精索静脉曲张对青春期大鼠睾丸中VEGF和Flt-1蛋白表达的影响

目的研究血管内皮生长因子(VEGF)及其受体Flt-1蛋白在实验性左侧精索静脉曲张(ELV)大鼠睾丸中的表达和定位,探讨它们在精索静脉曲张(VC)致男性不育中的作用。方法建立青春期大鼠ELV模型,采用免疫组化法检测VEGF及Flt-1在ELV4周、8周组及相应对照组大鼠睾丸中的表达变化。结果 VEGF和Flt-1蛋白在大鼠睾丸中定位具有细胞特异性。VEGF蛋白表达于生精细胞、精子细胞发育中的顶体、Sertoli和Leydig细胞胞质内;Flt-1表达于精子细胞发育中的顶体及Leydig细胞胞质中。ELV4周组睾丸中VEGF蛋白的表达显著增加(P<0.01),8周时其表达量下降(P<0.01);ELV4周组与8周组睾丸中Flt-1蛋白的表达均比相应对照组下降(P<0.01),ELV8周组比4周组显著减少(P<0.01)。结论 ELV可影响青春期大鼠睾丸中VEGF和Flt-1蛋白的表达量,可能会影响精子的发生、发育,因而该变化可能是VC引起男性不育的原因之一。     

VEGF和Flt-1在精索静脉曲张大鼠附睾中的表达变化

目的研究血管内皮生长因子(VEGF)及其受体Flt-1在实验性左侧精索静脉曲张(ELV)大鼠附睾组织中的表达变化,探讨它们与精索静脉曲张(VC)的关系及致男性不育的病理生理学机制。方法建立青春期雄性SD大鼠ELV模型,采用免疫组化SP法检测ELV及对照组附睾中VEGF和Flt-1的表达。结果 VEGF和Flt-1蛋白在大鼠附睾中均有表达,并具有细胞和区域特异性。ELV4周时双侧附睾中VEGF蛋白的表达明显上调(P<0.01),8周时则显著下降(P<0.01);而Flt-1蛋白在ELV4周左侧显著下降(P<0.01),右侧未见明显差异(P>0.05),8周组均显著下降(P<0.01)。结论 ELV引起大鼠附睾中VEGF和Flt-1表达量发生变化,可能影响精子的成熟,是VC引起男性生育力下降甚至不育的原因之一。     

超氧化物歧化酶和Bcl-2在实验性精索静脉曲张大鼠睾丸中的变化

目的:建立大鼠实验性精索静脉曲张(experimental varicocele EV)的模式,测量睾丸中超氧化物歧化酶(superoxide dismutaseSOD)活性和Bcl-2的表达。方法:将40只雄性青春期Wistar大鼠随机分为EV8周组和12周组(各12只)和相应的假手术对照组2组(各8只),通过部分结扎左肾静脉建立大鼠EV模型,分别于术后8周、12周处死动物,测左侧精索静脉直径,用比色法测SOD 活力,免疫组化法测Bcl-2的表达。结果:成功建立了EV型,与相应的对照组相比左侧精索静脉直径明显增大(P<0.01)。光学显微镜下观察睾丸组织,发现大鼠睾丸生精上皮退变,曲细精管萎缩,间质水肿和精子发育阻滞。EV组双侧睾丸的SOD活性显著低于相应的对照组(P<0.01),左侧睾丸比右侧睾丸更低,但无明显统计学意义(P>0.05)。EV组双侧睾丸间质细胞中Bcl-2的染色指数与相应的对照组相比均显著降低(P<0.01),左侧睾丸染色指数比右侧睾丸下降更明显(P<0.01),EV12周组与 EV8周组相比,EV12周组染色指数更低(P<0.05)。SOD活性与Bcl-2的染色指数在0.01水平有显著相...     

VEGF、VEGFR2在青春期大鼠睾丸、附睾及附睾精子上的表达

目的通过对血管内皮生长因子(VEGF)及其受体VEGFR2在青春期大鼠睾丸及附睾表达的研究,探讨其在雄性生殖器官中的作用。方法采用免疫组化法检测VEGF、VEGFR2在SD大鼠睾丸和附睾的表达定位,用免疫荧光法检测它们在大鼠附睾精子上的表达定位。结果VEGF及VEGFR2在青春期大鼠睾丸和附睾组织中均有表达。在睾丸中,VEGF主要表达于精原细胞胞质、精子细胞发育中的顶体、Sertoli细胞胞质及精子残余体内,Leydig细胞胞质也有阳性表达;VEGFR2主要表达于精子细胞发育中的顶体和间质细胞胞质。在附睾中,VEGF表达于附睾管上皮所有主细胞胞质内;而VEGFR2表达于附睾管头段和尾段上皮主细胞胞质内,体段免疫染色阴性。免疫荧光显示,VEGF与VEGFR2都与精子头部顶体、尾部颈段、中段和主段相结合,末段未见阳性荧光。结论VEGF及VEGFR2在大鼠的睾丸和附睾中均有表达,其表达定位具有细胞特异性和区域特异性,提示其可能在大鼠睾丸精子发生和附睾精子成熟中发挥重要作用。     

血管内皮生长因子及其受体与Cyclin E-CDK2在肝癌发生发展过程中的表达变化

目的通过观察血管内皮生长因子(VEGF)及其受体和细胞周期蛋白E(Cyclin E)在肝癌模型大鼠肝脏中表达情况,探讨VEGF与细胞周期相关蛋白在肝癌发生发展过程中的作用。方法建立诱发性肝癌模型,采用酶联免疫吸附试验检测血清中VEGF量的变化,免疫组化技术检测VEGFR1、Cyclin E和细胞周期蛋白依赖性激酶(CDK2)的表达情况。结果血清中的VEGF含量在对照组中最低,在实验组中逐渐增多,以癌变期含量最高。VEGFR1、Cyclin E和CDK2蛋白表达的平均光密度值均随着肝癌的发生发展有增高的趋势,大鼠血清中的VEGF量与肝脏组织中VEGFR1、Cyclin E和CDK2蛋白表达的平均光密度值随着肝癌的发生发展呈正相关(r=0.834,F=42.1274,P<0.05)。结论 VEGF及其受体VEGFR1在肝癌发生发展中异常表达,促进肝癌的发生发展,可能与Cyclin E、CDK2细胞周期蛋白异常表达有关。     

模拟室内高浓度PM2.5对大鼠血清和组织VEGF蛋白表达的影响

目的:采用"密闭环境熏烟法"模拟PM2.5高浓度环境,建立大鼠被动吸烟模型,观察模拟公共场所室内高浓度PM2.5对正常大鼠血清血管内皮生长因子(VEGF)以及心、脾、肺三种组织VEGF蛋白表达的影响。方法:将20只6月龄雄性健康Wistar大鼠按体重分层随机分为实验组和对照组。并且两组大鼠均于相同的环境下(温度,湿度,光照)进行饲养。对照组不做任何处理,实验组进行为期6周的密闭环境烟熏。末次烟熏结束24-36小时内,用ELISA检测两组大鼠血清VEGF水平的变化,用Western blot检测心、脾、肺三种组织VEGF蛋白表达的变化。结果:与对照组比较,实验组心、脾VEGF1、2以及肺VEGF1蛋白表达水平均显著下降,而肺VEGF2和血清VEGF水平无显著变化。结论:6周模拟公共场所室内高浓度PM2.5能显著降低大鼠心、脾、肺VEGF蛋白表达水平。     

有氧运动对原发性高血压大鼠的降压作用及对骨骼肌VEGF、eNOS表达的影响

目的：了解运动训练对原发性高血压大鼠骨骼肌血管调节因子的影响,探讨运动降压的机制。方法：原发性高血压大鼠随机分为对照组（SHR-C）和训练组（SHR-T）,配对正常血压大鼠对照组（WKY-C）（n=7）。SHR-T进行10周游泳训练,每周训练5 d,每天运动1次,第1周每次运动40 min,第2周50 min,第3周增加到60 min后保持不变,直至训练完毕。SHR-T训练结束24 h后大鼠全部处死并提取比目鱼肌,RT-PCR和免疫印迹法测定血管内皮生长因子（VEGF）等指标。结果：与WKY-C比较,SHR-C骨骼肌VEGF、内皮型一氧化氮合酶（eNOS）蛋白明显低于对照组（P〈0.05）,训练前SHR-C、SHR-T两组血压显著性高于WKY-C（P〈0.01）;训练结束后,与SHR-C比较,SHR-T血压显著性降低（P〈0.05）,心率降低更加显著（P〈0.01）,VEGF mRNA及蛋白、VEGFR2、eNOS均显著性升高（P〈0.05）。结论：氧运动训练能明显降低高血压大鼠血压,促进骨骼肌VEGF mRNA和蛋白水平的表达,同步提高VEGFR2、eNOS蛋白含量,血管生长因子水平增加有利于血管生成并产生降压效应。     

糖尿病大鼠血糖控制前后肾小管上皮细胞VEGF、TGF-β1及Smad蛋白表达的动态研究

目的动态观察链脲佐菌素（STZ）诱导的糖尿病大鼠血糖控制前后肾小管上皮细胞（TEC）中血管内皮生长因子（VEGF）、转化生长因子β1（TGF-β1）、Smad2/3、Smad4的表达情况,探讨四者在糖尿病大鼠TEC表型转变和肾间质纤维化中可能发挥的作用及相互关系。方法实验动物随机分为5组,依病程长短分为①A组（2周组）,②B组（4周组）,③C组（8周组）,④D组（16周组）,⑤E组（24周组）,每组分别设有正常对照组（N组）和糖尿病组（a组）;另外,16周、24周两组加设胰岛素治疗组（b组）。采用尾静脉注射STZ法复制糖尿病大鼠模型;免疫组织化学方法检测肾小管VEGF、TGF-β1、Smad2/3、Smad4及α-平滑肌肌动蛋白（-αSMA）和纤连蛋白（FN）的表达;Western blot检测肾皮质VEGF和TGF-β1蛋白;PAS染色光镜观察肾小管基底膜变化及细胞外基质沉积情况等形态学改变;生化方法测定血糖、血肌酐及24小时尿蛋白量。结果正常对照组VEGF、TGF-β1及Smad2/3、Smad4在肾小管均有少量表达,-αSMA在肾小管无表达;糖尿病组肾小管前述四者的表达均显著高于正常对照组,且从16周开始肾小管上皮细胞可见α-SMA蛋白阳性表达;糖尿病16周时肾小管VEGF、TGF-β1、Smad2/3、Smad4两两之间呈正相关;随糖尿病进展,α-SMA及FN在肾小管表达增多,24h尿蛋白增多,肾脏肥大指数增大,而VEGF、TGF-β1二者都分别和-αSMA、FN、24h尿蛋白及肾脏肥大指数呈正相关性;胰岛素治疗后,VEGF、TGF-β1、Smad2/3、Smad4及FN的表达都比糖尿病组明显下降,且各指标之间的正相关性依然存在,-αSMA蛋白则呈阴性表达。结论糖尿病肾病大鼠肾小管上皮细胞表达的VEGF、TGF-β1及Smad2/3、Smad4参与了TEC表型转变和肾间质纤维化的发生,并且VEGF和TGF-β1相互作用,共同促进了肾脏损害。胰岛素对DN大鼠TEMT和肾间质纤维化的影响可能部分是通过间接阻断VEGF、TGF-β1和Smad2/3、Smad4在TEC中的合成来实现的。     

早期糖尿病大鼠视网膜中血管生成素-1、血管内皮生长因子的表达

目的:研究血管生成素-1(angiopoietin-1,Ang-1)和血管内皮生长因子(vascular endothelial growth factor,VEGF)在早期糖尿病大鼠视网膜中的表达及其意义。方法:制备类似人类Ⅰ型糖尿病大鼠动物模型,取40只SD雄性大鼠分糖尿病组28只及正常对照组12只,糖尿病组28只SD雄性大鼠腹腔注射STZ65mg.Kg-1,建模成功后分别在1周、2周、3周、4周各取糖尿病组7只及正常对照组3只摘取大鼠眼球,应用免疫组化法检测Ang-1、VEGF在视网膜中的表达。结果:Ang-1、VEGF在正常大鼠视网膜的染色均为阴性,Ang-1在1、2、3周糖尿病大鼠视网膜内界膜、内核层及散在血管旁周细胞及Mǔller细胞中呈阳性表达,4周时呈阴性染色反应,Ang-1在糖尿病大鼠视网膜中表达1周阳性率约为39.5%,2周阳性率约为59.7%,3周阳性率约为78.9%,4周阳性率约为19.0%。VEGF在糖尿病大鼠视网膜中表达1周阳性率约为38.6%,2周阳性率约为54.3%,3周阳性率为78.9%,4周阳性率约为42%。结论:Ang-1、VEGF可能在糖尿病视网膜病变早期形成中起到重要...     

缺氧诱导因子-1α与血管内皮生长因子及其受体2在大鼠3期压力性损伤皮肤组织中的表达及意义*

目的:分析缺氧诱导因子-1α(HIF-1α)、血管内皮生长因子(VEGF)和血管内皮生长因子受体2(KDR)在不同受压时间点大鼠压力性损伤局部皮肤组织中的表达及相互关系,探讨3期压力性损伤慢性难愈的可能机制。方法:将40只SD雄性大鼠随机分为正常对照组、受压3 d、5 d、7 d、 9 d组( n=8 ),使用磁铁压迫法建立3期压力性损伤动物模型。HE染色观察皮肤组织形态;免疫组化法检测VEGF表达,Western blot 检测皮肤组织HIF-1α、VEGF、KDR蛋白表达;对数据行单因素方差分析、LSD检验。结果:①HE结果显示,与正常对照组相比,受压组大鼠表皮逐渐增厚,血管数量不断减少,胶原排列紊乱,炎症细胞浸润增加。②免疫组化结果显示:受压3 d组大鼠皮肤组织中VEGF蛋白表达量较正常对照组明显增高(P＜0.01);受压5 d、7 d和 9 d组大鼠皮肤组织中VEGF蛋白表达量均明显低于正常对照组(P＜0.05)。WB结果和免疫组化结果一致。③WB结果显示:受压3 d、5 d和7 d组大鼠皮肤组织中HIF-1α表达量均明显高于正常对照组(P＜0.01 或 P＜0.05);4组受压组大鼠皮肤组织KDR蛋白表达量均低于正常对照组(P＜0.05或P＜0.01)。结论:HIF-1α介导的VEGF和KDR蛋白表达减少引起组织血管生成减少可能是3期压力性损伤慢性难愈的重要原因之一。     

Experimental varicocele does not affect the blood-testis barrier, epididymal electrolyte concentrations, or testicular blood gas concentrations

It has been previously shown that 30-day experimental left varicocele (ELV) in adult rats produces a bilateral increase in testicular blood flow and temperature, as well as a concomitant decrease in epididymal sperm count and motility. In the present study, adult male rats with induced ELV were subjected to a variety of studies to determine the mechanism by which unilateral ELV causes a bilateral testicular response. The results demonstrate that ELV does not alter the blood-testis barrier (BTB) to 3H-inulin (MW 5000), it being largely excluded from entry into the tubule lumen in both control and ELV animals. Neither left nor right cauda epididymidal temperature was altered by ELV. Intraepididymal Na+ and K+ concentrations in the left caput epididymidis were 81.3 +/- 3.8 mEq/l and 26.3 +/- 1.5 mEq/l, respectively. From the cauda epididymidis, these values were 25.0 +/- 2.2 mEq/l and 46.8 +/- 1.0 mEq/l, respectively. These values were similar on the right side and in the left and right epididymis of ELV animals. Left testis arterial pH was 7.3 +/- 0.1, and PO2 and PCO2 were 116.0 +/- 6.4 mm of mercury and 44.3 +/- 3.2 mm of mercury, respectively. Left testicular venous values were 7.3 +/- 0.1 (pH), and 52.6 +/- 2.2 mm of mercury and 49.9 +/- 2.0 mm of mercury. These values were similar for right control testicles and left and right testicles of ELV animals. These results indicate that the mechanism by which unilateral ELV produces a bilateral change in testicular or epididymal function is not by altering the BTB, epididymal temperature or electrolyte concentrations, or testicular blood gas concentrations.     

Inhibition of testicular testosterone biosynthesis following experimental varicocele in rats

In an attempt to determine whether defective testicular testosterone (T) biosynthesis may be associated with a varicocele, an experimental study was performed in adult rats whereby a unilateral left varicocele was surgically created. At 2, 4, 8, and 12 wk following the creation of the varicocele, intratesticular T as well as the activities of three (17 alpha-hydroxylase, 17,20-desmolase, and 17 beta-hydroxysteroid dehydrogenase) of the five enzymes in the delta 4 pathway of testicular T biosynthesis were measured. Intratesticular T (ng/g testis +/- SEM) in the left testis decreased significantly from 121 +/- 21 in the control group to 59 +/- 8 in the two-wk varicocele group (p less than 0.01), and remained significantly suppressed throughout the experimental period. The T concentrations in the right testis paralleled those in the left in both the control and varicocele animals. At 2 wk following the creation of the varicocele, the activity (nmol/min/testis +/- SEM) of the 17,20-desmolase enzyme decreased significantly, from 115 +/- 8 in the left testis of control rats to 87 +/- 6 in the left testis of the varicocele animals (p less than 0.025), and remained low throughout the 12 weeks of the study. The activity of the 17 alpha-hydroxylase enzyme was significantly decreased at the 8th and 12th weeks of the study, while the 17 beta-hydroxysteroid dehydrogenase activity did not show any significant change during the study period. The enzyme activities in the right testis paralleled those in the left testis.(ABSTRACT TRUNCATED AT 250 WORDS)     

VEGF,not VEGFR2, is associated with the angiogenesis effect of mini-TyrRS/mini-TrpRS in human umbilical vein endothelial cells in hypoxia

The purpose of this study was to determine the relationship between VEGF and mini-TyrRS/mini-TrpRS in angiogenesis in hypoxic culture and to begin to comprehend their mechanism in angiogenesis. We designed a VEGF gene silencing assay by using lentivirus vectors, and then western blotting was used to determine the protein expression of VEGF, VEGFR2 and pVEGFR2 in three groups in hypoxic culture at 3, 6, 12, or 24 h: (1) untransfected human umbilical vein endothelial cells (HUVECs) (Control); (2) pGCSIL-GFP lentivirus vector-transduced HUVECs (Mock); and (3) pGCSIL-shVEGF lentivirus vector-transduced HUVECs (Experimental). We also detected the effects of mini-TyrRS/mini-TrpRS peptides on HUVEC proliferation, migration and tube formation after lentivirus vector transfection and VEGFR2 antibody injection. The results indicated that expression of the mini-TyrRS protein was increased, whereas that of mini-TrpRS was specifically decreased in hypoxic culture both in control and mock groups. However, this trend in protein levels of mini-TyrRS and mini-TrpRS was lost in the experimental group after transduction with the pGCSIL-shVEGF lentivirus vector. The protein expression of VEGF was increased in hypoxic culture both in control and mock groups. After transduction with the pGCSIL-shVEGF lentivirus vector, the protein level of VEGF was noticeably decreased in the experimental group; however, for VEGFR2, the results showed no significant difference in VEGFR2 protein expression in any of the groups. For pVEGFR2, we found a distinct trend from that seen with VEGF. The protein expression of pVEGFR2 was sharply increased in hypoxic culture in the three groups. The addition of mini-TyrRS significantly promoted proliferation, migration and tube formation of HUVECs, while mini-TrpRS inhibited these processes in both control and mock groups in hypoxic culture. However, these effects disappeared after transduction with the pGCSIL-shVEGF lentivirus vector in the experimental group, but no significant difference was observed after VEGFR2 antibody injection. The protein expression of VEGF is similar to that of mini-TyrRS in hypoxic culture and plays an important role in the mini-TyrRS/mini-TrpRS-stimulated proliferation, migration and tube formation of HUVECs in hypoxia. These results also suggest that the change in mini-TyrRS and mini-TrpRS expression in hypoxic culture is not related to VEGFR2 and that some other possible mechanisms, are involved in the phosphorylation of VEGFR2.     

Effects of hyperoxia on VEGF,its receptors,and HIF-2alpha in the newborn rat lung

Signaling through the hypoxia inducible factor (HIF)-VEGF-VEGF receptor system (VEGF signaling system) leads to angiogenesis and epithelial cell proliferation and is a key mechanism regulating alveolarization in lungs of newborn rats. Hyperoxia exposure (>95% O2 days 4-14) arrests lung alveolarization and may do so through suppression of the VEGF signaling system. Lung tissue mRNA levels of HIF-2alpha and VEGF increased from days 4-14 in normoxic animals, but hyperoxia suppressed these increases. Levels of HIF-2alpha and VEGF mRNA were correlated in the air but not the O2-treated group, suggesting that the low levels of HIF-2alpha observed at high O2 concentrations are not stimulating VEGF expression. VEGF164 protein levels increased with developmental age, and with hyperoxia to day 9, but continuing hyperoxia decreased levels by day 12. VEGFR1 and VEGFR2 mRNA expression also increased in air-exposed animals, and these, too, were significantly decreased by hyperoxia by day 9 and day 12, respectively. Receptor protein levels did not increase with development; however, O2 did decrease protein to less than air values. Hyperoxic suppression of VEGF signaling from days 9-14 may be one mechanism by which alveolarization is arrested.     

Phosphorylation of Dab2 is involved in inhibited VEGF‐VEGFR‐2 signaling induced by downregulation of syndecan‐1 in glomerular endothelial cell

Disabled‐2 (Dab2) and PAR‐3 (partitioning defective 3) are reported to play critical roles in maintaining retinal microvascular endothelial cells biology by regulating VEGF‐VEGFR‐2 signaling. The role of Dab2 and PAR‐3 in glomerular endothelial cell (GEnC) is unclear. In this study, we found that, no matter whether with vascular endothelial growth factor (VEGF) treatment or not, decreased expression of Dab2 could lead to cell apoptosis by preventing activation of VEGF‐VEGFR‐2 signaling in GEnC, accompanied by reduced membrane VEGFR‐2 expression. And silencing of PAR‐3 gene expression caused increased apoptosis of GEnC by inhibiting activation of VEGF‐VEGFR‐2 signaling and membrane VEGFR‐2 expression. In our previous research, we found that the silencing of syndecan‐1 gene expression inhibited VEGF‐VEGFR‐2 signaling by modulating internalization of VEGFR‐2. And our further research demonstrated that downregulation of syndecan‐1 lead to no significant change in the expression of Dab2 and PAR‐3 both at messenger RNA and protein levels in GEnC, while phosphorylation of Dab2 was significantly increased in GEnC transfected with Dab2 small interfering RNA (siRNA) compared with control siRNA. Atypical protein kinase C (aPKC) could induce phosphorylation of Dab2, thus negatively regulating VEGF‐VEGFR‐2 signaling. And we found that decreased expression of syndecan‐1 lead to activation of aPKC, and aPKC inhibitor treatment could block phosphorylation of Dab2 in GEnC. Besides, aPKC inhibitor treatment could activate VEGF‐VGEFR‐2 signaling in GEnC transfected with syndecan‐1 siRNA in a dose‐dependent manner. In conclusion, we speculated that phosphorylation of Dab2 is involved in preventing activation of VEGF‐VEGFR‐2 signaling in GEnC transfected with syndecan‐1 siRNA. This provides a new target for the therapy of GEnC injury and kidney disease.