem cells in developmental versus regenerative myogenesis," Journal of Internal Medicine, vol. 266 no. 4, pp. 372-389, DOI: 10.1111/j.1365-2796.2009.02158.x, 2009.
[40] S. I. Fukada, "The roles of muscle stem cells in muscle injury, atrophy and hypertrophy," Journal of Biochemistry, vol. 163 no. 5, pp. 353-358, DOI: 10.1093/jb/mvy019, 2018.
[41] T. L. vanLieshout, J. T. Bonafiglia, B. J. Gurd, V. Ljubicic, "Protein arginine methyltransferase biology in humans during acute and chronic skeletal muscle plasticity," Journal of Applied Physiology, vol. 127 no. 3, pp. 867-880, DOI: 10.1152/japplphysiol.00142.2019, 2019.
[42] T. Zhang, S. Günther, M. Looso, C. Künne, M. Krüger, J. Kim, Y. Zhou, T. Braun, "Prmt5 is a regulator of muscle stem cell expansion in adult mice," Nature Communications, vol. 6 no. 1,DOI: 10.1038/ncomms8140, 2015.
[43] R. S. Blanc, G. Vogel, T. Chen, C. Crist, S. Richard, "PRMT7 preserves satellite cell regenerative capacity," Cell Reports, vol. 14 no. 6, pp. 1528-1539, DOI: 10.1016/j.celrep.2016.01.022, 2016.
[44] P. Seale, L. A. Sabourin, A. Girgis-Gabardo, A. Mansouri, P. Gruss, M. A. Rudnicki, "Pax7 is required for the specification of myogenic satellite cells," Cell, vol. 102 no. 6, pp. 777-786, DOI: 10.1016/S0092-8674(00)00066-0, 2000.
[45] P. S. Zammit, F. Relaix, Y. Nagata, A. P. Ruiz, C. A. Collins, T. A. Partridge, J. R. Beauchamp, "Pax7 and myogenic progression in skeletal muscle satellite cells," Journal of Cell Science, vol. 119 no. 9, pp. 1824-1832, DOI: 10.1242/jcs.02908, 2006.
[46] G. Shao, R. Zhang, S. Zhang, S. Jiang, Y. Liu, W. Zhang, Y. Zhang, J. Li, K. Gong, X. R. Hu, S. W. Jiang, "Splice variants DNMT3B4 and DNMT3B7 overexpression inhibit cell proliferation in 293A cell line," In Vitro Cellular & Developmental Biology. Animal, vol. 49 no. 5, pp. 386-394, DOI: 10.1007/s11626-013-9619-z, 2013.
[47] Q. H. Zheng, L. W. Ma, W. G. Zhu, Z. Y. Zhang, T. J. Tong, "p21Waf1/Cip1 plays a critical role in modulating senescence through changes of DNA methylation," Journal of Cellular Biochemistry, vol. 98 no. 5, pp. 1230-1248, DOI: 10.1002/jcb.20838, 2006.
[48] H. C. Lee, D. Kang, N. Han, Y. Lee, H. J. Hwang, S. B. Lee, J. S. You, B. S. Min, H. J. Park, Y. G. Ko, M. Gorospe, J. S. Lee, "A novel long noncoding RNA Linc-ASEN represses cellular senescence through multileveled reduction of p21 expression," Cell Death and Differentiation, vol. 27 no. 6, pp. 1844-1861, DOI: 10.1038/s41418-019-0467-6, 2020.
[49] M. Thomassen, Q. Tan, T. A. Kruse, "Gene expression meta-analysis identifies chromosomal regions and candidate genes involved in breast cancer metastasis," Breast Cancer Research and Treatment, vol. 113 no. 2, pp. 239-249, DOI: 10.1007/s10549-008-9927-2, 2009.
[50] H. Acloque, M. S. Adams, K. Fishwick, M. Bronner-Fraser, M. A. Nieto, "Epithelial-mesenchymal transitions: the importance of changing cell state in development and disease," The Journal of Clinical Investigation, vol. 119 no. 6, pp. 1438-1449, DOI: 10.1172/JCI38019, 2009.
[51] J. P. Thiery, H. Acloque, R. Y. Huang, M. A. Nieto, "Epithelial-mesenchymal transitions in development and disease," Cell, vol. 139 no. 5, pp. 871-890, DOI: 10.1016/j.cell.2009.11.007, 2009.
[52] R. Yao, H. Jiang, Y. Ma, L. Wang, L. Wang, J. du, P. Hou, Y. Gao, L. Zhao, G. Wang, Y. Zhang, D. X. Liu, B. Huang, J. Lu, "PRMT7 induces epithelial-to-mesenchymal transition and promotes metastasis in breast cancer," Cancer Research, vol. 74 no. 19, pp. 5656-5667, DOI: 10.1158/0008-5472.CAN-14-0800, 2014.
[53] R. M. Baldwin, N. Haghandish, M. Daneshmand, S. Amin, G. Paris, T. J. Falls, J. C. Bell, S. Islam, J. Côté, "Protein arginine methyltransferase 7 promotes breast cancer cell invasion through the induction of MMP9 expression," Oncotarget, vol. 6 no. 5, pp. 3013-3032, DOI: 10.18632/oncotarget.3072, 2015.
[54] P. Geng, Y. Zhang, X. Liu, N. Zhang, Y. Liu, X. Liu, C. Lin, X. Yan, Z. Li, G. Wang, Y. Li, J. Tan, D. X. Liu, B. Huang, J. Lu, "Automethylation of protein arginine methyltransferase 7 and its impact on breast cancer progression," The FASEB Journal, vol. 31 no. 6, pp. 2287-2300, DOI: 10.1096/fj.201601196R, 2017.
[55] Y. Liu, L. Li, X. Liu, Y. Wang, L. Liu, L. Peng, J. Liu, L. Zhang, G. Wang, H. Li, D. X. Liu, B. Huang, J. Lu, Y. Zhang, "Arginine methylation of SHANK2 by PRMT7 promotes human breast cancer metastasis through activating endosomal FAK signalling," Elife, vol. 9,DOI: 10.7554/eLife.57617, 2020.
[56] J. Zhou, Q. Yi, L. Tang, "The roles of nuclear focal adhesion kinase (FAK) on cancer: a focused review," Journal of Experimental & Clinical Cancer Research, vol. 38 no. 1,DOI: 10.1186/s13046-019-1265-1, 2019.
[57] D. Cheng, Z. He, L. Zheng, D. Xie, S. Dong, P. Zhang, "PRMT7 contributes to the metastasis phenotype in human non-small-cell lung cancer cells possibly through the interaction with HSPA5 and EEF2," Oncotargets and Therapy, vol. Volume 11, pp. 4869-4876, DOI: 10.2147/OTT.S166412, 2018.
[58] F. Liu, L. Wan, H. Zou, Z. Pan, W. Zhou, X. Lu, "PRMT7 promotes the growth of renal cell carcinoma through modulating the β -catenin/C-MYC axis," The International Journal of Biochemistry & Cell Biology, vol. 120, article 105686,DOI: 10.1016/j.biocel.2020.105686, 2020.
[59] K. Hua, Y. T. Chen, C. F. Chen, Y. S. Tang, T. T. Huang, Y. C. Lin, T. S. Yeh, K. H. Huang, H. C. Lee, M. T. Hsu, C. W. Chi, C. W. Wu, C. H. Lin, Y. H. Ping, "MicroRNA-23a/27a/24-2 cluster promotes gastric cancer cell proliferation synergistically," Oncology Letters, vol. 16 no. 2, pp. 2319-2325, DOI: 10.3892/ol.2018.8924, 2018.
[60] M. Maghsudlu, E. Farashahi Yazd, T. Amiriani, "Increased expression of miR-27a and miR-24-2 in esophageal squamous cell carcinoma," Cancer, vol. 51 no. 1, pp. 227-233, DOI: 10.1007/s12029-019-00232-x, 2020.
[61] E. C. Martin, S. Elliott, L. V. Rhodes, J. W. Antoon, C. Fewell, Y. Zhu, J. L. Driver, M. Jodari-Karimi, C. W. Taylor, E. K. Flemington, B. S. Beckman, B. M. Collins-Burow, M. E. Burow, "Preferential star strand biogenesis of pre-miR-24-2 targets PKC-alpha and suppresses cell survival in MCF-7 breast cancer cells," Molecular Carcinogenesis, vol. 53 no. 1, pp. 38-48, DOI: 10.1002/mc.21946, 2014.
[62] H. W. He, N. N. Wang, X. M. Yi, C. P. Tang, D. Wang, "Low-level serum miR-24-2 is associated with the progression of colorectal cancer," Cancer Biomarkers, vol. 21 no. 2, pp. 261-267, DOI: 10.3233/CBM-170321, 2018.
[63] K. Nio, T. Yamashita, S. Kaneko, "The evolving concept of liver cancer stem cells," Molecular Cancer, vol. 16 no. 1,DOI: 10.1186/s12943-016-0572-9, 2017.
[64] L. Wang, X. Li, W. Zhang, Y. Yang, Q. Meng, C. Wang, X. Xin, X. Jiang, S. Song, Y. Lu, H. Pu, X. Gui, T. Li, J. Xu, J. Li, S. Jia, D. Lu, "miR24-2 promotes malignant progression of human liver cancer stem cells by enhancing tyrosine kinase Src epigenetically," Molecular Therapy, vol. 28 no. 2, pp. 572-586, DOI: 10.1016/j.ymthe.2019.10.015, 2020.
[65] Z. Ying, M. Mei, P. Zhang, C. Liu, H. He, F. Gao, S. Bao, "Histone arginine methylation by PRMT7 controls germinal center formation via regulating Bcl6 transcription," Journal of Immunology, vol. 195 no. 4, pp. 1538-1547, DOI: 10.4049/jimmunol.1500224, 2015.
[66] the DDD study, N. Akawi, J. McRae, M. Ansari, M. Balasubramanian, M. Blyth, A. F. Brady, S. Clayton, T. Cole, C. Deshpande, T. W. Fitzgerald, N. Foulds, R. Francis, G. Gabriel, S. S. Gerety, J. Goodship, E. Hobson, W. D. Jones, S. Joss, D. King, N. Klena, A. Kumar, M. Lees, C. Lelliott, J. Lord, D. McMullan, M. O'Regan, D. Osio, V. Piombo, E. Prigmore, D. Rajan, E. Rosser, A. Sifrim, A. Smith, G. J. Swaminathan, P. Turnpenny, J. Whitworth, C. F. Wright, H. V. Firth, J. C. Barrett, C. W. Lo, D. R. FitzPatrick, M. E. Hurles, "Discovery of four recessive developmental disorders using probabilistic genotype and phenotype matching among 4,125 families," Nature Genetics, vol. 47 no. 11, pp. 1363-1369, DOI: 10.1038/ng.3410, 2015.
[67] H. J. Jeong, H. J. Lee, T. A. Vuong, K. S. Choi, D. Choi, S. H. Koo, S. C. Cho, H. Cho, J. S. Kang, "Prmt7 deficiency causes reduced skeletal muscle oxidative metabolism and age-related obesity," Diabetes, vol. 65 no. 7, pp. 1868-1882, DOI: 10.2337/db15-1500, 2016.
[68] S. Y. Lee, T. A. Vuong, H. K. So, H. J. Kim, Y. B. Kim, J. S. Kang, I. Kwon, H. Cho, "PRMT7 deficiency causes dysregulation of the HCN channels in the CA1 pyramidal cells and impairment of social behaviors," Experimental & Molecular Medicine, vol. 52 no. 4, pp. 604-614, DOI: 10.1038/s12276-020-0417-x, 2020.
[69] K. D. Kernohan, A. McBride, Y. Xi, N. Martin, J. Schwartzentruber, D. A. Dyment, J. Majewski, S. Blaser, Care4Rare Canada Consortium, K. M. Boycott, D. Chitayat, "Loss of the arginine methyltranserase PRMT7 causes syndromic intellectual disability with microcephaly and brachydactyly," Clinical Genetics, vol. 91 no. 5, pp. 708-716, DOI: 10.1111/cge.12884, 2017.
[70] E. Agolini, M. L. Dentici, E. Bellacchio, V. Alesi, F. C. Radio, A. Torella, F. Musacchia, M. Tartaglia, B. Dallapiccola, V. Nigro, M. C. Digilio, A. Novelli, "Expanding the clinical and molecular spectrum of PRMT7 mutations: 3 additional patients and review," Clinical Genetics, vol. 93 no. 3, pp. 675-681, DOI: 10.1111/cge.13137, 2018.
[71] I. Valenzuela, M. Segura-Puimedon, B. Rodríguez-Santiago, P. Fernández-Alvarez, T. Vendrell, L. Armengol, E. Tizzano, "Further delineation of the phenotype caused by loss of function mutations in PRMT7," European Journal of Medical Genetics, vol. 62 no. 3, pp. 182-185, DOI: 10.1016/j.ejmg.2018.07.007, 2019.
[72] R. Birnbaum, N. Yosha-Orpaz, M. Yanoov-Sharav, D. Kidron, H. Gur, K. Yosovich, T. Lerman-Sagie, G. Malinger, D. Lev, "Prenatal and postnatal presentation of PRMT7 related syndrome: expanding the phenotypic manifestations," American Journal of Medical Genetics. Part A, vol. 179 no. 1, pp. 78-84, DOI: 10.1002/ajmg.a.6, 2019.
[73] H. J. Jeong, S. J. Lee, H. J. Lee, H. B. Kim, T. Anh Vuong, H. Cho, G. U. Bae, J. S. Kang, "Prmt7 promotes myoblast differentiation via methylation of p38MAPK on arginine residue 70," Cell Death and Differentiation, vol. 27 no. 2, pp. 573-586, DOI: 10.1038/s41418-019-0373-y, 2020.
[74] A. Yamane, K. Takahashi, M. Mayo, H. Vo, L. Shum, M. Zeichner-David, H. C. Slavkin, "Induced expression of myoD, myogenin and desmin during myoblast differentiation in embryonic mouse tongue development," Archives of Oral Biology, vol. 43 no. 5, pp. 407-416, DOI: 10.1016/S0003-9969(98)00018-1, 1998.
[75] Y. J. Jang, H. J. Son, Y. M. Choi, J. Ahn, C. H. Jung, T. Y. Ha, "Apigenin enhances skeletal muscle hypertrophy and myoblast differentiation by regulating Prmt7," Oncotarget, vol. 8 no. 45, pp. 78300-78311, DOI: 10.18632/oncotarget.20962, 2017.
[76] J. P. White, C. D. Wrann, R. R. Rao, S. K. Nair, M. P. Jedrychowski, J. S. You, V. Martinez-Redondo, S. P. Gygi, J. L. Ruas, T. A. Hornberger, Z. Wu, D. J. Glass, X. Piao, B. M. Spiegelman, "G protein-coupled receptor 56 regulates mechanical overload-induced muscle hypertrophy," Proceedings of the National Academy of Sciences of the United States of America, vol. 111 no. 44, pp. 15756-15761, DOI: 10.1073/pnas.1417898111, 2014.
[77] S. S. Dhar, S. H. Lee, P. Y. Kan, P. Voigt, L. Ma, X. Shi, D. Reinberg, M. G. Lee, "Trans-tail regulation of MLL4-catalyzed H3K4 methylation by H4R3 symmetric dimethylation is mediated by a tandem PHD of MLL4," Genes & Development, vol. 26 no. 24, pp. 2749-2762, DOI: 10.1101/gad.203356.112, 2012.
[78] P. N. Fiorica, H. E. Wheeler, "Transcriptome association studies of neuropsychiatric traits in African Americans implicatePRMT7in schizophrenia," PeerJ, vol. 7,DOI: 10.7717/peerj.7778, 2019.
[79] M. Zhu, V. K. Idikuda, J. Wang, F. Wei, V. Kumar, N. Shah, C. B. Waite, Q. Liu, L. Zhou, "Shank3-deficient thalamocortical neurons show HCN channelopathy and alterations in intrinsic electrical properties," The Journal of Physiology, vol. 596 no. 7, pp. 1259-1276, DOI: 10.1113/JP275147, 2018.
[80] Y. J. Hu, S. Sif, A. N. Imbalzano, "Prmt7 is dispensable in tissue culture models for adipogenic differentiation," F1000Research, vol. 2,DOI: 10.12688/f1000research.2-279.v1, 2013.
[81] H. N. Yang, J. S. Park, D. G. Woo, S. Y. Jeon, H. J. Do, H. Y. Lim, J. H. Kim, K. H. Park, "C/EBP- α and C/EBP- β -mediated adipogenesis of human mesenchymal stem cells (hMSCs) using PLGA nanoparticles complexed with poly(ethyleneimmine)," Biomaterials, vol. 32 no. 25, pp. 5924-5933, DOI: 10.1016/j.biomaterials.2011.04.072, 2011.
[82] J. C. Weill, S. Weller, C. A. Reynaud, "Human marginal zone B cells," Annual Review of Immunology, vol. 27 no. 1, pp. 267-285, DOI: 10.1146/annurev.immunol.021908.132607, 2009.
[83] G. D. Victora, L. Mesin, "Clonal and cellular dynamics in germinal centers," Current Opinion in Immunology, vol. 28, pp. 90-96, DOI: 10.1016/j.coi.2014.02.010, 2014.
[84] K. Hatzi, A. Melnick, "Breaking bad in the germinal center: how deregulation of BCL6 contributes to lymphomagenesis," Trends in Molecular Medicine, vol. 20 no. 6, pp. 343-352, DOI: 10.1016/j.molmed.2014.03.001, 2014.
[85] K. L. Bunting, A. M. Melnick, "New effector functions and regulatory mechanisms of BCL6 in normal and malignant lymphocytes," Current Opinion in Immunology, vol. 25 no. 3, pp. 339-346, DOI: 10.1016/j.coi.2013.05.003, 2013.
[86] D. I. Loukinov, E. Pugacheva, S. Vatolin, S. D. Pack, H. Moon, I. Chernukhin, P. Mannan, E. Larsson, C. Kanduri, A. A. Vostrov, H. Cui, E. L. Niemitz, J. E. J. Rasko, F. M. Docquier, M. Kistler, J. J. Breen, Z. Zhuang, W. W. Quitschke, R. Renkawitz, E. M. Klenova, A. P. Feinberg, R. Ohlsson, H. C. Morse, V. V. Lobanenkov, "BORIS, a novel male germ-line-specific protein associated with epigenetic reprogramming events, shares the same 11-zinc-finger domain with CTCF, the insulator protein involved in reading imprinting marks in the soma," Proceedings of the National Academy of Sciences of the United States of America, vol. 99 no. 10, pp. 6806-6811, DOI: 10.1073/pnas.092123699, 2002.
[87] M. Chen, Y. Wang, L. Lin, F. Dong, H. Wu, S. Bao, F. Gao, "PRMT7 is involved in regulation of germ cell proliferation during embryonic stage," Biochemical and Biophysical Research Communications, vol. 533 no. 4, pp. 938-944, DOI: 10.1016/j.bbrc.2020.09.099, 2020.
[88] N. Haghandish, R. M. Baldwin, A. Morettin, H. T. Dawit, H. Adhikary, J. Y. Masson, R. Mazroui, L. Trinkle-Mulcahy, J. Côté, "PRMT7 methylates eukaryotic translation initiation factor 2 α and regulates its role in stress granule formation," Molecular Biology of the Cell, vol. 30 no. 6, pp. 778-793, DOI: 10.1091/mbc.E18-05-0330, 2019.
[89] M. M. Szewczyk, Y. Ishikawa, S. Organ, N. Sakai, F. Li, L. Halabelian, S. Ackloo, A. L. Couzens, M. Eram, D. Dilworth, H. Fukushi, R. Harding, C. C. dela Seña, T. Sugo, K. Hayashi, D. McLeod, C. Zepeda, A. Aman, M. Sánchez-Osuna, E. Bonneil, S. Takagi, R. al-Awar, M. Tyers, S. Richard, M. Takizawa, A. C. Gingras, C. H. Arrowsmith, M. Vedadi, P. J. Brown, H. Nara, D. Barsyte-Lovejoy, "Pharmacological inhibition of PRMT7 links arginine monomethylation to the cellular stress response," Nature Communications, vol. 11 no. 1,DOI: 10.1038/s41467-020-16271-z, 2020.
[90] V. L. Vega, W. Charles, A. De Maio, "A new feature of the stress response: increase in endocytosis mediated by Hsp70," Cell Stress & Chaperones, vol. 15 no. 5, pp. 517-527, DOI: 10.1007/s12192-009-0165-2, 2010.
[91] H. Rayess, M. B. Wang, E. S. Srivatsan, "Cellular senescence and tumor suppressor gene p16," International Journal of Cancer, vol. 130 no. 8, pp. 1715-1725, DOI: 10.1002/ijc.27316, 2012.
[92] Y. S. Jung, Y. Qian, X. Chen, "Examination of the expanding pathways for the regulation of p21 expression and activity," Cellular Signalling, vol. 22 no. 7, pp. 1003-1012, DOI: 10.1016/j.cellsig.2010.01.013, 2010.
[93] T. A. Vuong, H. J. Jeong, H. J. Lee, B. G. Kim, Y. E. Leem, H. Cho, J. S. Kang, "PRMT7 methylates and suppresses GLI2 binding to SUFU thereby promoting its activation," Cell Death and Differentiation, vol. 27 no. 1, pp. 15-28, DOI: 10.1038/s41418-019-0334-5, 2020.
[94] Y. Li, H. Zhang, S. C. Choi, Y. Litingtung, C. Chiang, "Sonic hedgehog signaling regulates Gli3 processing, mesenchymal proliferation, and differentiation during mouse lung organogenesis," Developmental Biology, vol. 270 no. 1, pp. 214-231, DOI: 10.1016/j.ydbio.2004.03.009, 2004.
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer
Copyright © 2021 Bingyuan Wang et al. This is an open access article distributed under the Creative Commons Attribution License (the “License”), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License. https://creativecommons.org/licenses/by/4.0/
Abstract
Protein arginine methylation is a posttranslational modification catalyzed by protein arginine methyltransferases (PRMTs), which play critical roles in many biological processes. To date, nine PRMT family members, namely, PRMT1, 2, 3, 4, 5, 6, 7, 8, and 9, have been identified in mammals. Among them, PRMT7 is a type III PRMT that can only catalyze the formation of monomethylarginine and plays pivotal roles in several kinds of stem cells. It has been reported that PRMT7 is closely associated with embryonic stem cells, induced pluripotent stem cells, muscle stem cells, and human cancer stem cells. PRMT7 deficiency or mutation led to severe developmental delay in mice and humans, which is possibly due to its crucial functions in stem cells. Here, we surveyed and summarized the studies on PRMT7 in stem cells and development in mice and humans and herein provide a discussion of the underlying molecular mechanisms. Furthermore, we also discuss the roles of PRMT7 in cancer, adipogenesis, male reproduction, cellular stress, and cellular senescence, as well as the future perspectives of PRMT7-related studies. Overall, PRMT7 mediates the proliferation and differentiation of stem cells. Deficiency or mutation of PRMT7 causes developmental delay, including defects in skeletal muscle, bone, adipose tissues, neuron, and male reproduction. A better understanding of the roles of PRMT7 in stem cells and development as well as the underlying mechanisms will provide information for the development of strategies for in-depth research of PRMT7 and stem cells as well as their applications in life sciences and medicine.
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer
Details
; Zhang, Mingrui 2
; Liu, Zhiguo 1
; Mu, Yulian 1
; Li, Kui 3
1 Institute of Animal Sciences, Chinese Academy of Agricultural Sciences, Beijing 100193, China
2 Institute of Animal Sciences, Chinese Academy of Agricultural Sciences, Beijing 100193, China; College of Animal Science and Technology, China Agricultural University, Beijing 100193, China
3 Institute of Animal Sciences, Chinese Academy of Agricultural Sciences, Beijing 100193, China; Agricultural Genomes Institute at Shenzhen, Chinese Academy of Agricultural Sciences, Shenzhen 518120, China