The embryonic cell lineage of the nematode Caenorhabditis elegans

The embryonic cell lineage of Caenorhabditis elegans has been traced from zygote to newly hatched larva, with the result that the entire cell lineage of this organism is now known. During embryogenesis 671 cells are generated; in the hermaphrodite 113 of these (in the male 111) undergo programmed death and the remainder either differentiate terminally or become postembryonic blast cells. The embryonic lineage is highly invariant, as are the fates of the cells to which it gives rise. In spite of the fixed relationship between cell ancestry and cell fate, the correlation between them lacks much obvious pattern. Thus, although most neurons arise from the embryonic ectoderm, some are produced by the mesoderm and a few are sisters to muscles; again, lineal boundaries do not necessarily coincide with functional boundaries. Nevertheless, cell ablation experiments (as well as previous cell isolation experiments) demonstrate substantial cell autonomy in at least some sections of embryogenesis. We conclude that the cell lineage itself, complex as it is, plays an important role in determining cell fate. We discuss the origin of the repeat units (partial segments) in the body wall, the generation of the various orders of symmetry, the analysis of the lineage in terms of sublineages, and evolutionary implications.     

Embryonic cell lineage of the marine nematode Pellioditis marina

We describe the complete embryonic cell lineage of the marine nematode Pellioditis marina (Rhabditidae) up to somatic muscle contraction, resulting in the formation of 638 cells, of which 67 undergo programmed cell death. In comparison with Caenorhabditis elegans, the overall lineage homology is 95.5%; fate homology, however, is only 76.4%. The majority of the differences in fate homology concern nervous, epidermal, and pharyngeal tissues. Gut and, remarkably, somatic muscle is highly conserved in number and position. Partial lineage data from the slower developing Halicephalobus sp. (Panagrolaimidae) reveal a lineage largely, but not exclusively, built up of monoclonal sublineage blocs with identical fates, unlike the polyclonal fate distribution in C. elegans and P. marina. The fate distribution pattern in a cell lineage could be a compromise between minimizing the number of specification events by monoclonal specification and minimizing the need for migrations by forming the cells close at their final position. The latter could contribute to a faster embryonic development. These results reveal that there is more than one way to build a nematode.     

Cell lineage and cell fate specification in the embryonic CNS of Drosophila

The Drosophila CNS derives from a population of neural stem cells, called neuroblasts (NBs), which delaminate individually from the neurogenic region of the ectoderm. In the embryonic ventral nerve cord each NB can be uniquely identified and gives rise to a specific lineage consisting of neurons and/or glial cells. This 'NB identity' is dependent on the position of the progenitor cells in the neuroectoderm before delamination. The positional information is provided by the products of segment polarity and dorsoventral (D/V) patterning genes. Subsequently, 'cell fate genes' like huckebein (hkb) and eagle (eg) contribute to the generation of specific NB lineages. These genes act downstream of segment polarity and D/V patterning genes and regulate different processes such as the generation of glial cells and the determination of serotonergic neurons.     

Gonadal cell lineages of the nematode Panagrellus redivivus and implications for evolution by the modification of cell lineage

To explore the nature of cell lineage modifications that have occurred during evolution, the gonadal cell lineages of the nematode Panagrellus redivivus have been determined and compared to the known gonadal lineages of Caenorhabditis elegans (J. Kimble and D. Hirsh, 1979, Develop. Biol.70, 396–417). Essentially invariant lineages generate the 143 somatic cells of the male gonad and at least 326 somatic cells of the female gonad of P. redivivus. The basic program of gonadogenesis is strikingly similar among both sexes of both species. For example, the early division patterns of the somatic gonad precursors Z1 and Z4 are almost identical. Later division patterns are more divergent and, in a few cases, generate structures that are species specific. In general, similar cell types are produced after similar patterns of cell divisions. Differences among the Z1 and Z4 cell lineages appear to reflect phylogenetic modifications of a common developmental program. The nature of these differences suggests that the evolution of cell lineages involves four distinct classes of alterations: switches in the fate of a cell to that normally associated with another cell; reversals in the polarity of the lineage generated by a blast cell; alterations in the number of rounds of cell division; and an “altered segregation” of developmental potential, so that a potential normally associated with one cell instead becomes associated with its sister. A number of cell deaths occur during gonadogenesis in P. redivivus. The death of Z4.pp, a cell that controls the development of the posterior ovary in C. elegans, probably prevents the development of a posterior ovary in P. redivivus and hence is responsible for the gross difference in the morphologies of the gonads of the P. redivivus female and the C. elegans hermaphrodite. As exemplified by the death of Z4.pp, an alteration in the fate of a “regulatory cell” could facilitate rapid and/or discontinuous evolutionary change.     

Polymeric fibrous matrices for substrate-mediated human embryonic stem cell lineage differentiation

Chitosan-based fibrous matrices are prepared to mimic the ECM architecture and elucidate substrate-mediated hESC differentiation due to topographical scale and anisotropy without exogenic morphogens. Fibrous matrices support fewer pluripotent hESCs than films but enable topography-mediated hESC differentiation. Matrices composed of 400 nm and 1.1 μm diameter fibers support increased expression of neural markers indicative of ectodermal commitment while matrices of 200 nm diameter fibers increase expression of osteogenic and hepatic markers indicative of endodermal and mesodermal commitment. The fibrous-mediated hESC differentiation highlights the significant implication of tailored ECM-like substrates for hESC-based therapies.     

Comparative analysis of embryonic cell lineage between Caenorhabditis briggsae and Caenorhabditis elegans

Comparative genomic analysis of important signaling pathways in Caenorhabditis briggsae and Caenorhabditis elegans reveals both conserved features and also differences. To build a framework to address the significance of these features we determined the C. briggsae embryonic cell lineage, using the tools StarryNite and AceTree. We traced both cell divisions and cell positions for all cells through all but the last round of cell division and for selected cells through the final round. We found the lineage to be remarkably similar to that of C. elegans. Not only did the founder cells give rise to similar numbers of progeny, the relative cell division timing and positions were largely maintained. These lineage similarities appear to give rise to similar cell fates as judged both by the positions of lineally equivalent cells and by the patterns of cell deaths in both species. However, some reproducible differences were seen, e.g., the P4 cell cycle length is more than 40% longer in C. briggsae than that in C. elegans (p < 0.01). The extensive conservation of embryonic development between such divergent species suggests that substantial evolutionary distance between these two species has not altered these early developmental cellular events, although the developmental defects of transpecies hybrids suggest that the details of the underlying molecular pathways have diverged sufficiently so as to not be interchangeable.     

Osteogenic cell lineage analysis is facilitated by organ cultures of embryonic chick periosteum

Monoclonal antibodies against the surface of embryonic osteogenic cells (SB-1, SB-2, SB-3, and SB-5) have been used to characterize the sequence of transitions involved in the osteogenic cell lineage. In the present study, immunohistochemical analyses of the expression of osteogenic cell surface antigens in organ cultures of folded chick periosteum were performed. Unlike traditional culture methods using isolated osteoblastic cells, periosteal explants form a mineralized bone tissue in 4 to 6 days which is virtually identical to the in vivo counterpart. Examination of fresh explants confirm that no mature osteoblastic cells were present, although a discontinuous layer of preosteoblasts was evident. As the wave of osteodifferentiation swept through the cultured tissue, antibody SB-1 reacted with the surface of a large family of cells associated with the developing bone. Antibodies SB-3 and SB-2 reacted with progressively smaller subsets of cells, namely those in successively closer physical association with the newly formed and mineralizing bone. Cells recently encased in bone matrix were stained by both SB-2 and SB-5 antibodies, while those cells deep within the matrix reacted only with antibody SB-5. Analysis of this culture model allows dissection of the discrete cellular transition steps of osteogenesis, and reveals that osteogenic precursor cells proceed through the unique lineage stages which have been documented for in vivo osteogenesis. This culture system has furthermore provided evidence which is used to refine our understanding of the osteogenic cell lineage.     

Analysis of the embryonic lineage of vertebrate taste buds

In all vertebrates, taste buds are the last sensory receptorsto appear late in embryonic development. They are thought toarise locally from the oropharyngeal epithelium, although thishypothesis has not been tested experimentally. Alternatively,taste buds have been proposed to arise from neurocctodermalcells that migrate from peripheral neurogenic sources to theoropharyngeal epithelium and give rise to taste bud precursorcells. In order to determine the exact embryonic lineage ofthe cells of vertebrate taste buds, we have employed a combinationof endogenous and exogenous cell marking techniques to followneuroectodermal and endodermal cells through development. Wefind, in the ambystomatid salamander used in our studies, tastebuds arise locally within the endodermally-derived epitheliumlining the oropharyngeal cavity, and do not receive a contributionfrom neuroectodermal sources, i.e. ectodermal placodes or cephalicneural crest.     

Intestinal lineage commitment of embryonic stem cells

Generating lineage-committed intestinal stem cells from embryonic stem cells (ESCs) could provide a tractable experimental system for understanding intestinal differentiation pathways and may ultimately provide cells for regenerating damaged intestinal tissue. We tested a two-step differentiation procedure in which ESCs were first cultured with activin A to favor formation of definitive endoderm, and then treated with fibroblast-conditioned medium with or without Wnt3A. The definitive endoderm expressed a number of genes associated with gut-tube development through mouse embryonic day 8.5 (Sox17, Foxa2, and Gata4 expressed and Id2 silent). The intestinal stem cell marker Lgr5 gene was also activated in the endodermal cells, whereas the Msi1, Ephb2, and Dcamkl1 intestinal stem cell markers were not. Exposure of the endoderm to fibroblast-conditioned medium with Wnt3A resulted in the activation of Id2, the remaining intestinal stem cell markers and the later gut markers Cdx2, Fabp2, and Muc2. Interestingly, genes associated with distal gut-associated mesoderm (Foxf2, Hlx, and Hoxd8) were also simulated by Wnt3A. The two-step differentiation protocol generated gut bodies with crypt-like structures that included regions of Lgr5-expressing proliferating cells and regions of cell differentiation. These gut bodies also had a smooth muscle component and some underwent peristaltic movement. The ability of the definitive endoderm to differentiate into intestinal epithelium was supported by the vivo engraftment of these cells into mouse colonic mucosa. These findings demonstrate that definitive endoderm derived from ESCs can carry out intestinal cell differentiation pathways and may provide cells to restore damaged intestinal tissue.     

The infection of nymphal Baetisbicaudatus by the mermithid nematode Gasteromermis sp.

1. This study reports the infection in nymphs of a bivoltine mayfly host ( Baetis bicaudatus ) in a high-elevation watershed by the mermithid nematode Gasteromermis sp. Infection by Gasteromermis causes mortality in two ways. Fifty per cent of the infections do not successfully develop beyond the initial stage of penetration and result in the early death of both host and parasite.
2. Infected hosts that survive this initial stage are rendered completely sterile by the infection (reproductively dead). In addition to complete sterility, the emergence size of parasitized nymphs is reduced and development time lengthened compared with unparasitized nymphs.
3. Parasite infection levels are stable from year to year at one site, but with a higher incidence of infection in the mayfly summer generation. Size differences between the generations at the time of infection may account for their different susceptibilities.
4. Within a year infection levels vary seasonally and spatially from 1 to 71%. Seasonally, there is a condensation of parasitized hosts towards the end of development as unparasitized nymphs emerge earlier. Spatially, infection levels show a downstream decline that may result from upstream dispersal by infected hosts or differential parasite survivorship at different elevations.     

The role of cell lineage in development

Studies of the role of cell lineage in development began in the latter part of the 19th century, fell into decline in the early part of the 20th, and were revived about 20 years ago. This recent revival was accompanied by the introduction of new and powerful analytical techniques. Concepts of importance for cell lineage studies include the principal division modes by which a cell may give rise to its descendant clone (proliferative, stem cell and diversifying); developmental determinacy, or indeterminacy, which refer to the degree to which the normal cleavage pattern of the early embryo and the developmental fate of its individual cells is, or is not, the same in specimen after specimen; commitment, which refers to the restriction of the developmental potential of a pluripotent embryonic cell; and equivalence group, which refers to two or more equivalently pluripotent cell clones that normally take on different fates but of which under abnormal conditions one clone can take on the fate of another. Cell lineage can be inferred to have a causative role in developmental cell fate in embryos in which induced changes in cell division patterns lead to changes in cell fate. Moreover, such a causative role of cell lineage is suggested by cases where homologous cell types characteristic of a symmetrical and longitudinally metameric body plan arise via homologous cell lineages. The developmental pathways of commitment to particular cell fates proceed according to a mixed typologic and topographic hierarchy, which appears to reflect an evolutionary compromise between maximizing the ease of ordering the spatial distribution of the determinants of commitment and minimizing the need for migration of differentially committed embryonic cells. Comparison of the developmental cell lineages in leeches and insects indicates that the early course of embryogenesis is radically different in these phyletically related taxa. This evolutionary divergence of the course of early embryogenesis appears to be attributable to an increasing prevalence of polyclonal rather than monoclonal commitment in the phylogenetic line leading from an annelid-like ancestor to insects.     

Control of vulval cell division number in the nematode Oscheius/Dolichorhabditis sp. CEW1

Spatial patterning of vulval precursor cell fates is achieved through a different two-stage induction mechanism in the nematode Oscheius/Dolichorhabditis sp. CEW1 compared with Caenorhabditis elegans. We therefore performed a genetic screen for vulva mutants in Oscheius sp. CEW1. Most mutants display phenotypes unknown in C. elegans. Here we present the largest mutant category, which affects division number of the vulva precursors P(4-8).p without changing their fate. Among these mutations, some reduce the number of divisions of P4.p and P8.p specifically. Two mutants omit the second cell cycle of all vulval lineages. A large subset of mutants undergo additional rounds of vulval divisions. We also found precocious and retarded heterochronic mutants. Whereas the C. elegans vulval lineage mutants can be interpreted as overall (homeotic) changes in precursor cell fates with concomitant cell cycle changes, the mutants described in Oscheius sp. CEW1 do not affect overall precursor fate and thereby dissociate the genetic mechanisms controlling vulval cell cycle and fate. Laser ablation experiments in these mutants reveal that the two first vulval divisions in Oscheius sp. CEW1 appear to be redundantly controlled by a gonad-independent mechanism and by a gonadal signal that operates partially independently of vulval fate induction.     

Evolutionary dissociation between cleavage, cell lineage and embryonic axes in sea urchin embryos.

Using vital dye staining and the microinjection of fluorescent cell lineage-autonomous tracers, the relationship between the first cleavage plane and the prospective larval dorsoventral axis was examined in several sea urchin species, including: Strongylocentrotus purpuratus, S. droebachiensis, Lytechinus pictus, Clypeaster rosaceus, Heliocidaris tuberculata and H. erythrogramma. The results indicate that there is no single relationship between the early cleavage pattern and the dorsoventral axis for all sea urchins; however, specific relationships exist for individual species. In S. purpuratus the first cleavage plane occurs at an angle 45 degrees clockwise with respect to the prospective dorsoventral axis in most cases, as viewed from the animal pole. On the other hand, in S. droebachiensis, L. pictus and H. tuberculata, the first cleavage plane generally corresponds with the plane of bilateral symmetry. There does not appear to be a predominant relationship between the first cleavage plane and the dorsoventral axis in C. rosaceus. In the direct-developing sea urchin H. erythrogramma the first cleavage plane bisects the dorsoventral axis through the frontal plane. Clearly, evolutionary differences have arisen in the relationship between cleavage pattern and developmental axes. Therefore, the mechanism of cell determination is not necessarily tied to any particular pattern of cell cleavage, but to an underlying framework of axial systems resident within sea urchin eggs and embryos.     

Ceramide glucosyltransferase of the nematode Caenorhabditis elegans is involved in oocyte formation and in early embryonic cell division

Ceramide glucosyltransferase (Ugcg) [uridine diphosphate (UDP)-glucose:N-acylsphingosine D-glucosyltransferase or UDP-glucose ceramide glucosyltransferase (GlcT): EC 2.4.1.80] catalyzes formation of glucosylceramide (GlcCer) from ceramide and UDP-glucose. There is only one Ugcg gene in the mouse genome, which is essential in embryogenesis and brain development. The nematode Caenorhabditis elegans has three Ugcg genes (cgt-1, cgt-2 and cgt-3), and double RNAi of the cgt-1 and cgt-3 genes results in lethality at the L1 larval stage. In this study, we isolated knockout worms for the three genes and characterized the gene functions. Each gene product showed active enzymatic activity when expressed in GM95 cells deficient in glycosphingolipids (GSLs). When each gene function was disrupted, the brood size of the animal markedly decreased, and abnormal oocytes and multinucleated embryos were formed. The CGT-3 protein had the highest Ugcg activity, and knockout of its gene resulted in the severest phenotype. When cgt-3 RNAi was performed on rrf-1 worms lacking somatic RNAi machinery but with intact germline RNAi machinery, a number of abnormal oocytes and multinucleated eggs were observed, although the somatic phenotype, i.e., L1 lethal effects of cgt-1/cgt-3 RNAi, was completely suppressed. Cell surface expression of GSLs and sphingomyelin, which are important components of membrane domains, was affected in the RNAi-treated embryos. In the embryos, an abnormality in cytokinesis was also observed. From these results, we concluded that the Ugcg gene is indispensable in the germline and that an ample supply of GlcCer is needed for oocytes and fertilized eggs to maintain normal membranes and to proceed through the normal cell cycle.     

Epidermal cell lineage.

The epidermis is a stratified squamous epithelium, which is under a constant state of proliferation, commitment, differentiation, and elimination so that the functional integrity of the tissue is maintained. The intact epidermis has the ability to respond to diverse environmental stimuli by continuous turnover to maintain its normal homeostasis throughout an organism's life. This is achieved by a tightly regulated balance between stem cell self-renewal and the generation of a population of cells that undergo a limited number of more rapid (amplifying) transit divisions before giving rise to nonproliferative, terminally differentiating cells. This process makes it an excellent model system to study lineage, commitment, and differentiation, although neither the identity of epidermal stem cells nor the precise steps and regulators that lead to mature epidermal cells have yet been determined. Furthermore, the identities of genes that initiate epidermal progenitor commitment to the epidermal lineage, from putative epidermal stem cells, are unknown. This is mainly due to the lack of an in vitro model system, as well as the lack of specific reagents, to study the early events in epidermal lineage. Our recent development of a differentiating embryonic stem cell model for epidermal lineage now offers the opportunity to analyze the factors that regulate epidermal lineage. These studies will provide new insight into epidermal lineage and lead to a better understanding of various hyperproliferative skin diseases such as psoriasis and cancer.     

Oligodendrocyte development in the embryonic brain: the contribution of the plp lineage

Oligodendrocytes are the myelin forming cells of the central nervous system. Over the last decade, their development in the embryonic brain and spinal cord has been documented following the discovery of early oligodendroglial markers. This review highlights the fundamental results obtained on the specification and migration of oligodendroglial cells and illustrates our advances in the knowledge of the cell lineage expressing plp (proteolipid protein), one of the early oligodendroglial genes.