Rodenbaugh David W, Wang Wang, Davis Jennifer, Edwards Terri, Potter James D, Metzger Joseph M
Department of Molecular and Integrative Physiology, University of Michigan, 1301 E. Catherine St., Ann Arbor, MI 48109-0622, USA.
Am J Physiol Heart Circ Physiol. 2007 Sep;293(3):H1705-13. doi: 10.1152/ajpheart.00232.2007. Epub 2007 Jun 1.
The cytosolic Ca(2+)/Mg(2+)-binding protein alpha-parvalbumin (alpha-Parv) has been shown to accelerate cardiac relaxation; however, beyond an optimal concentration range, alpha-Parv can also diminish contractility. Mathematical modeling suggests that increasing Parv's Mg(2+) affinity may lower the effective concentration of Parv ([Parv]) to speed relaxation and, thus, limit Parv-mediated depressed contraction. Naturally occurring alpha/beta-Parv isoforms show divergence in amino acid primary structure (57% homology) and cation-binding affinities, with beta-Parv having an estimated 16% greater Mg(2+) affinity and approximately 200% greater Ca(2+) affinity than alpha-Parv. We tested the hypothesis that, at the same or lower estimated [Parv], mechanical relaxation rate would be more significantly accelerated by beta-Parv than by alpha-Parv. Dahl salt-sensitive (DS) rats were used as an experimental model of diastolic dysfunction. Relaxation properties were significantly slowed in adult cardiac myocytes isolated from DS rats compared with controls: time from peak contraction to 50% relaxation was 57 +/- 2 vs. 49 +/- 2 (SE) ms (P < 0.05), validating this model system. DS cardiac myocytes were subsequently transduced with alpha- or beta-Parv adenoviral vectors. Upon Parv gene transfer, beta-Parv caused significantly faster relaxation than alpha-Parv (P < 0.05), even though estimated [beta-Parv] was approximately 10% of [alpha-Parv]. This comparative analysis showing distinct functional outcomes raises the prospect of utilizing naturally occurring Parv variants to address disease-associated slowed cardiac relaxation.
胞质钙/镁结合蛋白α-小清蛋白(α-Parv)已被证明可加速心脏舒张;然而,超出最佳浓度范围后,α-Parv也会降低收缩性。数学模型表明,提高Parv对镁离子的亲和力可能会降低Parv的有效浓度([Parv]),从而加快舒张速度,并限制Parv介导的收缩抑制。天然存在的α/β-Parv异构体在氨基酸一级结构(57%同源性)和阳离子结合亲和力上存在差异,β-Parv对镁离子的亲和力估计比α-Parv高约16%,对钙离子的亲和力约高200%。我们检验了这样一个假设:在相同或更低的估计[Parv]下,β-Parv比α-Parv更能显著加速机械舒张速率。 Dahl盐敏感(DS)大鼠被用作舒张功能障碍的实验模型。与对照组相比,从DS大鼠分离的成年心肌细胞的舒张特性明显减慢:从收缩峰值到50%舒张的时间为57±2 vs. 49±2(SE)毫秒(P<0.05),验证了该模型系统。随后用α-或β-Parv腺病毒载体转导DS心肌细胞。在进行Parv基因转移后,β-Parv引起的舒张明显比α-Parv快(P<0.05),尽管估计的[β-Parv]约为[α-Parv]的10%。这一显示出不同功能结果的比较分析,为利用天然存在的Parv变体解决与疾病相关的心脏舒张减慢问题带来了希望。
