The search for the yellow crescent myogenic determinant is one of the long-standing quests of developmental biology. From Conklin's first observations that the determinant was located in a particularly colored cytoplasmic region, numerous investigators have tried to isolate it and determine how it functions. Two steps along the way were the demonstration that the factor operated to activate particular genes and that the factor may be an RNA localized to the cytoskeleton.
Richard Whittaker's Experiments on Muscle-Specific Acetylcholinesterase
In 1973, J. R. Whittaker provided dramatic biochemical confirmation of the cytoplasmic segregation of tissue determinants. Whittaker (1973) stained cells for the presence or absence of the enzyme acetylcholinesterase. This enzyme is found only in the larval muscle tissue and is involved in enabling muscles to respond to repeated nerve impulses. From the cell lineage studies of Conklin and others, it was known that only one pair of blastomeres (posterior vegetal; B4.1) in the 8-cell embryo is capable of producing tail muscle tissue. When Whittaker removed these two cells and placed them in isolation, they produced muscle tissue that stained positively for the presence of acetylcholinesterase. No other cell was able to form muscles when separated. (The b4.2 and A4.1 blastomeres can generate muscles, but through interaction with other cells, so they are not autonomous; Meedel et al., 1987; Nishida, 1987, 1990.)
Whittaker (1973) took tunicate embryos of various stages and arrested further cleavage by treating them with cytochalasin B. This drug binds to microfilaments, thus preventing cytokinesis (cell division) while allowing nuclear division to occur normally. In this manner, all further development occurs within the population of cells present at the time when cytochalasin was added. After the embryos had their further cleavages blocked, they were allowed to develop and then were stained for the presence of acetylcholinesterase. A comparison of these results with the cell lineage chart shows a striking concordance. The ability to produce muscle cells was originally present in both of the 2-cell blastomeres. However, by the 4-cell stage, the ability to produce acetylcholinesterase-synthesizing cells is limited to the vegetal blastomeres. In the 8-cell embryo, only the two posterior vegetal blastomeres can give rise to such cells. These are the cells known to form most of the tail muscles of the tunicate larva (Meedel et al., 1987; Nishida, 1987). The cells whose descendants were shown to synthesize acetylcholinesterase are precisely those cells destined to produce muscle autonomously. The production of that enzyme in the isolated cells occurs at exactly the time when it appears in normal embryos (Satoh, 1979).
Whereas the various inclusions of the fertilized egg (including yolk, pigment, and soluble proteins) can easily be displaced by centrifugation, such displacement does not usually affect embryogenesis (reviewed in Morgan, 1927). It appears, then, that either the determinants are too small to be moved by centrifugation or they are somehow anchored within the egg. The lack of diffusion manifest in the cytoplasmic localization of these determinants weighs against the first possibility. Most likely, the determinants are attached to insoluble material, probably the cytoskeletal framework of the cell. This infrastructure of filaments and tubules is particularly prominent in the oocyte cortex, but it extends throughout the cell. Cervera et al. (1981) have reported that most cellular RNA in cultured cells is associated with the cytoskeletal framework. Thus, the cytoskeleton might be a means of specifically localizing cytoplasmic determinants.
The cytoskeleton can be isolated by extracting cells with nonionic detergents such as Triton X-100. The detergent solubilizes lipids, tRNA, and monoribosomes. The remaining cytoskeleton contains microtubules, microfilaments, intermediate filaments, and roughly 200 proteins, including one that is capable of binding the 5' cap of mRNAs (Zumbe et al., 1982; Moon et al., 1983). In the tunicates Styelaand Boltenia, the muscle-forming yellow crescent is characterized by an actin-containing cytoskeletal domain. This domain is originally coextensive with the unfertilized egg. After fertilization, however, the actin microfilaments contract and become segregated into those blastomeres fated to form muscle cells, taking with them the yellow pigment granules and a set of mRNAs (Jeffery and Meier, 1983; Jeffery, 1984). Figure 2 shows that the cytoskeletal framework contains the yellow pigment granules and that these granules are given their intracellular localization by the movements of the oocyte cytoplasm during fertilization.
The proteins of this yellow crescent region differ significantly from the proteins of the rest of the egg, whereas the mRNAs in this region are not seen to be specific to the yellow crescent (Jeffery, 1985). One of these cytoskeletal proteins is a 58-kDa peptide that is localized in the periphery of the unfertilized egg, segregates to the yellow crescent during fertilization, and enters the tail muscle cells during subsequent development (Swalla et al., 1991). Thus, this cytoskeletal protein appears to follow the same route as the myoplasm during development. Moreover, in those species of ascidians that have direct development and lack a tailed tadpole stage, this protein is absent. The 58-kDa cytoskeletal protein is likely to be involved in myogenic determination in tunicates, perhaps as the protein that binds and moves the muscle cell determinant of ascidians.
In 1995, Swalla and Jefferey screened a one-cell zygote RNA library with probes made from the yellow crescent cytoplasm. This identified a 1.2 kilobase polyadenylated RNA that segregated with the yelow crescent. Moreover, as predicted, it could not be washed away by detergents which extracted everything but cytoskeletal-bound RNAs. This became the primary candidate for the yellow crescent myogenic determinant.
Cervera, M., Dreyfuss, G. and Penman, S. 1981. Messenger RNA is translated when associated with the cytoskeletal framework in normal and VSV-infected HeLa cells. Cell 23: 113-120.
Jeffery, W. R. 1984. Spatial distribution of messenger RNA in the cytoskeletal framework of ascidian eggs. Dev. Biol. 103: 482-492.
Jeffery, W. R. 1985. Identification of proteins and mRNAs in isolated yellow crescents of ascidian eggs. J. Embryol. Exp. Morphol. 89: 275-287.
Jeffery, W. R. and Meier, S. 1983. A yellow crescent cytoskeletal domain in ascidian eggs and its role in early development. Dev. Biol. 96: 125-143.
Moon, R. T., Nicosia, R. F., Olsen, C., Hille, M. and Jeffery, W. R. 1983. The cytoskeletal framework of sea urchin eggs and embryos: Developmental changes in the association of messenger RNA. Dev. Biol. 95: 447-458.
Morgan, T. H. 1927. Experimental Embryology. Columbia University Press, New York.
Meedel, T. H., Crowthier, R. J. and Whittaker, J. R. 1987. Determinative properties of muscle lineages in ascidian embryos. Development100: 245-260.
Nishida, H. 1987. Cell lineage analysis in ascidian embryos by intracellular injection of a tracer enzyme. III. Up to the tissue restricted stage. Dev. Biol. 121: 526-541.
Nishida, H. 1990. Determinative mechanisms in secondary muscle lineages of ascidian embryos: Development of muscle-specific features in isolated muscle progenitor cells. Development 108: 559-568.
Satoh, N. 1979. On the "clock" mechanism determining the time of tissue-specific development during ascidian embryogenesis. I. Acetylcholinesterase development in cleavage-arrested embryos. J. Embryol. Exp. Morphol. 54: 131-139.
Swalla, B. J. and Jeffery, W. R. 1995. A maternal RNA localized in the yellow crescent is segregated to the larval muscle cells during ascidian development. Devel. Biol. 170: 353-364.
Swalla, B. J., Bladgett, M. R. and Jeffery, W. R. 1991. Identification of a cytoskeletal protein localized in the myoplasm of ascidian eggs: Localization is modified during anuran development. Development 111: 425-423.
Whittaker, J. R. 1973. Segregation during ascidian embryogenesis of egg cytoplasmic information for tissue-specific enzyme development. Proc. Natl. Acad. Sci. USA 70: 2096-2100.
Zumbe, A., Stahli, C. and Trachsel, H. 1982. Association of a Mr 50,000 cap-binding protein with the cytoskeleton in baby hamster kidney cells. Proc. Natl. Acad. Sci. USA 79: 2927-2931.