Early differences between alternate n blast cells in leech embryo

Segmentally iterated tissues of the mature leech comprise five distinct sets of definitive progeny that arise from chains of blast cells (m, n, o, p, and q bandlets) produced by five bilateral pairs of stem cells (M, N, O/P, O/P, and Q teloblasts). In each n and q bandlet, two blast cells are needed to generate one set of hemisegmental progeny, and two alternating classes of blast cells (nf and ns, qf and qs) can be distinguished after their first divisions. Furthermore, two distinct subsets of definitive N and Q progeny exist within each hemisegment. Here we first show that there is fixed correspondence between the class of blast cell and the subset of final progeny: ns cells contribute mainly anterior ganglionic neurons and epidermal cells; nf cells contribute mainly posterior ganglionic neurons, peripheral neurons and neuropil glia; qs cells contribute both ventral and dorsal progeny; and qf cells contribute only dorsal progeny. Second, ablation studies indicate that the two classes of n blast cells do not behave as an equivalence group in the germinal band. Finally, we show that the cycles giving rise to nf and ns blast cells differ. These data suggest that cellular interactions within the germinal band may not be critical in establishing the distinct nf and ns cell fates and that, conversely, differences between the two classes of n blast cells may be established at birth.     

Gangliogenesis in leech: morphogenetic processes leading to segmentation in the central nervous system

 Using intracellular lineage tracers to study the main neurogenic lineage (N lineage) of the glossiphoniid leech embryo, we have characterized events leading from continuous columns of segmental founder cells (nf and ns primary blast cells) to discrete, segmentally iterated ganglia. The separation between prospective ganglia was first evident as a fissure between the posterior boundary of nf- and the anterior boundary of ns-derived progeny. We also identified the sublineages of nf-derived cells that contribute parallel stripes of cells to each segment. These stripes of cells project ventrolaterally from the dorsolateral margin of each nascent ganglion to the ventral body wall. The position and orientation of the stripes suggests that they play a role in forming the posterior segmental nerve; they are not coincident with the ganglionic boundary, and they form well after the separation of ganglionic primordia. Previous work has shown that cells in the anterior stripe express the leech engrailed-class gene. Thus, in contrast to the role of cells expressing engrailed in Drosophila, the stripes of N-derived cells expressing an engrailed-class gene in leech do not seem to play a direct role in segmentation or segment polarity. Received: 10 October 1997 / Accepted: 12 December 1997     

Applications of mRNA injections for analyzing cell lineage and asymmetric cell divisions during segmentation in the leech Helobdella robusta

Synthetic mRNAs can be injected to achieve transient gene expression even for 'non-model' organisms in which genetic approaches are not feasible. Here, we have used this technique to express proteins that can serve as lineage tracers or reporters of cellular events in embryos of the glossiphoniid leech Helobdella robusta (phylum Annelida). As representatives of the proposed super-phylum Lophotrochozoa, glossiphoniid leeches are of interest for developmental and evolutionary comparisons. Their embryos are suitable for microinjection, but no genetic approaches are currently available. We have injected segmentation stem cells (teloblasts) with mRNAs encoding nuclear localized green fluorescent protein (nGFP) and its spectral variants, and have used tandem injections of nGFP mRNA followed by antisense morpholino oligomer (AS MO), to label single blast cell clones. These techniques permit high resolution cell lineage tracing in living embryos. We have applied them to the primary neurogenic (N) lineage, in which alternate segmental founder cells (nf and ns blast cells) contribute distinct sets of progeny to the segmental ganglia. The nf and ns blast cell clones exhibit strikingly different cell division patterns: the increase in cell number within the nf clone is roughly linear, while that in the ns clone is almost exponential. To analyze spindle dynamics in the asymmetric divisions of individual blast cells, we have injected teloblasts with mRNA encoding a tau::GFP fusion protein. Our results show that the asymmetric divisions of n blast cells result from a posterior shift of both the spindle within the cell and the midbody within the mitotic spindle, with differential regulation of these processes between nf and ns.     

Grandparental stem cells in leech segmentation: Differences in CDC42 expression are correlated with an alternating pattern of blast cell fates

Embryonic segmentation in clitellate annelids (oligochaetes and leeches) is a cell lineage-driven process. Embryos of these worms generate a posterior growth zone consisting of 5 bilateral pairs of identified segmentation stem cells (teloblasts), each of which produces a column of segmental founder cells (blast cells). Each blast cell generates a lineage-specific clone via a stereotyped sequence of cell divisions, which are typically unequal both in terms of the relative size of the sister cells and in the progeny to which they give rise. In two of the five teloblast lineages, including the ventralmost, primary neurogenic (N) lineage, the blast cells adopt two different fates, designated nf and ns, in exact alternation within the blast cell column; this is termed a grandparental stem cell lineage. To lay groundwork for investigating unequal divisions in the leech Helobdella, we have surveyed the Helobdella robusta genome for genes encoding orthologs of the Rho family GTPases, including the rho, rac and cdc42 sub-families, which are known to be involved in multiple processes involving cell polarization in other systems. We find that, in contrast to most other known systems the Helobdella genome contains two cdc42 orthologs, one of which is expressed at higher levels in the ns blast cells than in nf blast cells. We also demonstrate that the asymmetric divisions of the primary nf and ns blast cells are regulated by the polarized distribution of the activated form of the Cdc42 protein, rather than by the overall level of expression. Our results provide the first molecular insights into the mechanisms of the grandparental stem cell lineages, a novel, yet evolutionarily ancient stem cell division pattern. Our results also provide an example in which asymmetries in the distribution of Cdc42 activity, rather than in the overall levels of Cdc42 protein, are important regulating unequal divisions in animal cells.     

Establishment of segment polarity in the ectoderm of the leech Helobdella

The segmented ectoderm and mesoderm of the leech arise via a stereotyped cell lineage from embryonic stem cells called teloblasts. Each teloblast gives rise to a column of primary blast cell daughters, and the blast cells generate descendant clones that serve as the segmental repeats of their particular teloblast lineage. We have examined the mechanism by which the leech primary blast cell clones acquire segment polarity - i.e. a fixed sequence of positional values ordered along the anteroposterior axis of the segmental repeat. In the O and P teloblast lineages, the earliest divisions of the primary blast cell segregate anterior and posterior cell fates along the anteroposterior axis. Using a laser microbeam, we ablated single cells from both o and p blast cell clones at stages when the clone was two to four cells in length. The developmental fate of the remaining cells was characterized with rhodamine-dextran lineage tracer. Twelve different progeny cells were ablated, and in every case the ablation eliminated the normal descendants of the ablated cell while having little or no detectable effect on the developmental fate of the remaining cells. This included experiments in which we specifically ablated those blast cell progeny that are known to express the engrailed gene, or their lineal precursors. These findings confirm and extend a previous study by showing that the establishment of segment polarity in the leech ectoderm is largely independent of cell interactions conveyed along the anteroposterior axis. Both intercellular signaling and engrailed expression play an important role in the segment polarity specification of the Drosophila embryo, and our findings suggest that there may be little or no conservation of this developmental mechanism between those two organisms.     

Differentiation of the O and P cell lines in the embryo of the leech. II. Genealogical relationship of descendant pattern elements in alternative developmental pathways

The p blast cells are a group of embryonic precursors found in the ectodermal cell layer of the leech germinal band. Each p blast cell normally undergoes the same invariant sequence of cell divisions and gives rise to a precisely defined set of uniquely identifiable neuronal and epidermal descendants in the mature leech. In the present paper, various of the p blast cell progeny were injected with a fluorescent lineage tracer in order to characterize the cellular composition of their descendant clones, and the results show that there is a stereotyped segregation of descendant cell fates through the first three p blast cell divisions. Previous work has shown that neurons and epidermal specializations which normally descend from the p blast cell will arise from a different precursor--the o blast cell--in response to ablation of the neighboring P cell line and that if the o blast cell is at a certain stage of differentiation when the ablation is performed it will produce only a subset of the normal P descendants. Comparison with the present findings indicates that under those conditions the o blast cell clone is not simply recapitulating a branch of the normal p blast cell lineage, but rather manifests an alternative lineage in which P descendants exhibit an abnormal genealogical relationship. Thus, even though normal leech development comprises a nearly invariant cell lineage, lineage relationships are open to considerable reorganization under experimental conditions.     

Cell lineage analysis of pattern formation in the Tubifex embryo. II. Segmentation in the ectoderm

Ectodermal segmentation in the oligochaete annelid Tubifex is a process of separation of 50-microm-wide blocks of cells from the initially continuous ectodermal germ band (GB), a cell sheet consisting of four bandlets of blast cells derived from ectoteloblasts (N, O, P and Q). In this study, using intracellular lineage tracers, we characterized the morphogenetic processes that give rise to formation of these ectodermal segments. The formation of ectodermal segments began with formation of fissures, first on the ventral side and then on the dorsal side of the GB; the unification of these fissures gave rise to separation of a 50-microm-wide block of approximately 30 cells from the ectodermal GB. A set of experiments in which individual ectoteloblasts were labeled showed that as development proceeded, an initially linear array of blast cells in each ectodermal bandlet gradually changed its shape and that its contour became indented in a lineage-specific manner. These morphogenetic changes resulted in the formation of distinct cell clumps, which were separated from the bandlet to serve as segmental elements (SEs). SEs in the N and Q lineages were each comprised of clones of two consecutive primary blast cells. In contrast, in the O and P lineages, individual blast cell clones were distributed across SE boundaries; each SE was a mixture of a part of a more anterior clone and a part of the next more posterior clone. Morphogenetic events, including segmentation, in an ectodermal bandlet proceeded normally in the absence of neighboring ectodermal bandlets. Without the underlying mesoderm, separated SEs failed to space themselves at regular intervals along the anteroposterior axis. We suggest that ectodermal segmentation in Tubifex consists of two stages, autonomous morphogenesis of each bandlet leading to generation of SEs and the ensuing mesoderm-dependent alignment of separated SEs.     

Pattern formation in embryos of the oligochaete annelid Tubifex: cellular basis for segmentation and specification of segmental identity

The embryonic origin of metameric segmentation was examined in the oligochaete Tubifex using lineage tracers. Segments in Tubifex embryos arise from five bilateral pairs of longitudinal coherent columns (bandlets) of primary blast cells which are generated by five bilateral pairs of embryonic stem cells called teloblasts (M, N, O, P and Q). As development proceeds, an initially linear array of blast cells in each ectodermal bandlet gradually changes its shape in a lineage-specific manner. These morphogenetic changes result in the formation of distinct cell clumps, which are separated from the bandlet to serve as segmental elements (SEs). SEs in the N and Q lineages are each comprised of clones of two consecutive primary blast cells. In contrast, in the O and P lineages, individual blast cell clones are distributed across SE boundaries; each SE is a mixture of a part of the preceding anterior clone and a part of the next posterior clone. Morphogenetic events, including segmentation, in an ectodermal bandlet proceed normally in the absence of neighboring ectodermal bandlets. Without the underlying mesoderm, separated SEs fail to space themselves at regular intervals along the anteroposterior axis. It is suggested that ectodermal segmentation in Tubifex consists of two stages; autonomous morphogenesis of each bandlet leading to generation of SEs, and the ensuing mesoderm-dependent alignment of separated SEs. In contrast, metameric segmentation in the mesoderm (M lineage) is a one-step process in that it arises from an initially simple organization (i.e. a linear series) of primary m-blast cells, which individually serve as a founder cell of each segment. The boundary between mesodermal segments is determined autonomously. The results of a set of cell ablation and transplantation experiments, using alkaline phosphatase activity as a biochemical marker for segments VII and VIII suggest that segmental identities in primary m-blast cells are determined according to the genealogical position in the M lineage and that the M teloblast possesses a developmental program through which the sequence of blast cell identities is determined.     

Cell lineage,cell-cell interaction,and segment formation in the ectoderm of a glossiphoniid leech embryo

Cell division patterns and cell-cell interactions in the germinal bands of the glossiphoniid leech Helobdella triserialis were studied with the aid of a cell lineage tracer dye. Each germinal band of the Helobdella embryo consists of five columns, or bandlets, of primary blast cells, designated as the mesodermal m bandlet and ectodermal n, o, p, and q bandlets. Primary blast cells of each ectodermal bandlet appear to undergo stereotyped, lineage-specific cell divisions. The metameric segmentation pattern of the leech thus appears to arise through a series of segmentally iterated, stereotyped cell divisions of serially homologous primary blast cell clones. Cell-cell interactions were studied by means of cell ablations. With one exception, blast cells underwent their stereotyped divisions without regard to the presence or absence of their normal neighbors. In the one exceptional case, o blast cells underwent divisions normally characteristic of p blast cells when their normal neighboring p bandlet was deleted. However, both o and p blast cells underwent their normal stereotyped divisions when their neighboring m, n, and q bandlets were deleted. It is proposed that the differential choice of pathway by the o and p blast cells depends upon their relative position with respect to each other and to a polarity cue external to the germinal band.     

Ectodermal interactions during neurogenesis in the glossiphoniid leech Helobdella triserialis

Morphogenetic cell interactions during development were studied by combining cell ablation and cell lineage tracing techniques in embryos of the leech Helobdella triserialis. Ablation of an identified ectodermal teloblast, or teloblast precursor blastomere, on one side of an early embryo was often found to result in the later abnormal migration of the progeny cells of the corresponding contralateral, nonablated teloblast to the ablated side of the embryo; such abnormal migration was termed “midline violation.” Two different kinds of midline violation were observed. Crossover: after ablation of an N teloblast individual stem cell progeny of the contralateral N teloblast sometimes cross the ventral midline of the germinal plate of the embryo. Switching: after ablation of an OPQ teloblast precursor bandlets of stem cells produced by the contralateral O, P, or Q teloblasts sometimes switch to the germinal band of the ablated side at the site of origin of the germinal bands. The occurrence of crossover and switching shows that the eventual site occupied by a progeny cell of a particular teloblast is not automatically determined by its lineage, but also depends on interactions with other cells. Midline violation in the leech embryo CNS does not constitute true regulation, however, since the restoration of neurons to the ablated side is accompanied by a neuron deficit on the nonablated side. The occurrence of the two distinct kinds of midline violation, crossover and switching, may be explained by the relative position of the stem cell bandlets within the germinal bands, and by the geometrical features of the formation of the germinal plate from the germinal bands.     

Cell lineage analysis of pattern formation in the Tubifex embryo. I. Segmentation in the mesoderm.

Annelids are strongly segmented animals that display a high degree of metamerism in their body plan. The embryonic origin of metameric segmentation was examined in an oligochaete annelid Tubifex using lineage tracers. Segmental organization arises sequentially in the anterior-to-posterior direction along the longitudinal axis of the mesodermal germ band, a coherent column of primary blast cells that are produced from the mesodermal teloblast. Shortly after its birth, each primary blast cell undergoes a spatiotemporally stereotyped sequence of cell divisions to generate three classes of cells (in terms of cell size), which together give rise to a distinct cell cluster. Each cluster is composed of descendants of a single primary blast cell; there is no intermingling of cells between adjacent clusters. Relatively small-sized cells in each cluster become localized at its periphery, and they form coelomic walls including an intersegmental septum to establish individuality of segments. A set of cell ablation experiments showed that these features of mesodermal segmentation are not affected by the absence of the overlying ectodermal germ band. These results suggest that each primary blast cell serves as a founder cell of each mesodermal segment and that the boundary between segments is determined autonomously. It is concluded that the metameric body plan of Tubifex arises from an initially simple organization (i.e., a linear series) of segmental founder cells.     

<Emphasis Type="Italic">Hau-Pax6A</Emphasis> expression in the central nervous system of the leech embryo

The leech Helobdella sp. (Austin) has two genes of the Pax6 subfamily, one of which is characterized in detail. Hau-Pax6A was expressed during embryonic development in a pattern similar to other bilaterian animals. RNA was detected in cellular precursors of the central nervous system (CNS) and in peripheral cells including a population associated with the developing eye. The CNS of the mature leech is a ventral nerve cord composed of segmental ganglia, and embryonic Hau-Pax6A expression was primarily localized to the N teloblast lineage that generates the majority of ganglionic neurons. Expression began when the ganglion primordia were four cells in length and was initially restricted to a single cell, n_s.a, whose descendants will form the ganglion’s anterior edge. At later stages, the Hau-Pax6A expression pattern expanded to include additional CNS precursors, including some descendants of the O teloblast. Expression persisted through the early stages of ganglion morphogenesis but disappeared from the segmented body trunk at the time of neuronal differentiation. The timing and iterated pattern of Hau-Pax6A expression in the leech embryo suggests that this gene may play a role in the segmental patterning of CNS morphogenesis.     

Cell lineage and segmentation in the leech

Segments in the leech arise by the proliferation of longitudinally arrayed bandlets of blast cells derived from ten identifiable embryonic stem cells, two M, two N, four O/P and two Q teloblasts. In each bandlet, older blast cells lie ahead of those born later. By using microinjected cell lineage tracers it was shown previously that the teloblasts give rise to characteristic cell patterns made up of segmentally iterated complements of progeny designated as M, N, O, P and Q kinship groups. When a teloblast is injected after it has begun generating blast cells, a boundary is observed later in development between anterior, unlabelled progeny of blast cells produced before injection and posterior, labelled progeny of blast cells produced after injection. We have examined such boundaries in detail to establish the precise relationship between blast cell clones and segments, with the following conclusions: (i) in the M, O and P cell lines, one blast cell generates one segmental complement of progeny, but serially homologous blast clones intermix so that no segment boundaries can be defined based on primary blast cell clones; (ii) in the N and Q cell lines, two blast cells are required to generate a complete segmental complement of progeny; (iii) in the process of forming the germinal plate, cells derived from the N and Q teloblasts move past those derived from the M and O/P teloblasts, so that consegmental blast cell clones do not come into register until well after the establishment of segmentally iterated units within each bandlet.     

A distinct patterning mechanism of O and P cell fates in the development of the rostral segments of the leech Helobdella robusta: implications for the evolutionary dissociation of developmental pathway and morphological outcome

Despite a high degree of homonomy in the segmental organization of the ectoderm, the body plan of the leech is divided into two zones based on the distinct cell lineage patterns that give rise to the O/P portion of the segmental ectoderm. In the midbody and caudal segments, each segmental repeat of ectoderm arises in part from one 'o' blast cell and one 'p' blast cell. These two blast cells are positionally specified to distinct O and P fates, and give rise to differentiated descendant cells called O and P pattern elements, respectively. In the rostral segments, each segmental repeat of O and P pattern elements arises from a single 'op' blast cell. Based on their developmental fates and their responses to the ablation of neighboring cells, the granddaughters of the primary op blast cell are categorized into two O-type cells and two P-type cells. The O-type cells do not require the presence of the rest of the op blast cell clone for their normal development. By contrast, normal development of the P-type cells depends upon interactions with the other OP sublineages. Additional experiments showed that the O-type cells are the source of a repressive signal involved in the normal fate specification of the P-type cells. Our data suggest that the cell interactions involved in fate specification differ substantially in the rostral and midbody segments, even though the set of differentiated descendants produced by the rostral OP pathway and the midbody O and P pathways are very similar.     

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. © 1995 John Wiley & Sons, Inc.     

Stepwise commitment of blast cell fates during the positional specification of the O and P cell lines in the leech embryo

The o and p bandlets of the leech embryo are parallel columns of ectodermal blast cells which are identified by their relative positions, and which during normal embryogenesis follow distinct developmental pathways. A previous study showed that o blast cells are initially capable of following either the O or P pathway, and suggested that commitment to the O pathway depends upon interaction with the adjacent p bandlet. To better understand the nature and timing of this interaction we examined the fate of o blast cells whose p blast cell neighbors had been selectively ablated by photoexcitation of a fluorescent lineage tracer. If an o blast cell has not yet begun its secondary divisions, its normal commitment to the O pathway can be effectively prevented by ablation of the adjacent p bandlet. Comparing the outcome of progressively later lesions reveals that the progeny of the o blast cell become committed to the O pathway in a series of three discrete steps, and that these steps occur around the time of the first three blast cell divisions. Each of the three events affects a different subset of elements within the blast cell clone, and apparently commits those elements to either the O or P pathway depending upon the presence or absence of the other bandlet. These changes in blast cell fate are coextensive with the lesion along the bandlet's length, suggesting that the interaction of the two bandlets is localized to neighboring cells.     

Axon outgrowth along segmental nerves in the leech. I. Identification of candidate guidance cells

We studied the development of the major extraganglionic components of the germinal plate in embryos of the glossiphoniid leech Helobdella triserialis to improve our understanding of the mechanism of segmental nerve formation. We examined the outgrowth of groups of axons from ganglionic neurons into the segmental nerves, the migration of peripheral neurons and epidermal specializations to their definitive sites, and the development of circular and longitudinal muscle fibers. We visualized axons, as well as neurons and epidermal specializations, by means of fluorescent cell lineage tracers injected earlier into blastomeres and muscle fibers by means of immunofluorescence. The development of cells in all groups was found to follow a stereotyped pattern. Axons of ganglionic neurons approach some identified peripheral neurons located along the segmental nerve paths but not, in general, epidermal specializations and muscle fibers. Near the somata of a subset of peripheral neurons they approach, axons cease or interrupt their growth. These findings identify a set of candidate guidance cells for axonal outgrowth in the leech, similar to those previously described in the developing nervous system of insects.     

Cell interactions in the developing leech embryo

The stereotyped pattern of cell commitments during leech embryogenesis is described. The nature of cell commitments during segmentation differs significantly between leech and fruit fly. Despite the constancy of cell fate assignments in normal development, ablation experiments show that cell interactions are essential in setting some of these commitments. Interacting cells follow a positionally determined hierarchy of fate choices. For other cells, which appear to have fates fixed from birth, the possibility of determinative interactions between mother and daughter cells is discussed.