Dept. of Nephrology, Univ. of Lund, Univ. Hospital of Lund, S-221 85 Lund, Sweden.
Am J Physiol Renal Physiol. 2011 Oct;301(4):F708-12. doi: 10.1152/ajprenal.00183.2011. Epub 2011 Jul 20.
The glomerular filtration barrier (GFB) is commonly conceived as a negatively charged sieve to proteins. Recent studies, however, indicate that glomerular charge effects are small for anionic, carboxymethylated (CM) dextran vs. neutral dextran. Furthermore, two studies assessing the glomerular sieving coefficients (θ) for negative CM-Ficoll vs. native Ficoll have demonstrated an increased glomerular permeability for CM-Ficoll (Asgeirsson D, Venturoli D, Rippe B, Rippe C. Am J Physiol Renal Physiol 291: F1083-F1089, 2006; Guimarães M, Nikolovski J, Pratt L, Greive K, Comper W. Am Physiol Renal Physiol 285: F1118-F1124, 2003.). The CM-Ficoll used, however, showed a larger Stokes-Einstein radius (a(e)) than neutral Ficoll, and it was proposed that the introduction of negative charges in the Ficoll molecule had made it more flexible and permeable. Recently, a negative FITC-labeled CM-Ficoll (CMI-Ficoll) was produced with a conformation identical to that of neutral FITC-Ficoll. Using these probes, we determined their θ:s in anesthetized Wistar rats (259 ± 2.5 g). After blood access had been achieved, the left ureter was cannulated for urine sampling. Either polysaccharide was infused (iv) together with a filtration marker, and urine and plasma were collected. Assessment of θ FITC-Ficoll was achieved by high-performance size-exclusion chromatography (HPSEC). CMI-Ficoll and native Ficoll had identical elugrams on the HPSEC. Diffusion of anionic Ficoll was significantly reduced compared with that of neutral Ficoll across the GFB for molecules of a(e) ∼20-35 Å, while there were no charge effects for Ficoll of a(e) = 35-80 Å. The data are consistent with a charge effect present in "small pores," but not in "large pores," of the GFB and mimicked those obtained for anionic membranes in vitro for the same probes.
肾小球滤过屏障(GFB)通常被认为是一种对蛋白质带负电荷的筛子。然而,最近的研究表明,对于阴离子羧甲基化(CM)葡聚糖与中性葡聚糖相比,肾小球的电荷效应很小。此外,两项评估负电荷 CM-Ficoll 与天然 Ficoll 的肾小球筛系数(θ)的研究表明,CM-Ficoll 的肾小球通透性增加(Asgeirsson D、Venturoli D、Rippe B、Rippe C. Am J Physiol Renal Physiol 291:F1083-F1089,2006;Guimarães M、Nikolovski J、Pratt L、Greive K、Comper W. Am Physiol Renal Physiol 285:F1118-F1124,2003)。然而,所用的 CM-Ficoll 的 Stokes-Einstein 半径(a(e))大于中性 Ficoll,有人提出,Ficoll 分子中引入负电荷使其更具柔韧性和通透性。最近,一种带负电荷的 FITC 标记的 CM-Ficoll(CMI-Ficoll)被制成,其构象与中性 FITC-Ficoll 相同。使用这些探针,我们在麻醉的 Wistar 大鼠(259 ± 2.5 g)中测定了它们的θ:s。在获得血液通路后,通过左输尿管进行尿液取样。将多糖与滤过标志物一起静脉内输注(iv),并收集尿液和血浆。通过高效体积排阻色谱(HPSEC)评估 FITC-Ficoll 的θ。CMI-Ficoll 和天然 Ficoll 在 HPSEC 上具有相同的洗脱图谱。与中性 Ficoll 相比,带负电荷的 Ficoll 的扩散在 GFB 中显著减少,对于 a(e) ∼20-35 Å 的分子,而对于 a(e) = 35-80 Å 的 Ficoll 则没有电荷效应。这些数据与 GFB 的“小孔”中存在电荷效应而“大孔”中不存在电荷效应一致,并且与体外相同探针的阴离子膜获得的结果相似。
