The zinc finger protein DIE-1 is required for late events during epithelial cell rearrangement in C. elegans

The mechanism by which epithelial cells undergo directed rearrangement is central to morphogenesis, yet the regulation of these movements remains poorly understood. We have investigated epithelial cell rearrangement (intercalation) in the dorsal hypodermis, or embryonic epidermis, of the C. elegans embryo by analyzing the die-1(w34) mutant, which fails to undergo normal intercalation. Dorsal hypodermal cells of die-1(w34) homozygous embryos initiate but fail to complete the process of intercalation. Multiphoton microscopy reveals that intercalating cells extend monopolar, basolateral protrusions in their direction of migration; posterior dorsal hypodermal cells in die-1(w34) mutants appear to extend protrusions normally, but fail to translocate their cell bodies to complete rearrangement. Despite abnormal intercalation, the subsequent morphogenetic movements that enclose the embryo with epithelial cells and the process of dorsal cell fusion still occur. However, elongation of the embryo into a wormlike shape is disrupted in die-1(w34) embryos, suggesting that intercalation may be necessary for subsequent elongation of the embryo. Actin filaments are not properly organized within the dorsal hypodermis of die-1(w34) embryos, consistent with intercalation's being a necessary prerequisite for elongation. The die-1 gene encodes a C2H2 zinc finger protein containing four fingers, which likely acts as a transcriptional regulator. DIE-1 is present in the nuclei of hypodermal, muscle, gut, and pharyngeal cells; its distribution suggests that DIE-1 acts in each of these tissues to regulate morphogenetic movements. die-1(w34) mutants display morphogenetic defects in the pharynx, gut, and muscle quadrants, in addition to the defects in the dorsal hypodermis, consistent with the DIE-1 expression pattern. Mosaic analysis indicates that DIE-1 is autonomously required in the posterior dorsal hypodermis for intercalation. Our analysis documents for the first time the dynamics of protrusive activity during epithelial cell rearrangement. Moreover, our analysis of die-1 shows that the events of epithelial cell rearrangement are under transcriptional control, and that early and later phases of epithelial cell rearrangement are genetically distinguishable.

Second-harmonic imaging microscopy of living cells

Second harmonic generation (SHG) has been developed in our laboratories as a high-resolution nonlinear optical imaging microscopy for cellular membranes and intact tissues. SHG shares many of the advantageous features for microscopy of another more established nonlinear optical technique: two-photon excited fluorescence (TPEF). Both are capable of optical sectioning to produce three-dimensional images of thick specimens and both result in less photodamage to living tissue than confocal microscopy. SHG is complementary to TPEF in that it uses a different contrast mechanism and is most easily detected in the transmitted light optical path. It can be used to image membrane probes with high membrane specificity and displays extraordinary sensitivity in reporting membrane potential; it also has the ability to image highly ordered structural proteins without any exogenous labels.

Neural cell adhesion molecule (NCAM) and myoblast fusion

Considerable evidence points to an involvement of neural cell adhesion molecule (NCAM) in myoblast fusion. Changes in the level of NCAM expression, isoform specificity, and localization in muscle cells and tissues correspond to key morphogenetic events during muscle differentiation and repair. Furthermore, anti-NCAM antibodies have been shown by others to reduce the rate of myoblast fusion, whereas overexpression of NCAM cDNAs increases the rate of myoblast fusion compared to controls. In this study we have used a novel fusion assay based on intracistronic complementation of lacZ, in combination with fluorescent X-gal histochemistry and immunocytochemistry to assess levels of NCAM expression in individual muscle cells. Our results indicate that a substantial proportion of newly fused myoblasts have NCAM expression levels unchanged from the levels of the surrounding unfused population suggesting that increased expression of NCAM is not required for wild-type myoblasts to fuse. Moreover, pure populations of primary myoblasts isolated from mice homozygous null for NCAM and therefore lacking the molecule, when placed in differentiation medium, consistently fused to form contractile myotubes with kinetics equivalent to wild-type primary myoblasts. We conclude that the increase in expression of NCAM, although typically observed during myogenesis, is not essential to myoblast fusion to form myotubes.

The Caenorhabditis elegans APC-related gene apr-1 is required for epithelial cell migration and Hox gene expression

Inactivation of the Caenorhabditis elegans APC-related gene (apr-1) has pointed at two separate functions of apr-1. First, apr-1 is required for the migration of epithelial cells during morphogenesis of the embryo. In this process, APR-1 may act in a Cadherin/alpha-Catenin/beta-Catenin complex as a component of adherens junctions. Second, apr-1 is required for Hox gene expression, most likely by positively regulating the activity of the Wingless signaling pathway. During embryogenesis, apr-1 is required for the expression of ceh-13 labial in anterior seam and muscle cells and during larval development, apr-1 is necessary for the expression of lin-39 deformed in the vulval precursor cells. Thus, APR-1 may positively regulate the activity of the beta-Catenin/Armadillo-related proteins HMP-2 in migrating epithelial cells and BAR-1 in the vulval precursor cells.

Dynamics and ultrastructure of developmental cell fusions in the Caenorhabditis elegans hypodermis

Cell fusions produce multinucleate syncytia that are crucial to the structure of essential tissues in many organisms [1-5]. In humans the entire musculature, much of the placenta, and key cells in bones and blood are derived from cell fusion. Yet the developmental fusion of cell membranes has never been directly observed and is poorly understood. Similarity between viral fusion proteins and recently discovered cellular proteins implies that both cell-cell and virus-cell fusion may occur by a similar mechanism [6-8]. Paradoxically, however, fusion of enveloped viruses with cells involves an opening originating as a single pore [9-11], whereas electron microscopy studies of cell-cell fusion describe simultaneous breakdown of large areas of membrane [12, 13]. Here, we have shown that developmental cell fusion is indeed consistent with initiation by a virus-like, pore-forming mechanism. We examined live cell fusions in the epithelia of Caenorhabditis elegans embryos by a new method that integrates multiphoton, confocal, and electron microscopy. The fusion aperture always originated at a single point restricted to the apical adherens junction and widened slowly as a radial wavefront. The fusing membranes dispersed by vesiculation, rather than simple unfolding of the conjoined double bilayer. Thus, in these cells fusion appears to require two specialized sequential processes: formation of a unique primary pore and expansion of the opening by radial internalization of the interacting cell membranes.

Stereo-4-D reconstruction and animation from living fluorescent specimens

We present a novel approach to the viewing and analysis of 4-dimensional (4-D) data sets recorded from live fluorescent samples. With stereo-4-D reconstructions, the observer manipulates a rotatable projection of the full 3-dimensional (3-D) specimen while simultaneously controlling animation of the recording forward or backward in time. The result is a unique lifelike perspective on the development of an entire living subject. Here, we apply this technique to the observation of the cell membranes of developing Caenorhabditis elegans. Embryos labeled with the vital plasma membrane probe FM 4-64 were imaged by multiphoton laser scanning fluorescence microscopy, yielding 4-D data sets of entire embryos over several hours of development. Stereo 4-D and standard focal-plane 4-D viewing of these novel time-lapse recordings provide the observer with detail at both the subcellular and whole-animal level from a single data set and produce a unique record of the lineage, cell shape changes, cell contacts and morphogenetic dynamics that make up embryogenesis. The procedures by which stereo-4-D reconstructions are created and viewed rely on public domain software running on a personal computer and should therefore be accessible by a general audience. Data output utilizes the versatile and well-supported QuickTime animation format. Additional features allow for stereo-4-D reconstruction of isolated 3-D volumes of interest from within the larger specimen.

Fusion competence of myoblasts rendered genetically null for N-cadherin in culture

Myoblast fusion is essential to muscle tissue development yet remains poorly understood. N-cadherin, like other cell surface adhesion molecules, has been implicated by others in muscle formation based on its pattern of expression and on inhibition of myoblast aggregation and fusion by antibodies or peptide mimics. Mice rendered homozygous null for N-cadherin revealed the general importance of the molecule in early development, but did not test a role in skeletal myogenesis, since the embryos died before muscle formation. To test genetically the proposed role of N-cadherin in myoblast fusion, we successfully obtained N-cadherin null primary myoblasts in culture. Fusion of myoblasts expressing or lacking N-cadherin was found to be equivalent, both in vitro by intracistronic complementation of lacZ and in vivo by injection into the muscles of adult mice. An essential role for N-cadherin in mediating the effects of basic fibroblast growth factor was also excluded. These methods for obtaining genetically homozygous null somatic cells from adult tissues should have broad applications. Here, they demonstrate clearly that the putative fusion molecule, N-cadherin, is not essential for myoblast fusion.

Genetic analysis of alpha 4 integrin functions in the development of mouse skeletal muscle

It has been suggested, on the basis of immunolocalization studies in vivo and antibody blocking experiments in vitro, that alpha 4 integrins interacting with vascular cell adhesion molecule 1 (VCAM-1) are involved in myogenesis and skeletal muscle development. To test this proposal, we generated embryonic stem (ES) cells homozygous null for the gene encoding the alpha 4 subunit and used them to generate chimeric mice. These chimeric mice showed high contributions of alpha 4-null cells in many tissues, including skeletal muscle, and muscles lacking any detectable (< 2%) alpha 4-positive cells did not reveal any gross morphological abnormalities. Furthermore, assays for in vitro myogenesis using either pure cultures of alpha 4-null myoblasts derived from the chimeras or alpha 4-null ES cells showed conclusively that alpha 4 integrins are not essential for muscle cell fusion and differentiation. Taking these results together, we conclude that alpha 4 integrins appear not to play essential roles in normal skeletal muscle development.

Gene expression and cell fusion analyzed by lacZ complementation in mammalian cells

Complementing reporter genes provide biological indicators of coincident expression of proteins in cells. We have adapted intracistronic complementation of the Escherichia coli lacZ gene for use in mammalian cells. Enzymatic activity detectable by quantitative biochemical assay, flow cytometry, or microscopy is produced upon convergent expression of two distinct mutant lacZ peptides within single cells, or upon fusion of cells expressing such mutants. A novel fluorescent substrate for beta-galactosidase (Fluor-X-Gal) increases detection and permits simultaneous microscopic visualization of other fluorescent markers. The enzymatic complementation described here should facilitate studies of cell fusion, cell lineage, and signal transduction, by producing activity only when two proteins are expressed at the same time and place in intact cells.

Spectrophotometric quantitation of tissue culture cell number in any medium

We have developed a spectrophotometric assay for cell number in suspensions of tissue culture cells. For each cell type tested, absorbance between 650 and 800 nm is linearly dependent upon cell density over a 50-fold range and is independent of the color or composition of the medium in which cells are suspended. A standard curve of absorbance vs. cell density is used to estimate cell number with accuracy and reproducibility superior to hemacytometer counting and with speed and ease surpassing use of a Coulter counter. Less than 5000 cells are needed for this quantitation. The same cells that are counted can be maintained live in culture after the reading is taken, thus allowing the growth of cells to be measured within individual cultures over time. The assay should be readily extended to assays of cell number directly within microplate culture wells. The spectrophotometric assay described here is of significant use in all experiments requiring rapid, accurate measurements of cell number, including determinations of cell doubling time and equal plating of parallel cultures.

Membrane-bound neomycin phosphotransferase confers drug-resistance in mammalian cells: a marker for high-efficiency targeting of genes encoding secreted and cell-surface proteins

An efficient method for inactivating genes is the use of silent selectable markers that are expressed only after homologous recombination into the active target gene. However, use of this approach for genes encoding secreted or membrane-anchored proteins may produce hybrid proteins comprising the N-terminal signal sequence from the target gene linked to the protein conferring drug resistance. Such chimeric enzymes will be secreted, precluding selection for drug resistance. To overcome this problem, we tested the possibility of anchoring in the membrane the cytoplasmic neomycin phosphotransferase (NPT). We constructed a fusion gene with a transmembrane domain connecting the N-terminal signal sequence of a membrane-targeted protein and the neo gene. Expression of this gene yielded G418-resistant colonies of C2C12 cells which contained assayable NPT activity. Comparison of enzyme activity in cell extract fractions verified that the active fusion protein was insoluble, presumably through localization to a membrane compartment. Transmembrane neo cassettes should serve as integration-activated markers capable of targeting genes encoding secreted or cell surface proteins.

Molecular cloning of mevalonate kinase and regulation of its mRNA levels in rat liver

Mevalonate kinase [ATP:(R)-mevalonate 5-phosphotransferase, EC 2.7.1.36] may be a regulatory site in the cholesterol biosynthetic pathway, and a mutation in the gene coding for this enzyme is thought to cause the genetic disease mevalonic aciduria. To characterize this enzyme, a rat liver cDNA library was screened with a monospecific antibody, and a 1.7-kilobase cDNA clone coding for mevalonate kinase was isolated. The complete DNA sequence was determined, and the longest open reading frame coded for a protein containing 395 amino acids with a deduced molecular weight of 41,990. Identification of the cDNA clone was confirmed by expression of enzyme activity in yeast and by protein sequence data obtained from sequencing purified rat mevalonate kinase. The deduced amino acid sequence of mevalonate kinase contained a motif for the ATP-binding site found in protein kinases, and it also showed sequence homology to the yeast RAR1 protein. The size of mevalonate kinase mRNA in rat liver was approximately 2 kilobases. Treatment with diets containing cholesterol-lowering agents caused an increase in both mevalonate kinase activity and mRNA levels, whereas diets containing 5% cholesterol lowered the levels of both enzyme activity and mRNA. These data indicate that long-term regulation of enzyme activity in rat liver is controlled by changes in the levels of mevalonate kinase mRNA.