室旁核注射胰高血糖素样肽-1对不同病程糖尿病大鼠胃排空的影响

目的:研究下丘脑室旁核(paraventricular nucleus,PVN)注射胰高血糖素样肽-1(GLP-1)对糖尿病早期大鼠胃排空的影响,并探讨其相关作用机制.方法:60只清洁级雄性Wistar大鼠随机分为正常对照组(NC组),糖尿病组(DM组),GLP-1干预组(GLP-1组),每组各20只,后两组腹腔注射链脲佐菌素(STZ)制备糖尿病模型,分别于注射STZ2周、6周后每组随机取半数进行实验,实验前于无菌条件下大鼠一侧下丘脑PVN区埋置套管,GLP-1组经套管注入GLP-1,NC组及DM组注入等体积生理盐水.酚红灌胃法检测胃排空率,酶联免疫吸附法(ELISA)测定血浆GLP-1浓度,半定量RT-PCR法测定胃窦、胃底GLP-1RmRNA表达.结果:注射STZ2周后,DM组较NC组胃排空率显著升高(P＜0.01).GLP-1组胃排空率低于DM组(P＜0.01),血浆GLP-1浓度高于DM组及NC组(P均＜0.05),胃窦GLP-1RmRNA表达明显高于DM组、NC组(P均＜0.01).注射STZ 6周后,DM组胃排空率高于NC组(P＜0.01).GLP-1组较DM组胃排空率显著降低(P＜0.01),血浆GLP-1浓度、胃窦GLP-1RmRNA表达显著高于DM组、NC组(P均＜0.01).结论:下丘脑PVN区注射GLP-1后,可减慢糖尿病大鼠初期加速的胃排空,原因可能与血浆GLP-1浓度及胃窦GLP-1RmRNA表达增加有关.     

下丘脑室旁核注射GLP-1 对糖尿病大鼠中枢GLP-1 受体表达

目的:探讨下丘脑室旁核(hypothalamic paraventricular nucleus,PVN)注射GLP-1(胰高血糖素样肽-1)对糖尿病大鼠胃排空的影响及机制。方法:30只Wistar大鼠随机分为正常对照组(NC组)、糖尿病组(DM组)和GLP-1干预组(GLP-1组),每组各10只。DM组和GLP-1组腹腔注射链脲佐菌素,三组大鼠均PVN区埋置套管,恢复7d,GLP-1组微量注射0.5μg/0.5μl的GLP-1,NC组和DM组大鼠PVN区微量注射等体积生理盐水。甲基纤维素-酚红灌胃法检测胃排空;半定量RT-PCR检测大鼠下丘脑GLP-1RmRNA的表达。结果:DM组胃排空率较NC组明显升高(P<0.05),GLP-1组胃排空明显低于DM组(P<0.05),GLP-1组和NC组差异无统计学意义(P>0.05)。GLP-1组下丘脑GLP-1RmRNA的表达明显高于DM组和NC组(P<0.05),并与胃排空率成负相关(P<0.05)。DM组和NC组差异无统计学意义(P>0.05)。结论:PVN区注射GLP-1可以抑制糖尿病大鼠早期胃排空加速,作用机制可能和促进下丘脑GLP-1受体表达有关。     

室旁核注射胰高血糖素样肽-1对不同病程糖尿病大鼠胃排空的影响（英文）

目的：研究下丘脑室旁核（paraventricular nucleus,PVN）注射胰高血糖素样肽-1（GLP-1）对糖尿病早期大鼠胃排空的影响,并探讨其相关作用机制。方法：60只清洁级雄性Wistar大鼠随机分为正常对照组（NC组）,糖尿病组（DM组）,GLP-1干预组（GLP-1组）,每组各20只,后两组腹腔注射链脲佐菌素（STZ）制备糖尿病模型,分别于注射STZ2周、6周后每组随机取半数进行实验,实验前于无菌条件下大鼠一侧下丘脑PVN区埋置套管,GLP-1组经套管注入GLP-1,NC组及DM组注入等体积生理盐水。酚红灌胃法检测胃排空率,酶联免疫吸附法（ELISA）测定血浆GLP-1浓度,半定量RT-PCR法测定胃窦、胃底GLP-1RmRNA表达。结果：注射STZ 2周后,DM组较NC组胃排空率显著升高（P〈0.01）。GLP-1组胃排空率低于DM组（P〈0.01）,血浆GLP-1浓度高于DM组及NC组（P均〈0.05）,胃窦GLP-1RmRNA表达明显高于DM组、NC组（P均〈0.01）。注射STZ 6周后,DM组胃排空率高于NC组（P〈0.01）。GLP-1组较DM组胃排空率显著降低（P〈0.01）,血浆GLP-1浓度、胃窦GLP-1RmRNA表达显著高于DM组、NC组（P均〈0.01）。结论：下丘脑PVN区注射GLP-1后,可减慢糖尿病大鼠初期加速的胃排空,原因可能与血浆GLP-1浓度及胃窦GLP-1RmRNA表达增加有关。     

室旁核注射GLP-1 及拮抗剂对大鼠胃组织nesfatin-1 表达的影响

目的:探讨下丘脑室旁核(pareventricular,PVN)注射胰高血糖素样肽-1(GLP-1)及其受体拮抗剂Exendin(9-39)后胃组织核组蛋白2(NUCB2)/nesfatin-1表达的影响。方法:选取48只雄性Wistar大鼠,随机分为6组,生理盐水组,四种不同剂量GLP-1组(0.003 nmol/10μL,0.03 nmol/10μL,0.3 nmol/10μL,3 nmol/10μL),30 nmol Exendin(9-39)+3 nmol GLP-1(E+G)组,每组8只。PVN区埋置套管并按每组要求分别经套管给予GLP-1及Exendin(9-39)等药物。给药2小时后处死大鼠并取胃组织,实时荧光定量RT-PCR法检测各组胃组织NUCB2 m RNA表达。另外生理盐水组,3 nmo L GLP-1组及E+G组每组分别随机取6只大鼠的部分胃组织,用免疫组织化学法测胃粘膜NUCB2/nesfatin-1蛋白的表达情况。结果:实时荧光定量RT-PCR法发现3 nmo L GLP-1组大鼠胃组织NUCB2 m RNA表达量高于生理盐水组,差异有统计学意义(P0.05),而其余各组大鼠胃组织NUCB2 m RNA表达与生理盐水组比较无统计学差异(P0.05)。免疫组化结果显示3 nmo L GLP-1组胃粘膜NUCB2/nesfatin-1蛋白表达与生理盐水组、E+G组比较有统计学差异(P0.05),生理盐水组大鼠胃粘膜NUCB2/nesfatin-1蛋白表达与E+G组比较无明显差异(P0.05)。结论:PVN注射GLP-1能够促进胃组织NUCB2/nesfatin-1的表达,这一作用可能是通过激活GLP-1受体来完成的。     

中枢nesfatin-1对大鼠夜间摄食和胃排空的影响

目的:观察中枢nesfatin-1对大鼠夜间摄食和胃排空的影响。方法:大鼠经腹腔注射硫酸仲丁巴比妥(100~150 mg/kg)麻醉,侧脑室、第四脑室或小脑延髓池注射nesfatin-1或CRF受体拮抗剂astressin-B或astressin2-B,观察对摄食、胃排空的影响。结果:侧脑室注射nesfatin-1后大鼠第3-6 h夜间进食量(t=3.05~3.58,P0.01)和3 h和6 h的累积进食量(t=5.90~12.1,P0.01)明显减少,nesfatin-1的该抑制效应可被预先侧脑室注射astressin-B或astressin2-B阻断(t=1.06~2.22,P0.05)。第四脑室或小脑延髓池注射nesfatin-1后大鼠夜间摄食量在第1h就明显减少(t=2.59~6.26,P0.05~0.01),持续减少至5-6h(t=1.69~7.42,P0.05~0.01)。侧脑室注射不同剂量nesfatin-1(0.05或0.5μg)20 min后GE率明显降低,且随注射剂量增大,GE率越低(t=3.25~4.67,P0.01)。若预先给予大鼠CRF受体拮抗剂astressin2-B(30μg)再注射nesfatin-1(0.5μg),nesfatin-1抑制大鼠胃排空效应明显减弱(t=2.45~2.85,P0.05)。禁食24 h后再喂食2 h,大鼠下丘脑中nesfatin-1表达明显增加(t=2.87,P0.05),禁食24 h后血浆nesfatin-1水平明显降低(t=1.51,P0.05)。结论:Nesfatin-1抑制摄食作用可能由nesfatin-1和CRF2信号系统共同调节。     

Nesfatin-1对大鼠摄食、胃酸分泌、胃运动及胃排空的影响

目的:观察Nesfatin-1对大鼠摄食、胃酸分泌、胃运动及胃排空的影响并探究其可能机制。方法:将大鼠随机分为摄食实验组、胃酸实验组、胃运动实验组以及胃排空实验组。大鼠经腹内侧核置管后给予nasfatin-1,检测大鼠摄食量,使用Na OH滴定法测定大鼠胃酸分泌,记录清醒大鼠胃运动,以比色法测定大鼠胃排空。结果:低剂量和高剂量nesfatin-1均减少2小时累积食物摄入量;高剂量组4小时累积食物摄入量仍显著低于NS对照组。Nesfatin-1能够抑制2-DG对胃酸分泌的促进作用。SHU9119能够部分阻断nesfatin-1对2-DG的抑制作用。Nesfatin-1能够抑制胃运动及胃排空,SHU9119可部分阻断nesfatin-1对胃运动及胃排空的抑制作用。结论:Nesfatin-1能够调控大鼠摄食、胃酸分泌、胃运动及胃排空,黑皮质素信号通路可能也参与该调控过程。     

Nesfatin-1 对营养性肥胖大鼠摄食量体重和胃排空率的影响

目的：通过颈静脉注射外源性nesfatin-1,观察营养性肥胖大鼠摄食、体重、胃排空率的变化情况。方法：营养性肥胖大鼠造模 成功后,各组大鼠行颈静脉插管手术,术后所有大鼠分为四组,正常对照组及肥胖对照组大鼠注射0.9%生理盐水,正常给药及肥 胖给药组大鼠注射外源性nesfatin-1（100 滋g·kg-1）,连续颈静脉给药7 d,期间记录各组大鼠摄食量以及体重,给药结束后采用灌 胃酚红法测定大鼠胃排空率。结果：用高脂饲料连续饲养大鼠7天,正常对照组和正常nesfatin-1组大鼠的Lee’s指数分别为314.22 和314.44,肥胖对照组和肥胖nesfatin-1 组大鼠的Lee’s指数分别为318.22 和319.03,肥胖差异显著(T-test, P<0.01),造模成功。连 续给药7 d 后,给药组摄食量和体重与对照组相比明显降低,但肥胖给药组摄食量及体重下降较正常给药组更加明显。胃排空率 与胃排出酚红量是成负相关的,实验中正常对照组和正常给药组的胃排空率分别是64.71± 4.51 和46.47± 3.20,而肥胖对照组和 肥胖给药组大鼠的胃排空率分别是75.67± 2.47 和50.88± 3.07,因此高剂量给予nesfatin-1 能显著降低大鼠的胃排空率。结论：综 上所述,长期持续外周静脉给予外源性的nesfatin-1 可以明显抑制正常及肥胖大鼠的摄食,动物体重减轻。     

Nesfatin-1对营养性肥胖大鼠摄食量体重和胃排空率的影响（英文）

目的:通过颈静脉注射外源性nesfatin-1,观察营养性肥胖大鼠摄食、体重、胃排空率的变化情况。方法:营养性肥胖大鼠造模成功后,各组大鼠行颈静脉插管手术,术后所有大鼠分为四组,正常对照组及肥胖对照组大鼠注射0.9%生理盐水,正常给药及肥胖给药组大鼠注射外源性nesfatin-1(100μg·kg-1),连续颈静脉给药7 d,期间记录各组大鼠摄食量以及体重,给药结束后采用灌胃酚红法测定大鼠胃排空率。结果:用高脂饲料连续饲养大鼠7天,正常对照组和正常nesfatin-1组大鼠的Lee’s指数分别为314.22和314.44,肥胖对照组和肥胖nesfatin-1组大鼠的Lee’s指数分别为318.22和319.03,肥胖差异显著(T-test,P0.01),造模成功。连续给药7 d后,给药组摄食量和体重与对照组相比明显降低,但肥胖给药组摄食量及体重下降较正常给药组更加明显。胃排空率与胃排出酚红量是成负相关的,实验中正常对照组和正常给药组的胃排空率分别是64.71±4.51和46.47±3.20,而肥胖对照组和肥胖给药组大鼠的胃排空率分别是75.67±2.47和50.88±3.07,因此高剂量给予nesfatin-1能显著降低大鼠的胃排空率。结论:综上所述,长期持续外周静脉给予外源性的nesfatin-1可以明显抑制正常及肥胖大鼠的摄食,动物体重减轻。     

糖尿病大鼠下丘脑Nesfatin-1对胃运动的影响及机制研究

目的:探讨下丘脑腹内侧核Nesfatin-1对正常大鼠及糖尿病大鼠胃运动的影响及其潜在机制。方法:正常大鼠随机分为0.08μg,0.8μg,8.0μg/0.5μL Nesfatin-1组;30μg/0.5μL astressin-B组;(0.8μg Nesfatin-1+30μg astressin-B)/0.5μL组;0.5μL生理盐水(NS)组;正常羊血清+假刺激(NR+SS)组;正常羊血清+电刺激(NR+ES)组;抗NUCB2/Nesfatin-1抗体+假刺激(anti-Nn-Ab+SS)组;抗NUCB2/Nesfatin-1抗体+电刺激(anti-Nn-Ab+ES)组。制作糖尿病大鼠模型,将糖尿病大鼠随机分为0.08μg/0.5μL Nesfatin-1组;0.8μg/0.5μLNesfatin-1组;8.0μg/0.5μL Nesfatin-1组;0.5μLNS组;NR+SS组;NR+ES组;anti-Nn-Ab+SS组;anti-Nn-Ab+ES组。大鼠胃部置入感应器后腹内侧核置管,记录清醒大鼠胃运动及电刺激海马CA1区后的胃运动。结果:与生理盐水组相比,下丘脑腹内侧核注射不同浓度Nesfatin-1,大鼠胃收缩幅度和频率显著降低,下丘脑腹内侧核注射0.5μL(0.8μg Nesfatin-1+30μg astressin-B)混合液后,相比单独给予0.8μg Nesfatin-1组,大鼠胃收缩幅度和频率显著升高。大鼠下丘脑腹内侧核注射0.5μL Nesfatin-1(0.8μg),大鼠胃收缩幅度和频率显著降低,下丘脑腹内侧核注射0.5μL(0.8μg Nesfatin-1+30μg astressin-B)混合液后,相比单独给予0.8μg Nesfatin-1组,大鼠胃收缩幅度和频率显著升高。下丘脑腹内侧核注射抗NUCB2/Nesfatin-1抗体后再电刺激海马CA1区,与正常羊血清+电刺激组相比,大鼠胃收缩幅度和频率进一步增强,下丘脑腹内侧核注射抗NUCB2/Nesfatin-1抗体后再电刺激海马CA1区,与单独注射抗NUCB2/Nesfatin-1抗体+假电刺激组相比,大鼠的胃收缩幅度和频率显著增高。下丘脑腹内侧核注射抗NUCB2/Nesfatin-1抗体后再给予电刺激海马CA1区,与正常羊血清+电刺激组相比,正常大鼠和糖尿病大鼠胃运动指数均显著增加,下丘脑腹内侧核注射抗NUCB2/Nesfatin-1抗体后再电刺激海马CA1区,与单独注射抗NUCB2/Nesfatin-1抗体+假电刺激组相比,正常和糖尿病大鼠的胃运动指数均显著增高。与正常大鼠相比,电刺激海马CA1区、下丘脑腹内侧核注射抗NUCB2/Nesfatin-1抗体后再给予电刺激海马CA1区,或下丘脑腹内侧核微量注射抗NUCB2/Nesfatin-1抗体,糖尿病大鼠胃运动指数均无显著差异。结论:海马-下丘脑Nesfatin-1信号通路参与胃传入信息和胃运动调控,该作用可能与CRF系统活动有关。     

Orexin受体1对摄食条件反射的调控研究

目的:观察Orexin受体1对摄食条件反射的调控研究。方法:将40只大鼠随机分为四组,分别为NS/NS组,SB/SB组,NS/SB组,SB/NS组,每组10只大鼠,给予大鼠八组"条件刺激-无条件刺激(CS-US)"训练,给予无条件刺激后立即进行条件刺激,每组进行训练前30 min给予SB或生理盐水(NS)。获得性训练后,给予2组反射消失性训练,即给予8次条件刺激。条件刺激是给予大鼠10 s,2kHZ声音刺激,无条件刺激是直接给予大鼠食物。结果:给予条件刺激后,四组大鼠摄食行为均明显增加,摄食间隔均明显缩短,当条件刺激强度增加时,摄食行为也增加,而预先给予SB,与NS/NS组相比,其余组大鼠摄食行为相对减少(P0.05),摄食间隔增加。消失性训练中,与NS/NS,NS/SB组相比,SB/NS组和SB/SB组大鼠摄食行为明显减少(P0.05)。与其他三组大鼠相比,SB/NS组大鼠摄食间隔缩短。预先给予SB使后两次刺激后摄食间隔明显增加(P0.05)。结论:OX1R信号通路调控摄食反射的产生和消失。     

Nesfatin-1 influences the excitability of glucosensing neurons in the hypothalamic nuclei and inhibits the food intake

Nesfatin-1 is a recently discovered neuropeptide that has been shown to decrease food intake after lateral, third, or fourth brain ventricle, cisterna magna administration, or PVN injection in ad libitum fed rats. With regards to the understanding of nesfatin-1 brain sites of action, additional microinjection studies will be necessary to define specific nuclei, in addition to the PVN, responsive to nesfatin-1 to get insight into the differential effects on food intake. In the present study, we evaluated nesfatin-1 action to modulate food intake response upon injection into the specific hypothalamic nuclei (PVN, LHA and VMN) in freely fed rats during the dark phase. We extend previous observations by showing that the nesfatin-1 (50 pmol) injected before the onset of the dark period significantly reduced the 1 to 5 h cumulative food intake in rats cannulated into the PVN, LHA, but not in rats cannulated into the VMN. Glucosensing neurons located in the hypothalamus are involved in glucoprivic feeding and homeostatic control of blood glucose. In order to shed light on the mechanisms by which nesfatin-1 exerts its satiety-promoting actions, we examined the effect of nesfatin-1 on the excitability of hypothalamic glucosensing neurons. Nesfatin-1 excited most of the glucose-inhibited (GI) neurons and inhibited most of the glucose-excited (GE) neurons in the PVN. Of 34 GI neurons in the LHA tested, inhibitory effects were seen in 70.6% (24/34) of GI neurons. The main effects were excitatory after intra-VMN administration of nesfatin-1 in GE neurons (27/35, 77.1%). Thus, our data clearly demonstrate that nesfatin-1 may exert at least a part of its physiological actions on the control of food intake as a direct result of its role in modulating the excitability of glucosensing neurons in the PVN, LHA and VMN.     

第四脑室注射Orexin-A对大鼠饮食摄取条件性位置偏爱的影响

目的:探讨第四脑室注射orexin-A(OXA)对大鼠饮食摄取条件性位置偏爱的影响。方法:将30只大鼠随机分成3组,即对照组,低剂量组和高剂量组,第四脑室分别注射生理盐水(NS)、orexin-A或orexin-A受体拮抗剂SB334867,观察大鼠按压杠杆获取蔗糖的次数和最高频率的变化。再选择30只大鼠,第四脑室注射orexin-A和SB334867,观察大鼠对高脂饮食(HF)食物的摄入量。另选取30只大鼠第四脑室注射orexin-A或SB334867,将大鼠置于条件位置偏爱箱来检测大鼠对HF条件性位置偏爱的变化。结果:与对照组相比,24小时禁食大鼠,第四脑室注射orexin-A,可显著增加大鼠按压杠杆获取蔗糖的次数和最高频率(P0.05)。而SB334867可显著降低大鼠按压杠杆获取蔗糖次数以及最大频率(P0.05)。第四脑室注射orexin-A,可使大鼠HF摄入量显著增加(P0.05),第四脑室注射SB334867,不影响大鼠HF摄入量,但会抑制普通饮食的摄入(P0.05)。第四脑室注射orexin-A能增强对HF饮食位置偏爱性的表达,注射SB334867后会显著抑制大鼠对HF饮食位置偏爱性的表达(P0.05)。结论:第四脑室注射Orexin-A可影响大鼠摄食行为,增加高脂饮食的摄入量,增强对HF饮食位置偏爱性的表达。     

Brain-derived neurotrophic factor in the hypothalamic paraventricular nucleus increases energy expenditure by elevating metabolic rate

Brain-derived neurotrophic factor (BDNF) decreases food intake and body weight, but few central sites of action have been identified. The hypothalamic paraventricular nucleus (PVN) is important in energy metabolism regulation, and expresses both BDNF and its receptor. We tested three hypotheses: 1) PVN BDNF reduces feeding and increases energy expenditure (EE), 2) PVN BDNF-enhanced thermogenesis results from increased spontaneous physical activity (SPA) and resting metabolic rate (RMR), and 3) PVN BDNF thermogenic effects are mediated, in part, by uncoupling protein 1 (UCP1) in brown adipose tissue (BAT). BDNF (0.5 microg) was injected into the PVN of Sprague-Dawley rats; and oxygen consumption, carbon dioxide production, food intake, and SPA were measured for 24 h in an indirect calorimeter. SPA was also measured in open-field activity chambers for 48 h after BDNF injection. Animals were killed 6 or 24 h after BDNF injection, and BAT UCP1 gene expression was measured with quantitative real-time PCR. BDNF significantly decreased food intake and body weight gain 24 h after injection. Heat production and RMR were significantly elevated for 7 h immediately after BDNF injection. BDNF had no effect on SPA, but increased UCP1 gene expression in BAT at 6 h, but not 24 h after injection. In conclusion, PVN BDNF reduces body weight by decreasing food intake and increasing EE consequent to increased RMR, which may be due, in part, to BAT UCP1 activity. These data suggest that the PVN is an important site of BDNF action to influence energy balance.     

Nesfatin-1(30-59) but not the N- and C-terminal fragments, nesfatin-1(1-29) and nesfatin-1(60-82) injected intracerebroventricularly decreases dark phase food intake by increasing inter-meal intervals in mice

Nesfatin-1 is an 82 amino acid N-terminal fragment of nucleobindin2 that was consistently shown to reduce dark phase food intake upon brain injection in rodents. We recently reported that nesfatin-1(1-82) injected intracerebroventricularly (icv) reduces dark phase feeding in mice. Moreover, intraperitoneal injection of mid-fragment nesfatin-1 (nesfatin-1(30-59)) mimics the food intake-reducing effects of nesfatin-1(1-82), whereas N-terminal (nesfatin-1(1-29)) and C-terminal fragments (nesfatin-1(60-82)) did not. We therefore characterized the structure-activity relationship of nesfatin-1 injected icv to influence the dark phase meal pattern in mice. Mouse nesfatin-1(1-29), nesfatin-1(30-59), nesfatin-1(60-82) or vehicle was injected icv in freely fed C57Bl/6 mice immediately before the dark phase and food intake was monitored using an automated episodic feeding monitoring system. Nesfatin-1(30-59) (0.1, 0.3, 0.9 nmol/mouse) induced a dose-related reduction of 4-h food intake by 28%, 49% and 49% respectively resulting in a 23% decreased cumulative 24-h food intake compared to vehicle at the 0.3 nmol/mouse dose (p<0.05). The peak reduction occurred during the 3rd (-96%) and 4th hour (-91%) post injection and was associated with a reduced meal frequency (0-4h: -47%) and prolonged inter-meal intervals (3.1-times) compared to vehicle (p<0.05), whereas meal size was not altered. In contrast, neither nesfatin-1(1-29) nor nesfatin-1(60-82) reduced dark phase food intake at equimolar doses although nesfatin-1(60-82) prolonged inter-meal intervals (1.7-times, p<0.05). Nesfatin-1(30-59) is the active core of nesfatin-1(1-82) to induce satiety indicated by a reduced meal number during the first 4h post injection. The delayed onset may be indicative of time required to modulate other hypothalamic and medullary networks regulating nocturnal feeding as established for nesfatin-1.     

Endogenous GLP-1 acts on paraventricular nucleus to suppress feeding: Projection from nucleus tractus solitarius and activation of corticotropin-releasing hormone,nesfatin-1 and oxytocin neurons

Glucagon-like peptide-1 (GLP-1) receptor agonists have been used to treat type 2 diabetic patients and shown to reduce food intake and body weight. The anorexigenic effects of GLP-1 and GLP-1 receptor agonists are thought to be mediated primarily via the hypothalamic paraventricular nucleus (PVN). GLP-1, an intestinal hormone, is also localized in the nucleus tractus solitarius (NTS) of the brain stem. However, the role of endogenous GLP-1, particularly that in the NTS neurons, in feeding regulation remains to be established. The present study examined whether the NTS GLP-1 neurons project to PVN and whether the endogenous GLP-1 acts on PVN to restrict feeding. Intra-PVN injection of GLP-1 receptor antagonist exendin (9–39) increased food intake. Injection of retrograde tracer into PVN combined with immunohistochemistry for GLP-1 in NTS revealed direct projection of NTS GLP-1 neurons to PVN. Moreover, GLP-1 evoked Ca²⁺ signaling in single neurons isolated from PVN. The majority of GLP-1-responsive neurons were immunoreactive predominantly to corticotropin-releasing hormone (CRH) and nesfatin-1, and less frequently to oxytocin. These results indicate that endogenous GLP-1 targets PVN to restrict feeding behavior, in which the projection from NTS GLP-1 neurons and activation of CRH and nesfatin-1 neurons might be implicated. This study reveals a neuronal basis for the anorexigenic effect of endogenous GLP-1 in the brain.     

Obestatin对血浆ghrelin和nesfatin-1水平及胃排空的影响

目的:探讨侧脑室注射obestatin对大鼠血浆酰基化ghrelin、去酰基化ghrelin、nesfatin-1水平的影响以及对胃排空的调控。方法:侧脑室注射obestatin,采用酶免疫测定(EIA)法检测血浆酰基化ghrelin、去酰基化ghrelin、nesfatin-1水平以及胃排空率的变化。结果:侧脑室分别注射0.1、0.3或1.0 nmol obestatin,大鼠血浆酰基化ghrelin、去酰基化ghrelin以及nesfatin-1水平无显著改变(P0.05),且酰基化ghrelin与去酰基化ghrelin比率无显著改变(P0.05);侧脑室注射obestatin,大鼠摄食量无显著改变,但胃排空率明显增加(P0.05);胃排空率明显延迟(P0.05)。与侧脑室注射1.0 nmol Obestatin组相比,注射1.0 nmol Obestatin+CRF,大鼠摄食量无显著改变,胃排空率明显延迟(P0.05)。各组摄食量及进入十二指肠内食物量无明显差异(P0.05)。结论:中枢obestatin促进大鼠的胃排空,可能与h/r CRF通路有关。     

Gut Peptide GLP-1 and Its Analogue,Exendin-4, Decrease Alcohol Intake and Reward

Glucagon-like-peptide-1 (GLP-1) is a gut- and neuro-peptide with an important role in the regulation of food intake and glucose metabolism. Interestingly, GLP-1 receptors (GLP-1R) are expressed in key mesolimbic reward areas (including the ventral tegmental area, VTA), innervated by hindbrain GLP-1 neurons. Recently GLP-1 has emerged as a potential regulator of food reward behavior, an effect driven by the mesolimbic GLP-1Rs. Its role in other reward behaviors remains largely unexplored. Since a considerable overlap has been suggested for circuitry controlling reward behavior derived from food and alcohol we hypothesized that GLP-1 and GLP-1Rs could regulate alcohol intake and alcohol reward. We sought to determine whether GLP-1 or its clinically safe stable analogue, Exendin-4, reduce alcohol intake and reward. To determine the potential role of the endogenous GLP-1 in alcohol intake we evaluated whether GLP-1R antagonist, Exendin 9-39, can increase alcohol intake. Furthermore, we set out to evaluate whether VTA GLP-1R activation is sufficient to reduce alcohol intake. Male Wistar rats injected peripherally with GLP-1 or Exendin-4 reduced their alcohol intake in an intermittent access two bottle free choice drinking model. Importantly, a contribution of endogenously released GLP-1 is highlighted by our observation that blockade of GLP-1 receptors alone resulted in an increased alcohol intake. Furthermore, GLP-1 injection reduced alcohol reward in the alcohol conditioned place preference test in mice. To evaluate the neuroanatomical substrate linking GLP-1 with alcohol intake/reward, we selectively microinjected GLP-1 or Exendin 4 into the VTA. This direct stimulation of the VTA GLP-1 receptors potently reduced alcohol intake. Our findings implicate GLP-1R signaling as a novel modulator of alcohol intake and reward. We show for the first time that VTA GLP-1R stimulation leads to reduced alcohol intake. Considering that GLP-1 analogues are already approved for clinical use, this places the GLP system as an exciting new potential therapeutic target for alcohol use disorders.