Repair mechanisms involved in muscle regeneration following partial excision of the rat gastrocnemius muscle

The sequential cytological events of the regeneration process, after partial excision of the gastrocnemius muscle in the rat, were followed by light and electron microscopy. During the first 2 days after injury leukocytes and macrophages infiltrate into the traumatized area. Myogenic regeneration is then characterized by mainly two repair mechanisms. Mononucleated cells, that populate the excised area, most probably fuse together to give rise to newly formed multinucleated myotubes that further develop to striated myofibers. Another mechanism involves the repair of injured muscle fibers by the possible fusion of mononucleated cells with their necrotic cut ends. Consequently, by addition of nuclei and new muscular material, sarcoplasmic outgrowths from the injured fibers are formed. It is concluded that mainly two repair mechanisms are involved in the regeneration process following partial excision of a muscle: addition of new muscle fibers in a process similar to that of embryonic myogenesis and also meristic growth from the injured fibers.     

Conjugation of lectins with fluorochromes: an approach to histochemical double labeling of carbohydrate components.

Methodical investigations on the coupling of lectins (Con A, LcL, WGA, RcA) to tetramethylrhodamine isothiocyan ate (TRITC) are reported. 20-microgram of TRITC per mg of lectin were found to be the optimal amount of TRITC for the conjugation. With this fluorochrome: protein ratio conjugates were produced which resulted in a specific and brilliant fluorescence in tissue staining. The optimally conjugated lectins were separated on DEAE-Sephadex-A 50. Using two different lectins which were conjugated with TRITC or FITC, respectively, a double labeling of different lectin-binding sites in tissue sections was achieved.     

Selective protein transport: Characterization and solubilization of the phosvitin receptor from chicken oocytes

Phosvitin (PV), a subunit of a female-specific protein, vitellogenin, binds to oocyte membranes with a KD of 10^?6 M. Binding reaches equilibrium within 30 min after incubation at 25°C. Bound ¹²⁵I-PV dissociates from the membrane with a t1/2 of 13 h when incubated in buffer. However, when ¹²⁵I-PV-labeled membranes are incubated in buffer containing 10^?5 M unlabeled PV, 50% of the initially bound ¹²⁵I-PV dissociates from the membrane within 10 min. These results support the conclusion that PV binds to a membrane-associated receptor. Solubilization studies show that Triton X-100 solubilizes up to 45% of the total membrane-bound ¹²⁵I-PV. Gel-exculsion chromatography of the solubilized material yields a 500,000 dalton ¹²⁵I-PV-containing complex separated from free ¹²⁵I-PV. The 500,000 dalton complex completely dissociates to yield free ¹²⁵I-PV when incubated with excess unlabeled PV. However, when incubated with (1) no addition, (2) IgG, or (3) serum albumin, the extent of dissociation is significantly reduced and is consistent with that which would be predicted on the basis of the observed dissociation rate in the absence of unlabeled PV. These results suggest that bound ¹²⁵I-PV can only be displaced by unlabeled PV. These results also indicate that the 500,000 dalton species is a solubilized PV-receptor complex and that it is possible to solubilize the PV-receptor in an active form.