小鼠乳腺中瘦素及其受体的表达与作用

瘦素(Leptin)是影响乳腺发育和泌乳的自分泌和旁分泌因子. 为探讨瘦素在乳腺发育、泌乳和退化过程中的调控及作用机理, 本研究应用激光共聚焦显微技术对小鼠乳腺发育、泌乳以及退化过程中瘦素及其长型受体(OB-Rb)蛋白水平的表达定位进行检测, 并采用乳腺组织体外培养和Western blot方法研究了妊娠期、泌乳期和退化期瘦素对乳腺的作用以及乳腺发育各个时期瘦素的信号转导通路. 结果显示, 小鼠乳腺整个发育过程中瘦素和OB-Rb的表达呈显著正相关, 在青春期最高, 妊娠期下降, 泌乳期维持在低水平, 幼仔离乳后乳腺退化, 瘦素和OB-Rb的表达显著上调, 并在乳腺退化13天恢复到青春期水平; 瘦素及其受体的表达部位的变化显示瘦素专一性地诱导OB-Rb的表达, 表明瘦素通过与OB-Rb共同作用调控乳腺发育和泌乳的生理机能; 妊娠期, 瘦素与OB-Rb结合, 通过激活JAK-MAPK信号通路促进乳腺导管上皮细胞的增殖和分化; 泌乳期, 瘦素激活JAK-STAT5信号通路诱导乳腺中b-酪蛋白基因表达; 退化期, 瘦素激活JAK-STAT3信号通路启动乳腺细胞凋亡并参与乳腺组织重建过程.     

乳腺重构的过程及其调节因素

受到妊娠周期的影响，乳腺组织在雌性哺乳动物一生中经历着妊娠-哺乳-退化的周期性发育变化. 在乳腺退化到再次泌乳的过程中，乳腺细胞经历凋亡和更新，从而实现乳腺组织的自我更新和修复，即乳腺重构. 重构期间乳腺在组织结构和生理过程中发生显著变化，但该过程物种间差异较大. 乳用家畜为维持泌乳，妊娠期和干奶期重叠，展示出独特的再生性乳腺重构. 再生性乳腺重构对乳畜乳腺健康和下一周期的泌乳具有重要意义，研究此过程将为后续调控乳腺自我更新和改善乳腺健康提供思路. 本综述总结了近年来动物乳腺重构的研究进展，系统归纳了影响乳腺重构的因素，包括激素、蛋白酶、细胞因子、热应激、氧化应激、光照周期等，旨在解析乳腺重构的生理机制，为精准调控该过程提供科学依据.     

Heregulin-α及其受体在小鼠乳腺中的表达与作用

为阐明Heregulin-α（HRG-α）及其受体对乳腺发育、泌乳及退化的调控作用及其机制,本实验采用激光扫描共聚焦显微技术,组织培养,毛细管电泳,Western Blot,ELISA等方法对小鼠乳腺发育、泌乳及退化阶段HRG-α及其受体ErbB2和ErbB3的表达、定位及其对乳腺形态发育、β-酪蛋白表达和分泌、Rab3A蛋白表达、HRG-α信号转导途径信号分子的磷酸化状态的影响进行了系统研究．结果表明,HRG-α及其受体ErbB2,ErbB3在妊娠期15d乳腺中表达到达高峰,退化期9d时又出现另一小高峰;HRG-α及其受体ErbB2,ErbB3主要在乳腺脂肪细胞、导管上皮细胞以及围绕导管的基膜中检测到,在青春期、妊娠期和退化期呈特异性表达;ErbB2和ErbB3的表达变化趋势与HRG-α的表达变化趋势相似,呈显著线性正相关．妊娠期,HRG-α能够促进STAT5,p42／p44,p38和PKC的磷酸化以及Rab3A蛋白表达,刺激乳腺上皮细胞的增殖和分化,增加并维持β-酪蛋白的表达和分泌;泌乳期,HRG-α能够促进STAT5,p38的磷酸化并抑制PKC磷酸化和Rab3A蛋白表达,维持泌乳期乳腺形态,促进乳蛋白的分泌而使乳腺上皮细胞内β-酪蛋白的表达量相对减少;退化期,HRG-α能够促进STAT3磷酸化和Rab3A蛋白表达并抑制PKC的磷酸化,启动乳腺上皮细胞退化,抑制β-酪蛋白的分泌导致乳腺上皮细胞内β-酪蛋白表达量相对增加。     

乳腺发育激素对小鼠乳腺中FGF7，FGF10及其受体表达的影响

为阐明雌激素、孕酮以及催乳素3种乳腺发育激素对乳腺发育的调节机制,本研究以昆明鼠为实验材料,通过体外实验,系统地研究了乳腺发育激素对不同时期乳腺中FGF7,FGF10及KGFR表达的影响．结果表明,17β-雌二醇能引起小鼠乳腺中FGF7表达上调;孕酮对小鼠乳腺中的FGF7表达没有影响;在小鼠乳腺发育的妊娠期与泌乳期,催乳素能弓I起FGF7表达显著上调．17β-雌二醇能引起小鼠乳腺中的FGF10表达上调;在青春期小鼠乳腺发育,孕酮和催乳素能显著降低FGF10的表达;在妊娠期小鼠乳腺发育,催乳素能显著增加FGF10的表达．当17β-雌二醇在体内所占比例较高时,会降低KGFR的表达;而17β-雌二醇在体内所占比例较低时,反而会增加KGFR的表达．低浓度孕酮使KGFR的表达增加,高浓度孕酮对于KGFR的表达没有影响．在妊娠期以及泌乳期,对于小鼠乳腺发育,催乳素能显著升高KGFR的表达．     

microRNA在小鼠乳腺不同发育时期差异表达谱及作用

microRNA是一类大小约22个核苷酸的非编码RNA分子,是一种广泛存在的对基因表达进行微调的分子。microRNA可以通过与靶基因mRNA的特定位点结合,抑制该蛋白的合成或诱导该mRNA的降解,从而参与基因的表达调控。一般来源于染色体的非编码区域,由大约70个核苷酸大小的可形成发夹结构的前体经Dicer酶加工而来。这类小RNA在表达上具有组织和时间的特异性,是调节其他功能基因表达的重要调控分子,在生物的生长发育过程中发挥着重要作用。因此,虽然microRNA的研究仅有很短的历史,但已成为基因表达调控研究的热点领域。以中国昆明小鼠不同发育时期的乳腺组织为实验材料,应用芯片技术及荧光定量PCR技术,分析发育不同时期的乳腺组织microRNA差异表达图谱。本文研究发现microRNA在乳腺不同的发育时期表达图谱不同;与青春期、退化期比较,妊娠期、哺乳期有十余种microRNAs表达上调,20余种microRNAs表达下调;microRNAs在乳腺发育和泌乳周期中发挥重要的作用。     

p53蛋白在周期调节蛋白A1变异引起的雄性小鼠生殖细胞凋亡中的作用

为研究p5 3蛋白在周期调节蛋白A1(cyclinA1)变异引起的雄性小鼠生殖细胞凋亡中的作用 ,以p5 3基因敲除的小鼠和周期调节蛋白A1基因敲除的小鼠杂交 ,获取同胎生单基因变异和双基因同时变异的雄性后代共 4组 12只 .比较它们的性腺和生殖细胞发育 ,并用TUNEL染色法观察和比较生殖细胞的凋亡情况 .在睾丸最大横切面上观察到 :周期调节蛋白A1变异组凋亡细胞最多 (348± 10 4个 ) ,明显高于p5 3 周期调节蛋白A1双基因变异组 (12 1± 38个 ) ,t=3 2 5 79,P =0 0 4 72 .p5 3变异组凋亡细胞最少 (45± 2 4个 ) ,配对t检验显示有非常显著性差异 ,t=8 4 0 13,P =0 0 0 35 .这一研究结果提示 ,p5 3基因可能在雄性生殖细胞的发育中起监视作用 ,并在周期调节蛋白A1变异引起发育异常时启动p5 3途径造成异常细胞的凋亡 .     

小鼠早期胚胎发育过程中细胞凋亡及凋亡基因表达的检测

小鼠早期胚胎发育过程中凋亡现象大量存在,细胞凋亡与凋亡基因表达有关。应用彗星电泳法检测小鼠早期胚胎凋亡情况;应用巢式RT-PCR、免疫组化的方法检测了Bcl-2家族成员(Bax、Bcl-2、Bak、Bcl-xl)的表达变化情况。结果显示:随着胚胎细胞数目的增加,凋亡比率逐渐增大;Bax表达量在整个过程中基本不变,Bcl-2表达量逐渐上调,Bak、Bcl-xl的表达量逐渐降低。对小鼠早期胚胎发育过程中的基因表达研究对于揭示早期胚胎发育的机制有重大的意义。     

小鼠体外受精、胚胎培养及胚胎快速冷冻的研究

目的　为扩大胚胎来源并获取特定胚龄胚胎 ,建立小鼠冷冻胚胎库。方法　运用超数排卵、体外受精与胚胎培养及胚胎冷冻技术系统研究了小鼠受精卵的体内发育与运行规律。卵母细胞的体外成熟与受精、单细胞胚胎培养及胚胎快速冷冻。结果　 (1)注射hCG后 12～ 2 0h受精卵发育至原核期 ,4 2～ 4 8h为 2 细胞期 ,4 8～ 6 0h为 4 细胞期 ,6 0～ 6 8h为 8 细胞期 ,以上各期受精卵均处于输卵管中 ;75～ 78h为桑椹胚 ,78～ 80h为致密桑椹胚 ,90～ 92h为早期囊胚 ,92～ 96h为囊胚 ,以上各期均处于子宫角中。 (2 )培养液中添加促性腺激素 (FSH与hCG) ,能显著提高卵母细胞的体外受精率 ,添加FCS和激素组的体外受精率又显著高于单独添加激素组 ,FCS还能显著提高胚胎发育。 (3)在培养液中添加EDTA ,能有效克服小鼠胚胎的 2 细胞阻断 ,其 2 细胞胚的发育率达 10 0 % ,8 细胞胚发育率达 5 5 %以上 ;牛、羊上皮细胞培养液上清也能有效克服 2 细胞阻断。添加乳酸钠和丙酮酸钠可使 2细胞与 8细胞期胚的发育率显著提高。 (4)以D PBS +甘油 +蔗糖为冷冻液 ,以D PBS +蔗糖为稀释液 ,对小鼠胚胎进行快速冷冻 ,桑椹胚的存活率为 6 9 3% ,早期囊胚的存活率为 6 0 4 %。结论　研究为将生物技术应用于小鼠 ,扩大卵子和胚胎来源     

家蚕蛹变态期丝腺组织的退化与细胞凋亡特征

利用形态学观察方法、分子生物学检测方法以及20-羟基蜕皮酮(20-hydroxyecdysone)和放线菌酮(cycloheximide)体外培养方法, 研究了家蚕Bombyx mori 蛹变态期丝腺组织的退化与细胞凋亡特征。显微镜的观察显示家蚕丝腺的逐渐退化发生在吐丝期间。DNA梯度电泳的分析表明程序性细胞死亡(programmed cell death)可能伴随发生在丝腺的退化过程中。在离体培养条件下, 用20-羟基蜕皮酮处理5龄第6天幼虫的丝腺, 导致的细胞凋亡提前于对照, 提示在进入蛹变态期前, 20-羟基蜕皮酮提早激发了介导家蚕丝腺细胞凋亡与水解机制的遗传调控级联系统。上述结果表明, 20-羟基蜕皮酮能够诱导家蚕丝腺组织在蛹变态期发生程序性细胞死亡。     

小鼠囊胚的细胞凋亡:体内发育和体外培养的比较

小鼠胚体外培养到囊胚期的成功率很高,但质量是否能及体内发育的囊胚还不太清楚。细胞的数量和凋亡程度是胚胎质量鉴定的重要指标。本文采用TUNEL法分别对2-、8-细胞和桑椹胚培育成的鼠囊胚及体内发育而成的鼠囊胚细胞凋亡情况进行了检验。结果表明90%以上的2-、8-细胞及桑椹胚经过72h、48h和24h的培养发育到囊胚期。由桑椹胚发育成的与体内发育成的囊胚细胞凋亡指数没有显著差异,但由2-、8-细胞胚培育成的囊胚细胞凋亡指数显著高于体内发育成的囊胚。由此可见,体外长时间培养会增加胚胎的细胞凋亡程率。为培养出高质量的囊胚,胚胎培养条件还需进一步改善。     

Expression and function of leptin and its receptor in mouse mammary gland

Leptin is an autocrine and paracrine factor which affects the development of duct, formation of gland alveolus, expression of milk protein gene and onset involution of mammary gland. In order to know the function and mechanism of leptin in mammary gland, the protein expression and localization of leptin and its long form receptor (OB-Rb) were detected by a confocal laser scanning microscope. To study the impacts of leptin on mammary gland and leptin signal transduction pathway in pregnancy-, lactation-and involution-stage mammary gland, explants were cultured and Western blotting was used. The results showed that in the whole development cycle of mammary gland, the expression of leptin and OB-Rb was in positive correlation. In virgin the leptin expression was the highest and then decreased in pregnancy. In lactation the expression of leptin was low and upgraded in involution, and recovered to the original level about virgin on involution 13 d. The localization of leptin and OB-Rb revealed that leptin induced the expression of OB-Rb specifically and controlled the development and physiological function of the mammary gland by binding to OB-Rb. In pregnancy stage, leptin stimulated proliferation and differentiation of ductal epithelial cells by JAK-MAPK signal pathway. In lactation, leptin induced gene expression of β-casein by JAK-STAT5 signal pathway, and in involution leptin induced mammary epithelial cell apoptosis and mammary gland restitution by JAK-STAT3 signal pathway.     

Expression and function of leptin and its receptor in mouse mammary gland

Leptin is an autocrine and paracrine factor which affects the development of duct, formation of gland alveolus, expression of milk protein gene and onset involution of mammary gland. In order to know the function and mechanism of leptin in mammary gland, the protein expression and localization of leptin and its long form receptor (OB-Rb) were detected by a confocal laser scanning microscope. To study the impacts of leptin on mammary gland and leptin signal transduction pathway in pregnancy-, lacta-tion-and involution-stage mammary gland, explants were cultured and Western blotting was used. The results showed that in the whole development cycle of mammary gland, the expression of leptin and OB-Rb was in positive correlation. In virgin the leptin expression was the highest and then decreased in pregnancy. In lactation the expression of leptin was low and upgraded in involution, and recovered to the original level about virgin on involution 13 d. The localization of leptin and OB-Rb revealed that leptin induced the expression of OB-Rb specifically and controlled the development and physiological function of the mammary gland by binding to OB-Rb. In pregnancy stage, leptin stimulated proliferation and differentiation of ductal epithelial cells by JAK-MAPK signal pathway. In lactation, leptin induced gene expression of β-casein by JAK-STAT5 signal pathway, and in involution leptin induced mammary epithelial cell apoptosis and mammary gland restitution by JAK-STAT3 signal pathway.     

Induction of mammary gland differentiation in transgenic mice by the fatty acid-binding protein MRG

A mammary-derived growth inhibitor-related gene (MRG) was previously identified and characterized. MRG induces differentiation of mammary epithelial cells in vitro and its expression is associated with mammary differentiation. To further define the role of MRG on mammary gland differentiation, a MRG transgenic mice model under the control of mouse mammary tumor virus promoter was established and the effect of MRG on mammary gland differentiation was investigated at histological and molecular levels. Expression of endogenous mouse MRG gene was significantly increased from the non-differentiated gland of control virgin mice to the functionally differentiated gland of pregnant control mice. Whole mount analyses demonstrated that ductal development was not affected by MRG transgene expression. While there was no lobuloalveolar structure in control virgin mice, expression of MRG transgene in the mammary gland resulted in the development of lobuloalveolar-like structure, which mimics the gland from early pregnancy. Consistent with the morphological change, expression of MRG also increased milk protein beta-casein expression in the gland. To study the mechanism of MRG-induced mammary differentiation, we investigated the Stat5 activation in the glands from the transgenic mouse versus virgin control mouse. While activated Stat5 was expressed at the minimal level in the non-differentiated control virgin gland, a significant Stat5 phosphorylation was observed in the virgin transgenic gland. Our data indicate that MRG is a mediator of the differentiating effects of pregnancy on breast epithelium, and overexpression of MRG in young nulliparous mice can induce differentiation.     

Lactation-dependent down regulation of leptin production in mouse mammary gland

Lactation-dependent regulation of leptin expression in mouse mammary gland and parametrial adipose tissue was estimated by RT-PCR analysis for virgin, pregnant, lactating and post-lactating mice, and the serum and milk leptin levels of these mice were also determined by ELISA. Leptin gene expression in mammary gland as well as in adipose tissue was obviously detected before pregnancy, markedly decreased to 30-50% after parturition and kept at the low level during lactation period, and restored to the original level after weaning. The leptin concentration of milk collected just before weaning was about two-fold higher than that of the milk collected at mid-lactating stages. The serum leptin levels of the mid- and late-lactating mice were not significantly higher than those of non-pregnant mice. These results suggested that the lactation-induced down regulation of leptin was associated with autocrine/paracrine action of leptin in mammary and adipose tissues, and that the milk leptin, especially at the latter stages of lactation, was not only ascribed to diffusive transport from maternal blood stream, but also regional production and secretion by mammary epithelial cells. This possible production of leptin by mammary epithelial cells was further supported by the fact that leptin was expressed by cultured cells of mammary epithelial cell line, COMMA-1D, in a manner negatively dependent on the lactogenic hormones.     

Coordinated expression of extracellular matrix-degrading proteinases and their inhibitors regulates mammary epithelial function during involution

Extracellular matrix (ECM) plays an important role in the maintenance of mammary epithelial differentiation in culture. We asked whether changes in mouse mammary specific function in vivo correlate with changes in the ECM. We showed, using expression of beta-casein as a marker, that the temporal expression of ECM-degrading proteinases and their inhibitors during lactation and involution are inversely related to functional differentiation. After a lactation period of 9 d, mammary epithelial cells maintained beta-casein expression up to 5 d of involution. Two metalloproteinases, 72-kD gelatinase (and its 62-kD active form), and stromelysin, and a serine proteinase tissue plasminogen activator were detected by day four of involution, and maintained expression until at least day 10. The expression of their inhibitors, the tissue inhibitor of metalloproteinases (TIMP) and plasminogen activator inhibitor-1, preceded the onset of ECM-degrading proteinase expression and was detected by day two of involution, and showed a sharp peak of expression centered on days 4-6 of involution. When involution was accelerated by decreasing lactation to 2 d, there was an accelerated loss of beta-casein expression evident by day four and a shift in expression of ECM-remodeling proteinases and inhibitors to a focus at 2-4 d of involution. To further extend the correlation between mammary-specific function and ECM remodeling we initiated involution by sealing just one gland in an otherwise hormonally sufficient lactating animal. Alveoli in the sealed gland contained casein for at least 7 d after sealing, and closely resembled those in a lactating gland. The relative expression of TIMP in the sealed gland increased, whereas the expression of stromelysin was much lower than that of a hormone-depleted involuting gland, indicating that the higher the ratio of TIMP to ECM-degrading proteinases the slower the process of involution. To test directly the functional role of ECM-degrading proteinases in the loss of tissue-specific function we artificially perturbed the ECM-degrading proteinase-inhibitor ratio in a normally involuting gland by maintaining high concentrations of TIMP protein with the use of surgically implanted slow-release pellets. In a concentration-dependent fashion, involuting mammary glands that received TIMP implants maintained high levels of casein and delayed alveolar regression. These data suggest that the balance of ECM-degrading proteinases and their inhibitors regulates the organization of the basement membrane and the tissue-specific function of the mammary gland.(ABSTRACT TRUNCATED AT 400 WORDS)     

Smad3 in the mammary epithelium has a nonredundant role in the induction of apoptosis, but not in the regulation of proliferation or differentiation by transforming growth factor-beta.

Transforming growth factor-beta (TGF-beta) regulates proliferation, morphogenesis, and functional differentiation in the mammary gland and plays complex roles in mammary tumorigenesis. Here we show that the signaling mediators Smad1-Smad5 are expressed at all stages of mammary gland development. To begin to investigate which Smads mediate which TGF-beta responses, we have analyzed mammary gland development in Smad3 null mice. Smad3 null virgin females showed delayed mammary gland development. However, this phenotype was secondary to ovarian insufficiency because Smad3 null mammary epithelium developed normally in hormonally supplemented Smad3 null mice or when transplanted into wild-type hosts. Absence of Smad3 had no effect on the ability of TGF-beta to inhibit the growth of mammary epithelial cells in culture, and no compensatory changes in expression or activation of Smad2 were seen in the Smad3 null epithelium. A small but significant decrease in apoptotic cells was seen in involuting glands from Smad3 null transplants. The results suggest that epithelial Smad3 is dispensable for TGF-beta effects on proliferation and differentiation in the mammary gland, but that it contributes in a nonredundant manner to the induction of apoptosis.     

Leptin mRNA expression in the rat mammary gland at different activation stages

Leptin is expressed in various tissues, suggesting that this protein is effective not only at the central nervous system level, but also peripherically. Recent studies have shown leptin production by other tissues, including the placenta, stomach, and mammary tissues, but there is no information available concerning expression levels of leptin in the rat mammary gland at different activation stages. We used semi-quantitative RT-PCR to investigate leptin mRNA expression levels in the rat mammary gland at different activity stages. Rat mammary gland samples were collected from virgin females and on days 6, 12, 18 of pregnancy and of lactation (six rats per group). The expression levels of leptin mRNA were measured by semi-quantitative RT-PCR, with β-actin as an internal control. Leptin mRNA was highly expressed in virgin rat mammary glands (leptin(IOD)/β-actin(IOD) = 1.60). It decreased gradually during pregnancy, being lowest at 18 days of pregnancy, when the levels were significantly lower than in virgin mammary tissue. Leptin mRNA increased slightly during lactation, but the difference was not significant. By day 18 of lactation, expression levels of leptin mRNA reached the same values as in virgin mammary tissue (leptin(IOD)/β-actin(IOD) = 1.65). Based on these results, we suggest that leptin has an important regulation role in rat mammary gland activation.     

The estrogen-responsive Agr2 gene regulates mammary epithelial proliferation and facilitates lobuloalveolar development

Agr2 is a putative protein disulfide isomerase (PDI) initially identified as an estrogen-responsive gene in breast cancer cell lines. While Agr2 expression in breast cancer is positively correlated with estrogen receptor (ER) expression, it is upregulated in both hormone dependent and independent carcinomas. Several in vitro and xenograft studies have implicated Agr2 in different oncogenic features of breast cancer; however, the physiological role of Agr2 in normal mammary gland development remains to be defined. Agr2 expression is developmentally regulated in the mammary gland, with maximum expression during late pregnancy and lactation. Using a mammary gland specific knockout mouse model, we show that Agr2 facilitates normal lobuloalveolar development by regulating mammary epithelial cell proliferation; we found no effects on apoptosis in Agr2(-/-) mammary epithelial cells. Consequently, mammary glands of Agr2(-/-) females exhibit reduced expression of milk proteins, and by two weeks post-partum their pups are smaller in size. Utilizing a conditional mouse model, we show that Agr2 constitutive expression drives precocious lobuloalveolar development and increased milk protein expression in the virgin mammary gland. In vitro studies using knock down and overexpression strategies in estrogen receptor positive and negative mammary epithelial cell lines demonstrate a role for Agr2 in estradiol-induced cell proliferation. In conclusion, the estrogen-responsive Agr2, a candidate breast cancer oncogene, regulates epithelial cell proliferation and lobuloalveolar development in the mammary gland. The pro-proliferative effects of Agr2 may explain its actions in early tumorigenesis.