Expression of actin mRNA in embryos of the leech Helobdella triserialis.

A cDNA clone (Htr-actin) containing a 1.48 kb insert corresponding to actin was isolated from a stage 10-11 Helobdella triserialis cDNA library by cross hybidization to a Drosophila melanogaster actin clone. The cDNA is equivalent in size to the adult actin mRNA detected by Northern analysis. Genomic Southern blot analysis revealed that Htr-actin is a single copy gene and is one member of a family of actins in H. triserialis. Protein sequence comparisons revealed that Htr-actin was most similar to actin-1 of the earthworm and like other invertebrate actins, Htr-actin was found to be more similar to mammalian cytoplasmic actins than to mammalian muscle-specific actins. In situ hybridization revealed that at early stages the actin mRNA was distributed primarily in the yolk-deficient cytoplasm of all cells. At later stages, elevated levels were detected over the germinal bands and plate. Following muscle formation, a subset of the actin mRNA expression pattern resembled the immunostaining pattern obtained with the muscle specific antibody, Lan3-14. The Htr-actin transcript was undetectable in the segmental nervous system. These studies lay the groundwork for any future ectopic gene expression studies using the Htr-actin promoter in the leech embryo.

Segmentally iterated expression of an engrailed-class gene in the embryo of an australian onychophoran.

We have identified an engrailed-class (en-class) gene and determined the distribution pattern of its protein during embryogenesis in a member of the Onychophora. The results of this work add to our understanding of the evolution of development and in addition, they contribute information toward clarifying the phylogenetic position of this group. We observe transient expression in a portion of each developing segment. By the time limbs have formed, segmental expression of en-class protein is restricted to the mesoderm. This pattern shares important spatio-temporal characteristics with those of Annelida and Arthropoda, both of which have members that express en-class genes segmentally in mesoderm and ectoderm.

Cloning and sequencing of a leech homolog to the Drosophila engrailed gene.

We have cloned and sequenced a homolog (ht-en) to the Drosophila engrailed (en) gene from the glossiphoniid leech, Helobdella triserialis. Amino acid comparisons of the ht-en homeodomain and C-terminal residues with the corresponding residues encoded by en-class genes of other species reveal 75-79% sequence identity. In addition, the ht-en sequence appears to have a serine-rich region 16 residues C-terminal from the homeodomain, which by analogy to Drosophila may be a target site for phosphorylation. The leech gene encodes some amino acid substitutions for residues that are highly conserved in other species. These are found within the second and third of the three putative helices of the homeodomain, and in both of the intervening turn regions.

Regionalization and segmentation of the leech.

Regionalization and segmentation of the leech body plan have been examined by numerous approaches over the years. A wealth of knowledge has accumulated regarding the normally invariant cell lineages of the leech and the degree of developmental plasticity that is possible in each cell line in early development and in neurogenesis. Homologues of genes that control regionalization and segmentation in Drosophila have been cloned from the leech and the expression patterns reveal conserved features with those in Drosophila and other organisms. Possible developmental functions of the en-class proteins in spatial and temporal modes of segment formation are discussed in light of leech and Drosophila development. Annelida and Arthropoda cell lineages of engrailed-class gene expression are compared in leech blast cell clones and crustacean parasegments. In addition, future directions for molecular analysis of segmentation of the leech are summarized.

Segmental expression of an engrailed-class gene during early development and neurogenesis in an annelid.

ht-en protein, an annelid homolog of the Drosophila engrailed protein, is expressed during both early development and neurogenesis in embryos of the leech, Helobdella triserialis. In Helobdella as in Drosophila, early expression is in segmentally iterated stripes of cells within the posterior portion of the segment and later expression is in cells of the segmental ganglia. These findings suggest that dual expression of an en-class gene was present in a common ancestor of annelids and arthropods.

Cell death in late embryogenesis of the leech Helobdella.

Cell death was characterized during stages 8 and 9 in the leech Helobdella with a modified terminal deoxynucleotidyl transferase-mediated dUTP nick end labeling method. Using confocal analysis, the positions of dying cells were compared to rows of cells expressing the leech engrailed protein ht-en and to fluorescently marked cell lineages. Dying cells were present in diverse tissues. Some dying cells were in no obvious pattern, and others were in segmentally iterated patterns. Particular attention was paid to the ectoderm and mesoderm, where most of the cells examined died over a period equivalent to 1-4 h at 25 degrees C. Segmentally iterated rows of dying cells were observed in the mesoderm just beneath the nf-derived ht-en expressing cell rows at a time when ht-en expressing cells were beginning to disappear. The position of these dying cell rows was consistent with a role in the partial deterioration of the septum.

Mesoderm is required for the formation of a segmented endodermal cell layer in the leech Helobdella.

The homeobox gene Lox3 is expressed in a segmentally iterated pattern within the endoderm of the leech Helobdella. We use that expression here to study endoderm differentiation following experimental ablations of mesoderm. Lox3 RNA was first detected by in situ hybridization at the stage when a definitive cellular endoderm is formed from its syncytial precursor and was never observed in derivatives of other germ layers. Expression is initially distributed throughout the endoderm, but rapidly disappears from specific regions of the nascent gut wall so as to produce a pattern of segmental stripes. The stripe pattern differs markedly between midgut organs, with thin stripes of Lox3 expression in the intercaecal constrictions of the crop and wide stripes of Lox3 expression marking the caecal bulges of the intestine. Lox3 expression in the rectum is not obviously segmental. Ablation of segmental mesoderm in the early Helobdella embryo prevents the formation of definitive endoderm and the expression of Lox3 RNA and leads to abnormalities in the morphogenesis of the gut tube. These endodermal deficits are precisely coextensive with the zone of mesodermal deficiency, suggesting that the mesoderm normally acts to promote the formation of the endodermal cell layer via local cell interactions. The segmental pattern of Lox3 expression is largely unaffected in portions of the endoderm surrounding such deficits, suggesting that endodermal segmentation is not established by lateral interactions within that tissue layer. Rather, we propose that the segmental organization of the endoderm is imprinted by vertical interactions with the segmental mesoderm.

Engineered interphase chromosome loops guide intrachromosomal recombination.

How large-scale topologies regulate interphase chromosome function remains an important question in eukaryotic cell biology. Looped structures are thought to modulate transcription by pairing promoters with distant control elements and to orchestrate intrachromosomal recombination events by pairing appropriate recombination partners. To explore the effects of chromosomal topology on intrachromosomal recombination, distinct loop geometries were engineered into chromosome III of the budding yeast Saccharomyces cerevisiae. These topologies were created by employing pairs of lac operator clusters to serve as pairing sites and a modified lac repressor to perform the role of a protein cross-bridge. The influence of these engineered loops on the selection of donor loci during mating-type switching was evaluated using novel genetic and molecular methods. These experiments demonstrate that engineered interphase chromosome loops are biologically active-capable of influencing the course of intrachromosomal recombination. They also provide insight into the mechanism of mating-type switching by revealing a causal relationship between defined chromosomal topologies and the choice of donor locus.

Cell lineage analysis of the expression of an engrailed homolog in leech embryos.

ht-en is an engrailed-class gene that is expressed during early development and neurogenesis in embryos of the leech Helobdella triserialis. During the early development of this annelid (stages 7-9), ht-en is expressed in each of the ectodermal and mesodermal teloblast lineages that contributes progeny to the definitive segments. ht-en is expressed transiently by individually identified cells within the segmentally iterated primary blast cell clones. Its expression is correlated with the age of the primary blast cell clone. After consegmental primary blast cell clones from the different teloblast lineages have come into segmental register, cells that express ht-en during stages 7-9 are clearly confined to a transverse region corresponding to the posterior portion of the segmental anlage, but not all cells within this region express ht-en. Only a minority of the identified cells that express ht-en during terminal differentiation of the segmental ganglia and body wall (stages 10-11) are descendants of cells that express ht-en in early development (stages 7-9).

Segmentation in leech development.

Segments in glossiphoniid leeches, such as Helobdella triserialis, are the products of sterotyped cell lineages that yield identifiable cells from first cleavage. Cell lines generating segmental tissues are separated from those generating prostomial tissues early in development. Segments arise from five bilateral pairs of longitudinal columns of primary blast cells that are generated by five bilateral pairs of embryonic stem cells called teloblasts. There are four ectodermal cell lines (N, O, P and Q) and one mesodermal cell line (M) on each side of the embryo. In normal development, each cell line generates a segmentally iterated set of identified definitive progeny comprising a mixture of cell types. In the M, O and P cell lines, each blast cell generates one segment's worth of definitive progeny (segmental complement). But the clones of blast cells in each of these three cell lines interdigitate longitudinally with cells of the adjacent clones from the same line, so that the clone of an individual m, o and p blast cell is distributed across more than one segment. Thus, there is no simple clonal basis for morphologically defined segments. In the N and Q cell lines, two blast cells are required to produce one segmental complement of definitive progeny; in each of these two cell lines, two classes of blast cells (nf and ns, qf and qs) are produced in exact alternation. Primary n and q blast cells are about the same size and are produced at the same rate as blast cells for the o and p bandlets, but the longitudinal extent of their clones is roughly half that of the o and p blast cells' clones.(ABSTRACT TRUNCATED AT 250 WORDS)

Nuclear suppressors of mitochondrial chloramphenicol resistance in Baker's yeast: their use for the isolation of novel mutants.

Strains that are genotypically sensitive to chloramphenicol and also contain one of the nuclear suppressors of mitochondrial chloramphenicol resistance (Waxman et al. 1979) were constructed. A manganese mutagenesis on such a strain produced chloramphenicol resistant mutants, most of which resulted from mutations in nuclear genes. These mutants may be either dominant or recessive, and they probably do not code for membrane proteins. The few mitochondrial mutants fall into several classes, but all result from mutations in the 21S rRNA gene. The suppressor allele effectively prevents the appearance of the most common group of mitochondrial mutants (those that map at cap1), and thereby enhances the selection of novel mutants in the region.

Identification of a neurogenic sublineage required for CNS segmentation in an Annelid.

In embryos of leeches (phylum Annelida), metameric structures arise sequentially from a germinal plate comprising the descendants of five pairs of embryonic stem cells called teloblasts. It has been shown that transverse stripes of cells expressing ht-en (a homolog of engrailed, a Drosophila segment polarity gene), arise in the germinal plate prior to the appearance of segmental ganglia and that, in the main neurogenic lineage (derived from the N teloblasts), the stripe of cells expressing ht-en demarcates the boundary between prospective segmental ganglia. Previous lineage-tracing experiments had suggested that the clones of nf and ns primary blast cells in the N lineage are confined to within segmental borders. This conclusion was called into question by the observation that the cells expressing ht-en do not appear to be at the very posterior edge of the nf clone, from which they arise. To resolve this issue, we have injected individual primary blast cells with fluorescent lineage tracers; we find that cells in the nf clone actually straddle two adjacent ganglia. Moreover, using photoablation techniques, we find that the nf clone is required for proper morphogenesis of the segmentally iterated central nervous system (CNS).

Molluscan engrailed expression, serial organization, and shell evolution.

Whether the serial features found in some molluscs are ancestral or derived is considered controversial. Here, in situ hybridization and antibody studies show iterated engrailed-gene expression in transverse rows of ectodermal cells bounding plate field development and spicule formation in the chiton, Lepidochitona cavema, as well as in cells surrounding the valves and in the early development of the shell hinge in the clam, Transennella tantilla. Ectodermal expression of engrailed is associated with skeletogenesis across a range of bilaterian phyla, suggesting a single evolutionary origin of invertebrate skeletons. The shared ancestry of bilaterian-invertebrate skeletons may help explain the sudden appearance of shelly fossils in the Cambrian. Our interpretation departs from the consideration of canonical metameres or segments as units of evolutionary analysis. In this interpretation, the shared ancestry of engrailed-gene function in the terminal/posterior addition of serially repeated elements during development explains the iterative expression of engrailed genes in a range of metazoan body plans.

Conserved anterior boundaries of Hox gene expression in the central nervous system of the leech Helobdella.

Molecular developmental studies of fly and mouse embryos have shown that the identity of individual body segments is controlled by a suite of homeobox-containing genes called the Hox cluster. To examine the conservation of this patterning mechanism in other segmented phyla, we here describe four Hox gene homologs isolated from glossiphoniid leeches of the genus Helobdella. Based on sequence similarity and phylogenetic analysis, the leech genes Lox7, Lox6, Lox20, and Lox5 are deemed to be orthologs of the Drosophila genes lab, Dfd, Scr, and Antp, respectively. Sequence similarities between Lox5 and Antp outside the homeodomain and phylogenetic reconstructions suggest that the Antennapedia family of Hox genes (as defined by Bürglin, 1994) had already expanded to include at least two discrete Antp and Ubx/abdA precursors prior to the annelid/arthropod divergence. In situ hybridization reveals that the four Lox genes described in this study are all expressed at high levels within the segmented portion of the central nervous system (CNS), with variable levels of expression in the segmental mesoderm. Little or no expression was seen in peripheral ectoderm or endoderm, or in the unsegmented head region (prostomium). Each Lox gene has a distinct anterior expression boundary within one of the four rostral segments, and the anterior-posterior (AP) order of these expression boundaries is identical to that reported for the orthologous Hox gene products in fly and mouse. This finding supports the idea that the process of AP axis differentiation is conserved among the higher metazoan phyla with respect to the regional expression of individual Hox genes along that axis. One unusual feature of leech Hox genes is the observation that some genes are only expressed during later development -- beginning at the time of terminal cell differentiation -- whereas others begin expression at a much earlier stage, and their RNA ceases to be detectable shortly after the onset of expression of the 'late' Hox genes. The functional significance of this temporal disparity is unknown, but it is noteworthy that only the two 'early' Hox genes display high levels of mesodermal expression.