摘要
Triple immunofluorescence staining has recently been developed to simultaneously identify all muscle fibers on a single cryosection which is helpful for clinical and basic research, but it has disadvantages such as fast photobleaching and unclear outlines of muscle fibers. Triple immunoenzyme staining(TIE) is likely to avoid these disadvantages. In this study, we aimed to establish a sensitive and specific TIE technique to identify fiber types in normal, denervated, and reinnervated rat muscles, and to develop a systematic sampling method for muscle fiber quantification. Tibialis anterior and soleus from normal, denervated, and reinnervated Lewis rat hind limbs were used. Five consecutive cryosections were cut from each muscle, including one for TIE and four for single immunoenzyme staining(SIE). The TIE was performed using the polymerized reporter enzyme staining system for the first two antigens(A4.74 for My HC-IIA, BA-F8 for My HC-I) and alkaline phosphatase staining system for the third antigen(BF-F3 for My HC-IIB), followed by corresponding detective systems and respective chromogens. The type of muscle fibers was quantified by systematic sampling at 12.5%, 25%, 33% and 50% of all muscle fibers, and was compared with that acquired from counting all the fibers(100%). All muscle fiber phenotypes, including pure and hybrid, could be simultaneously identified on a single TIE cryosection with clear outlines. The fiber types on TIE slides matched well with their respective counterpart on the consecutive SIE slides with a 95% match rate. Systematic sampling of 12.5% fibers could represent the true fiber type distribution of the entire muscle section. Our results suggest that novel TIE can effectively visualize fiber types in normal, denervated or reinnervated rat muscles.
Triple immunofluorescence staining has recently been developed to simultaneously identify all muscle fibers on a single cryosection which is helpful for clinical and basic research, but it has disadvantages such as fast photobleaching and unclear outlines of muscle fibers. Triple immunoenzyme staining(TIE) is likely to avoid these disadvantages. In this study, we aimed to establish a sensitive and specific TIE technique to identify fiber types in normal, denervated, and reinnervated rat muscles, and to develop a systematic sampling method for muscle fiber quantification. Tibialis anterior and soleus from normal, denervated, and reinnervated Lewis rat hind limbs were used. Five consecutive cryosections were cut from each muscle, including one for TIE and four for single immunoenzyme staining(SIE). The TIE was performed using the polymerized reporter enzyme staining system for the first two antigens(A4.74 for My HC-IIA, BA-F8 for My HC-I) and alkaline phosphatase staining system for the third antigen(BF-F3 for My HC-IIB), followed by corresponding detective systems and respective chromogens. The type of muscle fibers was quantified by systematic sampling at 12.5%, 25%, 33% and 50% of all muscle fibers, and was compared with that acquired from counting all the fibers(100%). All muscle fiber phenotypes, including pure and hybrid, could be simultaneously identified on a single TIE cryosection with clear outlines. The fiber types on TIE slides matched well with their respective counterpart on the consecutive SIE slides with a 95% match rate. Systematic sampling of 12.5% fibers could represent the true fiber type distribution of the entire muscle section. Our results suggest that novel TIE can effectively visualize fiber types in normal, denervated or reinnervated rat muscles.
基金
sponsored by the Armed Forces Institute of Regenerative Medicine award number W81XWH-08-2-0034
The U.S.Army Medical Research Acquisition Activity,820 Chandler Street,Fort Detrick MD 21702-5014 is the awarding and administering acquisition office
The content of the manuscript does not necessarily reflect the position or the policy of the Government,and no official endorsement should be inferred
supported(AJW)by CTSA Grants Number UL1 TR000135 and TL1 TR000137 from the National Center for Advancing Translational Science(NCATS)
supported by the Sundt Fellowship fund,Department of Neurological Surgery,Mayo Clinic
supported by the Helene Houle Career Development Award in Neurologic Surgery Research
Fund for the Center for Regenerative Medicine Program Director,Neuroregenerative Medicine,Mayo Clinic
