The embryonic cell lineage of the nematode Caenorhabditis elegans

Molecular characterization of the histone gene family of Caenorhabditis elegans

The core histone genes (H2A, H2B, H3 and H4) of Caenorhabditis elegans are arranged in approximately 11 dispersed clusters and are not tandemly arrayed in the genome. Three well-characterized genomic clones, which contain histone genes, have one copy of each core histone gene per cluster. One of the clones (lambda Ceh-1) carries one histone cluster surrounded by several thousand base-pairs of non-histone DNA, and another clone (lambda Ceh-3) contains a histone cluster duplication surrounded by non-histone DNA. A third clone (lambda Ceh-2) carries a cluster of core histone genes flanked on one side (12,000 base-pairs away) by a single H2B gene and on the other by non-histone DNA. A fourth cluster (clone BE9) has one copy each of H3 and H4 and two copies each of H2A and H2B. This cluster is also flanked by non-histone DNA. Analysis of cosmid clones which overlap three of the clusters shows that no other histone clusters are closer than 8000 to 60,000 base-pairs, although unidentified non-histone transcription units are present on the flanking regions. Gene order within the histone clusters varies, and histone mRNAs are transcribed from both DNA strands. No H1 sequences are found on these core histone clones. Restriction fragment length polymorphisms between two related nematode strains (Bristol and Bergerac) were used as phenotypic markers in genetic crosses to map one histone cluster to linkage group V and another to linkage group IV. Hybridization of gene-specific probes from sea urchin to C. elegans RNA identifies C. elegans core histone messenger RNAs of sizes similar to sea urchin early stage histone mRNAs (H2A, H2B, H3 and H4). The organization of histone genes in C. elegans resembles the clustering found in most vertebrate organisms and does not resemble the tandem patterns of the early stage histone gene family of sea urchins or the major histone locus of Drosophila.

Aging can be genetically dissected into component processes using long-lived lines of Caenorhabditis elegans

The aging process has been dissected by analysis of genetic variants of the nematode Caenorhabditis elegans. Long-lived recombinant inbred lines were generated; some of these lines have mean and maximum life spans up to 70% longer than wild type. Longer life results from a slowing of the characteristic exponential increase in mortality rate that is typical of aging populations in all species. The length of developmental periods and the length of the reproductive period are unrelated to increased life span. Lengthened life is due entirely to an increase in postreproductive life span. Development, reproduction, and life span are each under independent genetic control. General motor activity decays linearly with chronological age in all genotypes. The decay in general motor activity is correlated with and a predictor of life span, suggesting that both share at least one common rate-determining component.

Cell lineage analysis in ascidian embryos by intracellular injection of a tracer enzyme. III. Up to the tissue restricted stage

Cell lineages during embryogenesis of the ascidian Halocynthia roretzi were analyzed up until the stage where each blastomere was fated to be only a single tissue type (i.e., the tissue restricted stage) by intracellular injection of horseradish peroxidase using the iontophoretic injection method. Initially, the developmental fates of all blastomeres of the 64-cell stage embryo were examined, and thereafter, only the fates of daughter blastomeres of those blastomeres that were not tissue restricted at the 64-cell stage were traced. The developmental fates of blastomeres were highly invariant except for two candidates for "equivalence groups" (J. Kimble, J. Sulston, and J. White (1979). In "Cell Lineage, Stem Cells and Cell Determination," pp. 59-68. Elsevier, Amsterdam/New York), in which cellular interaction is suggested to be involved in the specification of the fates. The right and left a8.25 cells gave rise to the otolith and ocellus, and the right and left b8.17 cells gave rise to the spinal cord and endodermal strand in a complementary manner. No fixed relationship existed between the position of the blastomere and its derivative. Most restrictions of cell fates occurred early in cleavage. The numbers of blastomeres which generated a single type of tissue were 44 at the 64-cell stage and 94 at the 110-cell stage. Eight pairs of blastomeres had not yet become tissue restricted by the 110-cell stage. Almost complete lineages of epidermis, nervous system, muscle, mesenchyme, notochord, and endodermal tissues were described, and a fate map was constructed for the blastula. For certain tissues, the primordial cells occupied two different regions. Supplementary investigations of the lineage of muscle cells were also performed on embryos of another species, Ciona intestinalis.

Genetic analysis of halothane sensitivity in Caenorhabditis elegans

The nematode Caenorhabditis elegans appears to be a useful model for studying the action of volatile anesthetics. A mutant strain that is hypersensitive to the widely used anesthetic halothane was described earlier. The mutation is now shown to be an allele of unc-79. Other alleles of unc-79 are also associated with hypersensitivity to halothane. A strain with a mutation in a second gene, unc-80, is also hypersensitive to halothane. Nematodes bearing mutations in both unc-79 and unc-80 are slightly more sensitive to halothane than those bearing only one of these mutations. Mutations in a third gene, unc-9, suppress both unc-79 and unc-80. Nematodes bearing the suppressor mutations alone have normal sensitivity to halothane. These results show that sensitivity to halothane can be altered by mutations in several different genes.

Parental DNA strands segregate randomly during embryonic development of Caenorhabditis elegans

The fate of gamete DNA was followed in the next generation embryos of the nematode C. elegans. Either male worms or spermless hermaphrodites were grown on bromodeoxyuridine-containing E. coli in order to label germ-line DNA. Matings then produced embryos in which only the DNA strands provided by the gametes contained label. This original gamete DNA could be detected during embryonic development by using a fluorescently labeled monoclonal antibody specific to bromodeoxyuridine. Both the number and position of fluorescent spots in the embryo indicate that gamete DNA strands segregate randomly during development. Random segregation of parental DNA strands rules out models of development that invoke chromosome imprinting or immortal DNA strands.

Sevenless, a cell-specific homeotic gene of Drosophila, encodes a putative transmembrane receptor with a tyrosine kinase domain

The determination of cell fates during the assembly of the ommatidia in the compound eye of Drosophila appears to be controlled by cell-cell interactions. In this process, the sevenless gene is essential for the development of a single type of photoreceptor cell. In the absence of proper sevenless function the cells that would normally become the R7 photoreceptors instead become nonneuronal cells. Previous morphological and genetic analysis has indicated that the product of the sevenless gene is involved in reading or interpreting the positional information that specifies this particular developmental pathway. The sevenless gene has now been isolated and characterized. The data indicate that sevenless encodes a transmembrane protein with a tyrosine kinase domain. This structural similarity between sevenless and certain hormone receptors suggests that similar mechanisms are involved in developmental decisions based on cell-cell interaction and physiological or developmental changes induced by diffusible factors.

Differentiated parental DNA strands confer developmental asymmetry on daughter cells in fission yeast

The two strands of the DNA molecule are complementary but not identical. Hence, upon semiconservative replication, different parental DNA strands are segregated to daughter cells. A molecular analysis suggests that the process of fission yeast mating-type interconversion uses asymmetry of the DNA strands to generate a regular lineage of cellular differentiation.

Caffeine-resistant mutants of Caenorhabditis elegans

Wild-typeCaenorhabditis elegansfails to reach adulthood if L1 larvae are incubated in the presence of 30 mM or greater concentrations of caffeine. Eleven mutants have been isolated in which caffeine has a less pronounced effect on development. The mutations are recessive, define two genes, and have been mapped. The mechanism(s) of resistance is unknown.

A provisional epithelium in leech embryo: cellular origins and influence on a developmental equivalence group

Segmental tissues of glossiphoniid leeches arise from rostrocaudally arrayed columns (bandlets) of segmental founder cells (primary m, n, o, p, and q blast cells) which undergo stereotyped sublineages to generate identifiable subsets of definitive progeny. The bandlets lie at the surface of the embryo beneath the squamous epithelium of a transient embryonic covering called the provisional integument. This "provisional epithelium" derives from microsomes produced during the early cleavage divisions. Previous experiments have shown that the primary o and p blast cells constitute an equivalence group, i.e., are initially developmentally equipotent and undergo hierarchical interactions which cause them to assume distinct O and P fates. Here, we examine the role of the provisional epithelium in determining the fates of the underlying o and p blast cells. Experiments entailing the microinjection of individual micromeres with cell lineage tracers show that, at stages 7-8 of normal development, the epithelium comprises coherent and relatively stereotyped domains derived from particular micromeres. Upon photoablating domains of epithelium labeled with photosensitizing lineage tracer, the normal assignment of O fates is disturbed; o blast cells divide symmetrically (as p blast cells do) and some supernumerary definitive progeny expressing P fates arise within the O lineage. We therefore conclude that the epithelium is essential for generation and/or reception of signal(s) by which the o and p blast cells' normally determine their fates. Finally, a new tracer substance, biotinylated fixable dextran (BFD), is described which was essential for this study by virtue of its superior resistance to photobleaching and which offers several other advantages as well.

A genetic pathway for the specification of the vulval cell lineages of Caenorhabditis elegans

Twenty-three genes have been assigned to particular steps in a genetic pathway for the specification of the vulval cell lineages of the nematode Caenorhabditis elegans. Mutations in most of these genes cause homoeotic transformations in the fates of individual cells, suggesting that these lineages may be specified by a series of decisions that distinguish between alternative cell fates. Fifteen of the genes function in a system involved in the intracellular response to the extracellular signal that induces vulval formation.

Fates of the blastomeres of the 16-cell stage Xenopus embryo

The fate of each of the blastomeres in the 16-cell stage Xenopus embryo which had been carefully selected for stereotypic cleavages was determined by intracellularly marking a single blastomere with horseradish peroxidase and identifying the labeled progeny in the tailbud embryo by histochemistry. Each blastomere populated all three primary germ layers. The progeny of each blastomere were distributed characteristically both in phenotype and in location. For example, most organs were populated by the descendants of particular sets of blastomeres. Furthermore, within an organ the progeny of a single blastomere were restricted to defined spatial addresses. This study describes the fates of identified 16-cell stage blastomeres and demonstrates that they are distinct and predictable if embryos are preselected for stereotypic cleavages.

Cellular interactions in early C. elegans embryos

In normal development both the anterior and posterior blastomeres in a 2-cell C. elegans embryo produce some descendants that become muscles. We show that cellular interactions appear to be necessary in order for the anterior blastomere to produce these muscles. The anterior blastomere does not produce any muscle descendants after either the posterior blastomere or one of the daughters of the posterior blastomere is removed from the egg. Moreover, we demonstrate that a daughter of the anterior blastomere that normally does not produce muscles appears capable of generating muscles when interchanged with its sister, a cell that normally does produce muscles. Embryos develop normally after these blastomeres are interchanged, suggesting that cellular interactions play a major role in determining the fates of some cells in early embryogenesis.

Caenorhabditis elegans compensates for the difference in X chromosome dosage between the sexes by regulating transcript levels

The primary sex-determining signal in the nematode C. elegans is the ratio of X chromosomes to sets of autosomes (X/A ratio). As a consequence, males (XO; ratio 0.5) and hermaphrodites (XX; ratio 1.0) possess different doses of X-linked genes. Here we demonstrate that C. elegans compensates for this disparity in gene dose by equalizing the levels of X-specific mRNA transcripts in the two sexes. Moreover, we show that mutations in three autosomal genes disrupt the process of dosage compensation. Reduction in the activity of either dpy-21, dpy-27, or dpy-28 results in the overexpression of X-specific genes, 2- to 3-fold above wild-type levels.

Fluorescence visualization of the distribution of microfilaments in gonads and early embryos of the nematode Caenorhabditis elegans

Several intracellular motility events in the Caenorhabditis elegans zygote (pseudocleavage, the asymmetric meeting of the pronuclei, the segregation of germ line-specific granules, and the generation of an asymmetric spindle) appear to depend on microfilaments (MFs). To investigate how MFs participate in these manifestations of zygotic asymmetry, the distribution of MFs in oocytes and early embryos was examined, using both antibodies to actin and the F-actin-specific probe rhodamine-phalloidin. In early-stage zygotes, MFs are found in a uniform cortical meshwork of fine fibers and dots or foci. In later zygotes, concomitant with the intracellular movements that are thought to be MF mediated, MFs also become asymmetrically rearranged; as the zygote undergoes pseudocleavage and as the germ line granules become localized in the posterior half of the cell, the foci of actin become progressively more concentrated in the anterior hemisphere. The foci remain anterior as the spindle becomes asymmetric and the zygote undergoes its first mitosis, at which time fibers align circumferentially around the zygote where the cleavage furrow will form. A model for how the anterior foci of actin may participate in zygotic motility events is discussed. Phalloidin and anti-actin antibodies have also been used to visualize MFs in the somatic tissues of the adult gonad. The myoepithelial cells that surround maturing oocytes are visibly contractile and contain an unusual array of MF bundles; the MFs run roughly longitudinally from the loop of the gonad to the spermatheca. Myosin thick filaments are distributed along the MFs in a periodic manner suggestive of a sarcomere-like configuration. It is proposed that these actin and myosin filaments interact to cause sheath cell contraction and the movement of oocytes through the gonad.

Genetic programming of development: a model

Genetic programming of the developmental processes in multicellular organisms is proposed to be so intricate and vitally important that a large set of genes is dedicated solely to this end. It is further proposed that this set can be compartmentalized into subsets on the basis of the changes in gene activities that occur during ontogenesis, and that the genes in each subset transiently control the epigenetic activities of a small group of cells. Automatic subset activation is achieved by the product of a gene in each subset that transfers activity specifically to the subset next in the developmental sequence. This device can generate a unidirectional series of activations that cascade hierarchically through development like toppling dominoes. The model provides a basis for developmental phenomena, such as pattern formation, morphogenesis, and regeneration, and it makes testable predictions at the molecular level.

Mutant sensory cilia in the nematode Caenorhabditis elegans

Eight classes of chemosensory neurons in C. elegans fill with fluorescein when living animals are placed in a dye solution. Fluorescein enters the neurons through their exposed sensory cilia. Mutations in 14 genes prevent dye uptake and disrupt chemosensory behaviors. Each of these genes affects the ultrastructure of the chemosensory cilia or their accessory cells. In each case, the cilia are shorter or less exposed than normal, suggesting that dye contact is the principal factor under selection. Ten genes affect many or all of the sensory cilia in the head. The daf-19 (m86) mutation eliminates all cilia, leaving only occasional centrioles in the dendrites. The cilia in che-13 (e1805), osm-1 (p808), osm-5 (p813), and osm-6 (p811) mutants have normal transition zones and severely shortened axonemes. Doublet-microtubules, attached to the membrane by Y links, assemble ectopically proximal to the cilia in these mutants. The amphid cilia in che-11 (e1810) are irregular in diameter and contain dark ground material in the middle of the axonemes. Certain mechanocilia are also affected. The amphid cilia in che-10 (e1809) apparently degenerate, leaving dendrites with bulb-shaped endings filled with dark ground material. The mechanocilia lack striated rootlets. Cilia defects have also been found in che-2, che-3, and daf-10 mutants. The osm-3 (p802) mutation specifically eliminates the distal segment of the amphid cilia. Mutations in three genes affect sensillar support cells. The che-12 (e1812) mutation eliminates matrix material normally secreted by the amphid sheath cell. The che-14 (e1960) mutation disrupts the joining of the amphid sheath and socket cells to form the receptor channel. A similar defect has been observed in daf-6 mutants. Four additional genes affect specific classes of ciliated sensory neurons. The mec-1 and mec-8 (e398) mutations disrupt the fasciculation of the amphid cilia. The cat-6 (e1861) mutation disrupts the tubular bodies of the CEP mechanocilia. A cryophilic thermotaxis mutant, ttx-1 (p767), lacks fingers on the AFD dendrite, suggesting this neuron is thermosensory.

Development of reticulospinal neurons of the zebrafish. I. Time of origin

The times of origin (birthdays) of identifiable types of reticulospinal (RS) neurons of the zebrafish (Brachydanio rerio) were determined in order to learn if differences in neuronal characteristics among cell types correlate with differences in their times of origin. The RS neurons are located in the midbrain and hindbrain and cell types can be identified by differences in their cell body sizes and positions, axonal projections, and dendritic arborizations (Metcalfe et al., J. Comp. Neurol. 251: 147-159, 1986). In this study, the birthdays of RS cells were determined by combining 3H-thymidine autoradiography with horseradish peroxidase histochemistry. The RS neurons that were examined were generated between 7 and 28 h after fertilization. Each cell type had a specific time of origin. Dorsally located neurons were always generated earlier than ventral neurons present at the same axial level. Often, but not always, larger and more lateral neurons were born earlier than smaller and more medial ones. There was no overall rostrocaudal gradient of neuronal generation and no overall correlation between time of origin and axonal pathway. However, the times at which RS neurons are generated may be important with respect to the establishment of their characteristic dorsoventral positions in the brain.

Computer-aided three-dimensional reconstruction of nematode embryos from EM serial sections

Embryos of the nematode Caenorhabditis elegans were serially sectioned and photographed in the electron microscope (EM). The micrographs were used to produce three-dimensional (3D) reconstructions. Size and position of each nucleus were entered into a computer, displayed as spheres, and were color-coded to indicate lineage membership. Location in space and position in the cell cycle are generally adequate criteria to identify cells. The reconstructions allow visualization of lineage-related topographic patterns and ultrastructural analysis of differently determined cells.

Caenorhabditis elegans morphogenesis: the role of the cytoskeleton in elongation of the embryo

During development Caenorhabditis elegans changes from an embryo that is relatively spherical in shape to a long thin worm. This paper provides evidence that the elongation of the body is caused by the outermost layer of embryonic cells, the hypodermis, squeezing the embryo circumferentially. The hypodermal cells surround the embryo and are linked together by cellular junctions. Numerous circumferentially oriented bundles of microfilaments are present at the outer surfaces of the hypodermal cells as the embryo elongates. Elongation is associated with an apparent pressure on the internal cells of the embryo, and cytochalasin D reversibly inhibits both elongation and the increase in pressure. Circumferentially oriented microtubules also are associated with the outer membranes of the hypodermal cells during elongation. Experiments with the microtubule inhibitors colcemid, griseofulvin, and nocodazole suggest that the microtubules function to distribute across the membrane stresses resulting from microfilament contraction, such that the embryo decreases in circumference uniformly during elongation. While the cytoskeletal organization of the hypodermal cells appears to determine the shape of the embryo during elongation, an extracellular cuticle appears to maintain the body shape after elongation.

Replication and expression of an X-linked cluster of Drosophila chorion genes

Two 80- to 100-kb chromosomal replicons containing clustered chorion genes amplify in the ovarian follicle cells during the final 22 hr of Drosophila oogenesis. We have studied the relationship between amplification and transcription within one of these domains, located at 7E10-7F3,4 on the X chromosome. A tandem cluster of six genes, encoding chorion structural proteins s36-1, s38-1, and four putative minor chorion protein mRNAs, was mapped in the central 18 kb of the amplified domain, a region showing the highest levels of amplification. The regions both proximal and distal to this gene cluster, where lower levels of amplification occur, were also transcribed in ovary, but mRNAs produced specifically during choriogenesis were not detected. Thus, differences in amplification do not appear to modulate differential RNA accumulation. Instead, the gradient of amplification observed in egg chamber DNA may simply reflect the mechanism of amplification. In the female sterile mutation, In(1)ocelliless, a chromosomal rearrangement separates the central gene cluster into two parts, only one of which retains the capacity to amplify. Genes located within the unamplified portion of the ocelliless chromosome were expressed at the appropriate time during oogenesis, but at a 5- to 10-fold reduced level of RNA per gene. Thus neither cluster integrity nor amplification are required for the normal developmental program of gene expression within the cluster.

Neuronal Circuits: An Evolutionary Perspective

To understand neural circuits completely, it is necessary to know not only how they work, but also why they work that way. Answers to the latter question have been almost teleological in their assumption of optimal design. However, close examination of certain systems has revealed features that apparently lack adaptive value. Their existence can be understood only if the evolution of these circuits is considered and, in particular, how nonadaptive determinants have guided that evoluton.

A gene involved in the development of the posterior body region of C. elegans

Many regional differences in Caenorhabditis elegans body pattern are generated after hatching. Here I describe a gene, mab-5, that is required for the postembryonic development of nearly all ectodermal and mesodermal features that normally characterize a posterior body region. In addition, this gene is necessary for most cell migrations toward the posterior, but not for cell migrations toward the anterior. mab-5+ activity is cell-autonomous. In animals carrying a mutation in the gene lin-22, increases or decreases in mab-5+ gene dosage produce corresponding increases or decreases in the size of the region in which cells adopt posterior-specific fates. The model that best explains the data is that during postembryonic development, posterior-specific patterns of cell differentiation and cell migration are initiated by graded positional information, and that a common step in the different cellular responses to this information is mediated by mab-5 activity.

Microtubules and microtubule-associated proteins from the nematode Caenorhabditis elegans: periodic cross-links connect microtubules in vitro

The nematode Caenorhabditis elegans should be an excellent model system in which to study the role of microtubules in mitosis, embryogenesis, morphogenesis, and nerve function. It may be studied by the use of biochemical, genetic, molecular biological, and cell biological approaches. We have purified microtubules and microtubule-associated proteins (MAPs) from C. elegans by the use of the anti-tumor drug taxol (Vallee, R. B., 1982, J. Cell Biol., 92:435-44). Approximately 0.2 mg of microtubules and 0.03 mg of MAPs were isolated from each gram of C. elegans. The C. elegans microtubules were smaller in diameter than bovine microtubules assembled in vitro in the same buffer. They contained primarily 9-11 protofilaments, while the bovine microtubules contained 13 protofilaments. The principal MAP had an apparent molecular weight of 32,000 and the minor MAPs were 30,000, 45,000, 47,000, 50,000, 57,000, and 100,000-110,000 mol wt as determined by SDS-gel electrophoresis. The microtubules were observed, by electron microscopy of negatively stained preparations, to be connected by stretches of highly periodic cross-links. The cross-links connected the adjacent protofilaments of aligned microtubules, and occurred at a frequency of one cross-link every 7.7 +/- 0.9 nm, or one cross-link per tubulin dimer along the protofilament. The cross-links were removed when the MAPs were extracted from the microtubules with 0.4 M NaCl. The cross-links then re-formed when the microtubules and the MAPs were recombined in a low salt buffer. These results strongly suggest that the cross-links are composed of MAPs.

Intermediate filaments in muscle and epithelial cells of nematodes

Current concepts of the developmentally controlled multigene family of intermediate filament (IF) proteins expect the origin of their complexity in evolutionary precursors preceding all vertebrate classes. Among invertebrates, however, firm ultrastructural as well as molecular documentation of IFs is restricted to some giant axons and to epithelia of a few molluscs and annelids. As Ascaris lumbricoides is easily dissected into clean tissues, IF expression in this large nematode was analyzed by electron microscopic and biochemical procedures and a monoclonal antibody reacting with all mammalian IF proteins. We document for the first time the presence of IFs in muscle cells of an invertebrate. They occur in three muscle types (irregular striated pharynx muscle, obliquely striated body muscle, uterus smooth muscle). IFs are also found in the epithelia studied (syncytial epidermis, intestine, ovary, testis). Immunoblots on muscles, pharynx, intestine, uterus, and epidermis identify a pair of polypeptides (with apparent molecular masses of 71 and 63 kD) as IF constituents. In vitro reconstitution of filaments was obtained with the proteins purified from body muscle. In the small nematode Caenorhabditis elegans IF proteins are so far found only in the massive desmosome-anchored tonofilament bundles which traverse a special epithelial cell type, the marginal cells of the pharynx. We speculate that IFs may occur in most but perhaps not all invertebrates and that they may not occur in all cells in large amounts. As electron micrographs of the epidermis of a planarian--a member of the Platyhelminthes--reveal IFs, the evolutionary origin of this cytoplasmic structure can be expected either among the lowest metazoa or already in some unicellular eukaryotes.

Cell lineage relationships in the development of the mammalian CNS: role of cell lineage in control of cerebellar Purkinje cell number

This report continues our studies of the cell lineage relationships among the cells of the cerebellar Purkinje cell population. It examines the question of whether there are cell autonomous factors that regulate cell number during mammalian CNS development. Experimental aggregation chimeras were made by the joining of two embryos, one wild-type, one lurcher in genotype; both embryos were of C57BL/6 genetic background. Since all Purkinje cells of +/Lc genotype will degenerate, only wild-type Purkinje cells remain in the cerebellar cortex of the adult chimeras. The number of remaining cells does not vary uniformly from zero (the lurcher value) to wild-type (92,000 for C57BL/6). Rather the cells occur in numerical quanta that represent developmental clones of cells. In an earlier work, the Purkinje cell population of the C3H/HeJ inbred strain was shown to consist of eight such clones in each cerebellar half. Each C3H/HeJ clone contains 10,200 Purkinje cells. Evidence is presented in the present study that the Purkinje cells of the C57BL/6 strain, exist in 10 clones, of 9200 cells per half cerebellum. The findings suggest that a clonal organization exists in the Purkinje cell population of at least two inbred strains of mice, that differences in adult neuronal number can be due to either the number of clones present or the size of each individual clone (i.e., the number of cells per clone), and that the number of cells in a clone appears to be an autonomous property of the lineage itself and hence, presumably, of the progenitor cell that founded the clone.

Isolation and characterization of Caenorhabditis elegans DNA sequences homologous to the v-abl oncogene

DNA sequences homologous to the v-abl oncogene were isolated from a Caenorhabditis elegans genomic library by their ability to hybridize with a v-src probe. The DNA sequence of 2465 nucleotides of one clone was determined. This region corresponds to the 5' protein kinase domain of v-abl plus approximately equal to 375 base pairs toward the 3' end. Four potential introns were identified. The homology between the deduced amino acid sequence of the C. elegans clone and that of the 1.2-kilobase-pair protein kinase region of v-abl is 62%. The tyrosine residue corresponding to the tyrosine that is phosphorylated in the v-src protein is conserved in the C. elegans sequence. When 95 amino acids around this tyrosine were compared with the corresponding sequences of Drosophila c-abl, v-abl, and v-src, the identities were 83%, 79%, and 56%, respectively. Hybridization of the cloned DNA with C. elegans poly(A)+ RNA revealed a major transcript of 4.4 kilobases.

Pattern formation during vulval development in C. elegans

Previous studies have shown that the development of the vulva of the C. elegans hermaphrodite involves six multipotential hypodermal cells as well as the gonadal anchor cell, which induces vulval formation. Our further examination of the interactions among these seven cells has led to the following model. Each hypodermal precursor cell becomes determined to adopt one of its three potential fates; each of these fates is to generate a particular cell lineage. In the absence of cellular interactions each precursor cell will generate the nonvulval cell lineage; an inductive signal from the anchor cell is required for a precursor cell to generate either of the two types of vulval cell lineages. The inductive signal is spatially graded, and the potency of the signal specifies which lineage is expressed by each of the tripotential precursor cells.

Evidence in a nematode for regulation of transposon excision by tissue-specific factors

The transposable element Tc1 in Caenorhabditis elegans undergoes an excision reaction, which can be detected in a Southern hybridization as the appearance of empty chromosomal insertion sites. This excision reaction is under tissue-specific regulation in that it occurs at much higher frequency in somatic cells than in the germ line. We show here that this regulation is likely to be due to the action of tissue-specific factors that either promote excision in somatic tissues or repress it in the germ line. The rate of excision of elements at five distinct chromosomal sites has been measured by a method that avoids ambiguities due to cell division. All these elements are found to undergo excision at closely similar rates during the L1 larval stage. No distinct difference exists among the elements at different sites that would suggest regulation by flanking sequences.

Nerve cells in hydra: monoclonal antibodies identify two lineages with distinct mechanisms for their incorporation into head tissue

The relationship between populations of nerve cells defined by two monoclonal antibodies was investigated in Hydra oligactis. A population of sensory nerve cells localized in the head (hypostome and tentacles) is identified by the binding of antibody JD1. A second antibody, RC9, binds ganglion cells throughout the animal. When the nerve cell precursors, the interstitial cells, are depleted by treatment with hydroxyurea or nitrogen mustard, the JD1+ nerve cells are lost as epithelial tissue is sloughed at the extremities. In contrast, RC9+ nerve cells remain present in all regions of the animal following treatment with either drug. When such hydra are decapitated to initiate head regeneration, the new head tissue formed is again free of JD1+ sensory cells but does contain RC9+ ganglion cells. Our studies indicate that (1) nerve cells are passively displaced with the epithelial tissue in hydra, (2) JD1+ sensory cells do not arise by the conversion of body column nerve cells that are displaced into the head, whereas RC9+ head nerve cells can originate in the body column, (3) formation of new JD1+ sensory cells requires interstitial cell differentiation. We conclude from these results that the two populations defined by these antibodies are incorporated into the h ad via different developmental pathways and, therefore, constitute distinct nerve cell lineages.

Embryonic expression of a gut-specific esterase in Caenorhabditis elegans

We describe an esterase activity that, by the criterion of histochemical staining, is completely localized to the intestine of the nematode Caenorhabditis elegans. Esterase activity appears in the embryonic gut when the embryo contains 4-8 intestinal precursor cells and 100-150 total cells. Esterase activity is abolished by treating early embryos with alpha-amanitin, indicating that expression depends upon transcription by RNA polymerase II within the developing embryo. In partial embryos produced by lysing one blastomere of a two-cell embryo, esterase expression appears only in descendants of the blastomere that normally produces the gut; esterase expression appears independent of the other non-gut blastomere. In early cleavage-stage embryos in which cytokinesis has been blocked by cytochalasin D, esterase expression appears at the normal time and only in cells in the gut lineage; thus neither normal cell division nor normal embryogenesis is required for lineage-specific expression. However, esterase does not appear in cytochalasin D blocked one-cell embryos. These observations confirm the traditional view that C. elegans development is "mosaic," with each cell following a defined independent program of gene expression.

Two loci required for cytoplasmic organization in early embryos of Caenorhabditis elegans

We have identified five new alleles, including an amber allele, at each of two loci (zyg-11 II and zyg-9 II) previously identified by temperature-sensitive strict maternal-effect lethal mutations. Genetic analysis indicates that each of these genes is expressed specifically during oogenesis and encodes a protein product whose function is required only during embryogenesis. Temperature-pulse experiments suggest that the time of action of both products is during the one-cell stage of embryogenesis. Phenotypic analysis reveals that mutations in both loci lead to disorganization of the cytoplasm in early embryos and to abnormalities in at least one of the meiotic divisions. Mutations at the zyg-9 locus appear to specifically affect microtubule function in one-cell embryos while zyg-11 mutations affect many cytoplasmic properties.

Tissue-specific cell lineages originate in the gastrula of the zebrafish

In the zebrafish, cells of a clone derived from a single blastomere migrate away from one another during gastrulation. Later in development their descendants are usually found scattered within several different types of tissues of embryo. The divisions and migrations of individual cells were monitored during early development, revealing that in most cases the lineal descendants of single cells present at gastrula stage exclusively populate only single tissues, and may have stereotyped positional relationships within these tissues. Thus the gastrula stage is the first stage when heritable restrictions in cell type might arise in the zebrafish.

Transcription of class III genes in cell-free extracts from the nematode Caenorhabditis elegans

Using the nematode Caenorhabditis elegans as a model organism, we have prepared cell-free extracts which accurately transcribe cloned homologous 5S RNA genes in vitro. These extracts also transcribe cloned tRNA genes, and actively process the resulting products. Unlike tRNA genes, transcription of 5S DNA shows some species specificity: C. elegans extracts do not transcribe Xenopus 5S RNA genes, nor does a Xenopus extract efficiently transcribe the heterologous nematode 5S DNA. However, addition of limiting amounts of C. elegans fractions permits Xenopus extracts to transcribe nematode 5S RNA genes. This apparent biochemical "complementation" may provide an assay to purify 5S RNA gene-specific factors from C. elegans.

The major gut esterase locus in the nematode Caenorhabditis elegans

Mutations in the major gut esterase of the nematode Caenorhabditis elegans have been induced by ethylmethane sulfonate and detected by isoelectric focusing. The gut esterase locus, denoted ges-1, maps less than 0.3 map units to the right of the unc-60 locus, at the left end of chromosome V.