收稿日期: 2017-03-11
网络出版日期: 2019-04-26
基金资助
国家自然科学基金(81472393);北京市自然科学基金(7194327)
CMTM2 is involved in spermiogenesis in mice
Received date: 2017-03-11
Online published: 2019-04-26
Supported by
National Natural Foundation of China(81472393);Beijing Municipal Natural Science Foundation(7194327)
目的: 探究人类趋化素样因子超家族2(CKLF-like MARVEL transmembrane domain-containing protein 2, CMTM2)在小鼠精子生成过程中的作用。方法: 构建CMTM2基因敲除小鼠模型,利用Northern、RT-PCR及 Western 印迹检测野生型、杂合子及纯合子小鼠的CMTM2表达水平,统计小鼠生育幼崽数量及生育率,采集并分析精子活动度、形态及睾丸组织切片,检验血清睾酮及促卵泡激素(follicle-stimulating hormone, FSH)水平。结果: CMTM2在小鼠生精中呈现准确的调控式高度表达,基因敲除的成年小鼠和野生型成年小鼠在体重上差异没有统计学意义。纯合子的小鼠睾丸体积及重量小于野生型小鼠睾丸,野生型小鼠与CMTM2敲除小鼠的睾丸长径比较,差异有统计学意义[(11.32±1.21) mm vs. (8.29±1.92) mm, P<0.05],睾丸重量比较,差异有统计学意义[(101.63±2.33) mg vs. (85.22±2.84) mg, P <0.05]。与野生型小鼠相比,杂合子精子数量明显减少,纯合子小鼠精子发生停滞。在精子形态学方面,与野生型小鼠相比,杂合子小鼠有更多圆形精子,而纯合子则因精子发育停滞,多为圆形精子细胞。睾酮和FSH在3组间差异无统计学意义。纯合子雄性小鼠由于精子发生停滞而不育,纯合子小鼠缺失生精上皮层。结论: CMTM2在生精过程中发挥着不可或缺的作用,其参与精子发生的潜在机制有待于进一步实验研究以证实。
关键词: 人类趋化素样因子超家族2; 精子; 基因敲除小鼠模型; 精子生成
张晓威 , 殷华奇 , 李清 , 赵永平 , KiteBrandes , 白文俊 , 徐涛 . 人类趋化素样因子超家族2参与小鼠精子形成[J]. 北京大学学报(医学版), 2019 , 51(2) : 228 -233 . DOI: 10.19723/j.issn.1671-167X.2019.02.005
Objective: To investigate whether CKLF-like MARVEL transmembrane domain-containing protein 2 (CMTM2) is involved in spermatogenesis in mice. CMTM2 is highly expressed in testis, and could possibly be a potential spermagogenesis specific gene.Methods: CMTM2-deficient mouse model was generated. Northern, RT-PCR and Western blotting analysis were performed on total RNA derived from wild-type (WT, CMTM2 +/+) and CMTM2 +/- (heterozygote) and CMTM2 -/-(homozygote) mice to examine the CMTM2 level. The number of litters and the number of pups were counted and pregnancy rates calculated. The motility and morphology of the sperm and the histology of testes were analyzed. Se-rum testosterone and FSH concentrations were also measured. Standard t-tests were used and standard error of means were calculated.Results: CMTM2 was highly expressed in a finely regulated pattern in the mouse testis during spermatogenesis. The body weight of adult mice with CMTM2 deficiency was not significantly different from that of wild type mice. No obvious anatomical or behavioral abnormalities were observed. The testis of CMTM2 -/- was smaller than that of CMTM2 +/+ mice. The testis diameter in wild mice and CMTM2 null mice were (11.32±1.21) mm vs. (8.29±1.92) mm (P<0.05), and the weights were (101.63±2.33) mg vs. (85.22±2.84) mg (P<0.05), respectively. Female CMTM2 null mice were fertile, indicating that CMTM2 was not required for female gametogenesis. The CMTM2 -/- mice produced virtually no sperm, and CMTM2 +/- mice sperm count showed a significant decline. In terms of sperm morphorlogy study, more round spermatids could be observed in the heterozygote group, compared with the wild type group; while in the homozygote group, a large amount of round spermatids could be observed because of complete arrest of spermiogenesis. The hormone levels were not significantly different. The CMTM2 -/- male mice were sterile due to a late, complete arrest of spermiogenesis. The organized architecture of the seminiferous epithelium of the seminiferous tubules seen in CMTM2 +/+ mice was lost in CMTM2 -/- mice. Conclusion: This study suggests CMTM2 is not required for embryonic development in the mouse but is essential for spermiogenesis, however, further studies are required for more detailed mechanism study.
Key words: CMTM2; Sperm; Gene knockout mouse model; Spermiogenesis
| [1] | Zhang Y, Xiao F, Lu S , et al. Research trends and perspectives of male infertility: a bibliometric analysis of 20 years of scientific literature[J]. Andrology, 2016,4(6):990-1001. |
| [2] | Kumar N, Singh AK . Trends of male factor infertility, an important cause of infertility: a review of literature[J]. J Hum Reprod Sci, 2015,8(4):191-196. |
| [3] | Cho C, Willis WD, Goulding EH , et al. Haploinsufficiency of protamine-1 or-2 causes infertility in mice[J]. Nat Genet, 2001,28(1):82-86. |
| [4] | Pan J, Goodheart M, Chuma S , et al. RNF17, a component of the mammalian germ cell nuage, is essential for spermiogenesis[J]. Development, 2005,132(18):4029-4039. |
| [5] | Yan W . Male infertility caused by spermiogenic defects: lessons from gene knockouts[J]. Mol Cell Endocrinol, 2009,306(1/2):24-32. |
| [6] | Liu G, Xin ZC, Chen L , et al. Expression and localization of CKLFSF2 in human spermatogenesis[J]. Asian J Androl, 2007,9(2):189-198. |
| [7] | Han W, Ding P, Xu M , et al. Identification of eight genes encoding chemokine-like factor superfamily members 1-8 (CKLFSF1-8) by in silico cloning and experimental validation[J]. Genomics, 2003,81(6):609-617. |
| [8] | Han W, Lou Y, Tang J , et al. Molecular cloning and characterization of chemokine-like factor 1 (CKLF1), a novel human cytokine with unique structure and potential chemotactic activity[J]. Biochem J, 2001,357(Ptl):127-135. |
| [9] | Shi S, Rui M, Han W , et al. CKLFSF2 is highly expressed in testis and can be secreted into the seminiferous tubules[J]. Int J Biochem Cell Biol, 2005,37(8):1633-1640. |
| [10] | Zhang XD, Yin LL, Zheng Y , et al. Expression of a novel beta adaptin subunit mRNA splice variant in human testes[J]. Asian J Androl, 2005,7(2):179-188. |
| [11] | Noormets K, K?ks S, Kavak A , et al. Male mice with deleted Wolframin (Wfs1) gene have reduced fertility [J]. Reprod Biol Endocrinol, 2009,7:82. |
| [12] | Ramalho-Santos J, Moreno RD . Targeting and fusion proteins during mammalian spermiogenesis[J]. Biol Res, 2001,34(2):147-152. |
| [13] | Sánchez-Pulido L, Martín-Belmonte F, Valencia A , et al. MARVEL: a conserved domain involved in membrane apposition events[J]. Trends Biochem Sci, 2002,27(12):599-601. |
| [14] | Centola GM . Semen assessment[J]. Urol Clin North Am, 2014,41(1):163-167. |
| [15] | Parmegiani L, Cognigni GE, Filicori M . Sperm selection: effect on sperm DNA quality[J]. Adv Exp Med Biol, 2014,791:151-172. |
| [16] | Skakkebaek NE, J?rgensen N, Main KM , et al. Is human fecundity declining[J]. Int J Androl, 2006,29(1):2-11. |
| [17] | Shamsi MB, Kumar K, Dada R . Genetic and epigenetic factors: Role in male infertility[J]. Indian J Urol, 2011,27(1):110-120. |
| [18] | 刘振华, 谢京, 萧云备 , 等. CMTM2改善环磷酰胺致转基因小鼠模型生殖毒性作用并影响StAR蛋白的表达[J]. 中华男科学杂志, 2013,19(3):210-213. |
| [19] | 刘振华, 萧云备, 张晓威 , 等. CMTM2转基因小鼠的构建及其血清睾酮水平的变化[J]. 中华男科学杂志, 2012,18(6):483-486. |
| [20] | Walker WH, Habener JE . Role of transcription factors CREB and CREM in cAMP-regulated transcription during spermatogenesis[J]. Trends Endocrinol Metab, 1996,7(4):133-138. |
| [21] | Sassone-Corsi P . CREM: a master-switch governing male germ cells differentiation and apoptosis[J]. Semin Cell Dev Biol, 1998,9(4):475-482. |
| [22] | Schmidt EE, Schibler U . High accumulation of components of the RNA polymerase II transcription machinery in rodent spermatids[J]. Development, 1995,121(8):2373-2383. |
| [23] | Kotaja N . MicroRNAs and spermatogenesis[J]. Fertil Steril, 2014,101(6):1552-1562. |
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