Craig R. Tomlinson

Localization of actin messenger RNA during early ascidian development

The spatial distribution of RNA sequences during early development of the ascidian, Styela plicata, was determined by in situ hybridization with poly(U) and cloned DNA probes. Styela eggs and embryos contain three colored cytoplasmic regions of specific morphogenetic fates, the ectoplasm, endoplasm, and myoplasm. These cytoplasmic regions participate in ooplasmic segregation after fertilization and are distributed to different cell lineages during early embryogenesis. n situ hybridization with poly(U) suggests that poly(A)+RNA is unevenly distributed in eggs and embryos, with about 45% in the ectoplasm, 50% in the endoplasm, and only 5% in the myoplasm. In situ hybridization with a histone DNA probe showed that histone RNA sequences were not localized in eggs or embryos and distributed between the three cytoplasmic regions according to their volumes. In situ hybridization with an actin DNA probe showed actin RNA was localized in the myoplasm and ectoplasm of eggs and embryos with about 45% present in the myoplasm, 40% in the ectoplasm, and only 15% in the endoplasm. These results suggest that a large proportion of the egg actin mRNA is localized in the myoplasm, participates in ooplasmic segregation after fertilization, and is differentially distributed to the mesodermal cell lineages during embryogenesis. Analysis of the translation products of egg mRNA suggests that the localized mRNA codes for a cytoplasmic actin isoform.

Evolution of the chordate muscle actin gene

SummaryThe ascidians Styela plicata, S. clava, and Mogula citrina are urochordates. The larvae of urochordates are considered to morphologically resemble the ancestral vertebrate. We asked whether larval and adult ascidian muscle actin sequences are nonmusclelike as in lower invertebrates, musclelike as in vertebrates, or possess characteristics of both. Nonmuscle and muscle actin cDNA clones from S. plicata were sequenced. Based on 27 diagnostic amino acids, which distinguish vertebrate muscle actin from other actins, we found that the deduced protein sequences of ascidian muscle actins exhibit similarities to both invertebrate and vertebrate muscle actins. A comparison to muscle actins from different vertebrate and invertebrate phylogenetic groups suggested that the urochordate muscle actins represent a transition from a nonmusclelike sequence to a vertebrate musclelike sequence. The ascidian adult muscle actin is more similar to skeletal actin and the larval muscle actin is more similar to cardiac actin, which indicates that the divergence of the skeletal and cardiac isoforms occurred before the emergence of urochordates. The muscle actin gene may be a powerful probe for investigating the chordate lineage.

PDGF-BB and TGF-α rescue gastrulation, spiculogenesis, and LpS1 expression in collagen-disrupted embryos of the sea urchin genus Lytechinus

Development and LpS1 transcription in Lytechinus embryos are arrested at the mesenchyme blastula stage when collagen deposition is inhibited by the lathrytic agent beta-aminopropionitrile (BAPN) or by proline analogs. We found that human recombinant platelet derived growth factor-BB (PDGF-BB) and transforming growth factor-alpha (TGF-alpha) synergistically rescue collagen disrupted/developmentally arrested L. pictus and L. variegatus embryos so that development and RNA accumulation of LpS1 proceed. In addition, nonspecific antagonists of PDGF block gastrulation and LpS1 RNA accumulation. The embryos recover and LpS1 RNA accumulation resumes when the antagonists are removed. These data suggest that a growth factor mediated pathway, associated with the ECM, is required for sea urchin gastrulation, spiculogenesis, and LpS1 gene activation.

Development of a muscle actin specified by maternal and zygotic mRNA in ascidian embryos

In this investigation, we characterize the embryonic and adult actins and describe the embryonic expression of a muscle actin in the ascidian Styela. Two-dimensional polyacrylamide gel electrophoresis showed that embryos, tadpole larvae, and adult organs contain three major and two minor isoforms of actin. Two of the major isoforms, which are present in the mantle, branchial sac, alimentary tract, and gonads of adults and in eggs, embryos, and heads and tails of tadpoles, are likely to be cytoplasmic actins. The third major isoform, which was enriched in the mantle and branchial sac of adults and localized primarily in the tails of tadpoles, is a muscle actin. The muscle actin isoform was not detected in eggs and early embryos. Radioactivity incorporation studies showed that the cytoplasmic actins were synthesized throughout early development, but muscle actin synthesis was first detected between the 16- and 64-cell stages, 2-3 hr after fertilization. Two lines of evidence indicate that embryonic muscle actin synthesis is directed in part by maternal mRNA. First, poly(A)+ RNA isolated from unfertilized eggs directed the synthesis of muscle actin in an mRNA-dependent reticulocyte lysate. Second, muscle actin was synthesized in anucleate egg fragments. Arguments are also presented that muscle actin synthesis is not directed exclusively by maternal mRNA. It is concluded that embryonic and adult Styela exhibit actin heterogeneity, that one of the actin isoforms is a muscle actin, and that the muscle actin is synthesized during embryogenesis under the direction of maternal and zygotic mRNA.

The Yellow Crescent of Ascidian Eggs: Molecular Organization, Localization and Role in Early Development

The molecular composition, localization, and role in early development of the yellow crescent cytoplasm is reviewed. The yellow, myoplasmic crescent is a localized cytoplasmic region preferentially distributed to the muscle and mesenchyme lineage cells during early development of ascidian eggs. It consists of a collection of lipid pigment granules with numerous adherent mitochondria underlain by a specific cytoskeletal domain. The yellow crescent cytoskeleton is comprised of a superficial, sub-membrane network of actin filaments (PML) and a more internal filamentous lattice which connects pigment granules and possibly other cytoplasmic organelles to the cell surface. The yellow crescent originates during oogenesis and is uniformly distributed around the periphery of the mature, unfertilized egg. After fertilization the peripheral cytoplasm streams into the vegetal hemisphere forming the yellow crescent. The yellow crescent cytoskeleton, under the direction of local changes in the concentration of calcium ions, seems to be involved in this movement. Although relatively poor in total mRNA, the yellow crescent is highly enriched in mRNA sequences coding for cytoplasmic actin. The enrichment in actin mRNA is due to an association of these molecules with yellow crescent cytoskeletal elements. In general, however, prevalent messages in the yellow crescent region are not qualitatively different from those in other areas of the egg. A wide variety of different proteins are also found in the yellow crescent which are a subset of those present in the whole egg. There is strong evidence that the yellow crescent contains cytoplasmic determinants which are segregated during cleavage and specify muscle cell properties in the cells they enter. The molecular nature and mode of action of these agents, however, remains to be determined.

Identification of an antennapedia-like homeobox gene in the ascidians Styela clava and S. plicata

Homeobox genes from the urochordates Styela clava (AHox2) and S. plicata (AHox3) were cloned and analyzed. The two genes are homologous and Antennapedia-like. The homeobox regions have 87% identity at the nucleotide level and are identical at the amino-acid level. No introns are present in the homeobox region of AHox3, and AHox3 is represented at a low copy number per haploid genome. AHox2 and AHox3 represent the second type of homeobox gene found in this evolutionarily and developmentally important group of organisms.

Two distinct forms of USF in the Lytechinus sea urchin embryo do not play a role in LpS1 gene inactivation upon disruption of the extracellular matrix.

Recent studies in our laboratory indicated that the upstream stimulatory factor (USF) in the sea urchin embryo of Lytechinus acts as a transcriptional repressor for the aboral ectoderm‐specific expression of the LpS1 genes. Disruption of the extracellular matrix (ECM) arrests development prior to gastrulation and inactivates the LpS1 genes. We wanted to determine whether the inactivation of the LpS1 genes by ECM disruption may be due to an increase in USF expression. In the course of the investigation, a second L. variegatus USF cDNA clone (LvUSF2) was isolated and sequenced. The deduced amino acid sequence of LvUSF2 is nearly identical to LvUSF1 except at the amino end, where they are sharply divergent. Like LvUSF1, LvUSF2 has a USF‐specific, a basic/helix‐loop‐helix, and a leucine zipper domain. Genomic DNA blots indicated that the two cDNA clones are derived from one gene, which suggested that the Lytechinus USF1 and USF2 mRNAs, of approximately 6.0 and 4.0 kb, respectively, are the result of differential RNA splicing. ECM disruption in Lytechinus embryos caused a relative drop in USF RNA accumulation levels to approximately 60% of control embryos, while LpS1 RNA accumulation levels dropped to less than 5%. USF protein levels and DNA binding activities in ECM‐disrupted embryos also dropped to approximately 60% to that of control embryos. A mutation at the USF binding site in an LpS1 promoter‐chloramphenicol acetyl transferase (CAT) fusion DNA construct did not cause a relative increase in CAT activity in ECM disrupted embryos. These results suggest that the induced drop in LpS1 gene expression by ECM disruption is not due to an increase in the repressive activity of USF.