Department of Biological Sciences, Youngstown State University, 4013 Ward Beecher Science Hall, Youngstown, OH, 44555, USA.
The Sloth Sanctuary of Costa Rica, Penshurst, Limon, Costa Rica.
J Comp Physiol B. 2021 Jan;191(1):207-224. doi: 10.1007/s00360-020-01325-x. Epub 2020 Nov 19.
Sloths exhibit almost obligatory suspensory locomotion and posture. These behaviors require both strength and fatigue resistance, although we previously found muscle fiber type characteristics in the forelimbs of sloths that belied these initial expectations. Based on locomotor roles of the forelimbs versus hindlimbs in propulsion and braking, respectively, sloth hindlimb musculature should be adapted for force production and energy savings by a near homogeneous expression of slow myosin heavy chain (MHC) fibers. This hypothesis was tested by determining MHC fiber type (%) distribution and energy metabolism in the hindlimbs of three-toed (B. variegatus, N = 5) and two-toed (C. hoffmanni, N = 3) sloths. A primary expression of the slow MHC-1 isoform was found in the hindlimbs of both species. Slow MHC fiber type (%) was significantly greater in the flexors of B. variegatus, whereas expression of fast MHC-2A fibers was significantly greater in the extensors of C. hoffmannni. MHC-1 fibers were largest in cross-sectional area (CSA) and comprised the greatest %CSA in each muscle sampled from both species. Enzyme assays showed elevated activity for anaerobic enzymes (CK and LDH) compared with low-to-moderate activity for aerobic enzymes (3-HAD and CS), and only CK activity was related to body size. These findings emphasize a joint stabilization role by the hindlimbs during suspension, especially in smaller three-toed sloths, and suggest that larger two-toed sloths could have muscles further modified for greater power output and/or prolonged arboreal maneuvering. Moreover, modifications to muscle metabolism rather than MHC expression may be more reflective of functional adaptation in sloth limbs.
树懒表现出几乎强制性的悬挂式运动和姿势。这些行为既需要力量,又需要抗疲劳能力,尽管我们之前在树懒的前肢中发现了肌肉纤维类型特征,这与最初的预期背道而驰。基于前肢在推进和制动方面相对于后肢的运动作用,树懒后肢肌肉应该通过近乎均匀表达慢肌球蛋白重链 (MHC) 纤维来适应力量产生和节能。通过确定三种趾(B. variegatus,N=5)和两种趾(C. hoffmanni,N=3)树懒后肢的 MHC 纤维类型 (%)分布和能量代谢,检验了这一假设。在两种物种的后肢中都发现了慢 MHC-1 同工型的主要表达。B. variegatus 的屈肌中慢 MHC 纤维类型 (%)明显更高,而 C. hoffmannni 的伸肌中快 MHC-2A 纤维的表达明显更高。MHC-1 纤维的横截面积 (CSA) 最大,占两种物种每个肌肉样本的最大 %CSA。酶测定显示,与低到中等活性的有氧酶 (3-HAD 和 CS) 相比,无氧酶 (CK 和 LDH) 的活性更高,只有 CK 活性与体型相关。这些发现强调了后肢在悬挂时的联合稳定作用,尤其是在较小的三种趾树懒中,并且表明较大的两种趾树懒的肌肉可能进一步修改为更大的功率输出和/或延长树栖操纵。此外,肌肉代谢的改变而不是 MHC 表达可能更能反映树懒四肢的功能适应。
