Lindsey Merry L, Yoshioka Jun, MacGillivray Catherine, Muangman Suphichaya, Gannon Joseph, Verghese Anjali, Aikawa Masanori, Libby Peter, Krane Stephen M, Lee Richard T
Leducq Center for Cardiovascular Research, Cardiovascular Division, Department of Medicine, Brigham and Women's Hospital, Boston, Mass, USA.
Circ Res. 2003 Aug 8;93(3):238-45. doi: 10.1161/01.RES.0000085580.45279.60. Epub 2003 Jul 10.
Matrix metalloproteinase-mediated degradation of type I collagen may play a role in cardiac remodeling after strain or injury. To explore this hypothesis, we used mice homozygous (r/r) for a targeted mutation in Col1a1; these mice synthesize collagen I that resists collagenase cleavage at Gly975-Leu976. A total of 64 r/r and 84 littermate wild-type mice (WT) underwent experimental pressure overload by transverse aortic constriction (TAC) or myocardial infarction (MI). Echocardiographic, hemodynamic, and histological parameters were evaluated up to 12 weeks after TAC or 21 days after MI. At 4 weeks after TAC, collagen levels, wall thickness, and echocardiographic parameters were similar in the 2 groups. At 12 weeks after TAC, r/r mice had smaller LV dimensions (ESD: 2.7+/-0.2 mm WT versus 1.7+/-0.2 mm r/r, P<0.013; EDD: 3.8+/-0.2 mm WT versus 3.1+/-0.1 mm r/r, P<0.013); better fractional shortening (30+/-2% WT versus 46+/-4% r/r; P<0.013); and lower LV/body weight ratios (7.3+/-0.6 WT and 5.1+/-0.5 r/r; P<0.013). Surprisingly, these differences were not accompanied by differences in collagen accumulation, myocyte cross-sectional areas, wall thickness, or microvessel densities. Furthermore, no differences in LV remodeling assessed by echocardiography, fibrosis, or hemodynamic parameters were found between r/r and WT mice after MI. Thus, a mutation that encodes a collagenase cleavage-resistant collagen I does not affect early LV remodeling after TAC or MI, suggesting that collagen cleavage at this site is not the mechanism by which metalloproteinases mediate LV remodeling. Collagen cleavage could, however, have a role in preservation of cardiac function in late remodeling by mechanisms independent of collagen accumulation. We were not able to detect collagen cleavage fragments, and could not, therefore, rule out the possibility of collagen cleavage at additional sites.
基质金属蛋白酶介导的I型胶原降解可能在应变或损伤后的心脏重塑中起作用。为了探究这一假说,我们使用了Col1a1基因靶向突变的纯合子(r/r)小鼠;这些小鼠合成的I型胶原可抵抗胶原酶在Gly975-Leu976处的切割。总共64只r/r小鼠和84只同窝野生型小鼠(WT)通过横向主动脉缩窄(TAC)或心肌梗死(MI)接受了实验性压力超负荷。在TAC后12周或MI后21天评估超声心动图、血流动力学和组织学参数。TAC后4周,两组的胶原水平、壁厚度和超声心动图参数相似。TAC后12周,r/r小鼠的左心室尺寸较小(收缩末期内径:WT为2.7±0.2mm,r/r为1.7±0.2mm,P<0.013;舒张末期内径:WT为3.8±0.2mm,r/r为3.1±0.1mm,P<0.013);缩短分数更好(WT为30±2%,r/r为46±4%;P<0.013);左心室/体重比更低(WT为7.3±0.6,r/r为5.1±0.5;P<0.013)。令人惊讶的是,这些差异并未伴随着胶原积累、心肌细胞横截面积、壁厚度或微血管密度的差异。此外,MI后r/r小鼠和WT小鼠在通过超声心动图、纤维化或血流动力学参数评估的左心室重塑方面没有差异。因此,编码抗胶原酶切割的I型胶原的突变不会影响TAC或MI后的早期左心室重塑,这表明该位点的胶原切割不是金属蛋白酶介导左心室重塑的机制。然而,胶原切割可能通过独立于胶原积累的机制在晚期重塑中对心脏功能的维持起作用。我们无法检测到胶原切割片段,因此不能排除在其他位点进行胶原切割的可能性。
