Cooperative regulation of AJM-1 controls junctional integrity in Caenorhabditis elegans epithelia.

The function of epithelial cell sheets depends on the integrity of specialized cell-cell junctions that connect neighbouring cells. We have characterized the novel coiled-coil protein AJM-1, which localizes to an apical junctional domain of Caenorhabditis elegans epithelia basal to the HMR-HMP (cadherin-catenin) complex. In the absence of AJM-1, the integrity of this domain is compromised. Proper AJM-1 localization requires LET-413 and DLG-1, homologues of the Drosophila tumour suppressors Scribble and Discs large, respectively. DLG-1 physically interacts with AJM-1 and is required for its normal apical distribution, and LET-413 mediates the rapid accumulation of both DLG-1 and AJM-1 in the apical domain. In the absence of both dlg-1 and let-413 function AJM-1 is almost completely lost from apical junctions in embryos, whereas HMP-1 (alpha-catenin) localization is only mildly affected. We conclude that LET-413 and DLG-1 cooperatively control AJM-1 localization and that AJM-1 controls the integrity of a distinct apical junctional domain in C. elegans.

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.

Transgenes encoding both type I and type IV c-abl proteins rescue the lethality of c-abl mutant mice.

Mice carrying homozygous mutations in the c-abl gene (abl-(m1) or abl2) exhibit severe, though variable phenotypes, including a high rate of postnatal mortality, runting, morphological abnormalities, a susceptibility to infections, and selected immune system defects. To further determine the role of the c-Abl protein in vivo, we have generated three lines of mice expressing c-abl transgenes. These minigenes encode the two major forms of the c-abl gene product (c-Abl types I and IV) and a kinase defective type IV c-Abl. The transgenic lines, in Abl-positive genetic backgrounds, were phenotypically almost indistinguishable from their non-transgene littermates and expressed the c-abl transgene in a variety of tissues at levels comparable to that of the endogenous c-abl gene. When the transgenes were introduced into a mutant c-abl strain by mating, the mutant c-abl phenotype was almost completely rescued by either of the c-abl type I or type IV transgenes, but not by the kinase-defective transgene. These findings suggest that either of the two alternatively spliced c-abl gene products can provide the in vivo functions of c-Abl, and that these functions are dependent on kinase activity.

A role for c-Abl in c-myc regulation.

c-Abl, a nonreceptor tyrosine kinase, appears to play a role in cell cycle progression, cell proliferation and differentiation. Mice homozygous for a mutation in c-abl (ablml), show pleiotropic abnormalities, including neonatal death, developmental defects, susceptibility to infection and dehydration (Schwartzberg et al., 1991). However, the exact substrates of c-Abl and the signal transduction pathways it might initiate are not known. We have examined how c-Abl affects c-myc expression by studying ablml mice. Quantitative riboprobe analyses demonstrated that in the heart, liver, thymus, brain, testes, intestines and lung, there were no differences in the steady-state level of c-myc RNA between the ablml mice and littermate controls. However, in adrenal glands, kidneys and splenic B cells, c-myc RNA levels were decreased approximately 50% compared to littermate controls. Induction of c-myc mRNA following activation of splenic B cells with LPS is also defective in ablml splenocytes. Finally, we show that c-Abl can directly transactivate c-myc transcription. These results suggest that c-Abl is involved in the normal transcription regulation of c-myc in selected tissues and that decreased c-myc RNA could be one cause of abnormalities in the ablml mice.

Archenteron elongation in the sea urchin embryo is a microtubule-independent process.

Earlier studies using colchicine (L. G. Tilney and J. R. Gibbins, 1969, J. Cell Sci. 5, 195-210) had suggested that intact microtubules (MTs) are necessary for archenteron elongation during the second phase of sea urchin gastrulation (secondary invagination), presumably by allowing secondary mesenchyme cells (SMCs) to extend their long filopodial processes. In light of subsequently discovered effects of colchicine on other cellular processes, the role of MTs in archenteron elongation in the sea urchin, Lytechinus pictus, has been reexamined. Immunofluorescent staining of ectodermal fragments and isolated archenterons reveals a characteristic pattern of MTs in the ectoderm and endoderm during gastrulation. Ectodermal cells exhibit arrays of MTs radiating away from the region of the basal body/ciliary rootlet and extending along the periphery of the cell, whereas endodermal cells exhibit a similar array of peripheral MTs emanating from the region of the apical ciliary rootlet facing the lumen of the archenteron. MTs are found primarily at the bases of the filopodia of normal SMCs. beta-Lumicolchicine (0.1 mM), an analog of colchicine which does not bind tubulin, inhibits secondary invagination, indicating that the effects previously ascribed to the disruption of MTs are probably due to the effects of colchicine on other cellular processes. The MT inhibitor nocodazole (5-10 micrograms/ml) added prior to secondary invagination does not prevent gastrulation or spontaneous exogastrulation, even though indirect immunofluorescence indicates that cytoplasmic MTs are completely disrupted in drug-treated embryos. Transverse tissue sections indicate that a comparable amount of cell rearrangement occurs in nocodazole-treated and control embryos. Significantly, SMCs in nocodazole-treated embryos often detach prematurely from the tip of the gut rudiment and extend abnormally large broad lamellipodial protrusions but are also capable of extending long slender filopodia comparable in length to those of control embryos. These results indicate that cytoplasmic MTs are not essential for either filopodial extension by SMCs or for the active epithelial cell rearrangement which accompanies elongation during sea urchin gastrulation.

Targeted disruption of the flk2/flt3 gene leads to deficiencies in primitive hematopoietic progenitors.

The flk2 receptor tyrosine kinase has been implicated in hematopoietic development. Mice deficient in flk2 were generated. Mutants developed into healthy adults with normal mature hematopoietic populations. However, they possessed specific deficiencies in primitive B lymphoid progenitors. Bone marrow transplantation experiments revealed a further deficiency in T cell and myeloid reconstitution by mutant stem cells. Mice deficient for both c-kit and flk2 exhibited a more severe phenotype characterized by large overall decreases in hematopoietic cell numbers, further reductions in the relative frequencies of lymphoid progenitors, and a postnatal lethality. Taken together, the data suggest that flk2 plays a role both in multipotent stem cells and in lymphoid differentiation.

Bone marrow B lymphocyte development in c-abl-deficient mice.

Mice homozygous for a mutation in the c-abl tyrosine kinase gene have multiple defects including high postnatal mortality, runting, morphological abnormalities, susceptibility to infections, and reductions in lymphocytes and their precursors. FACS analysis of bone marrow from mutant mice demonstrates variable reductions in pro-B and pre-B cells. While the numbers of cells in these populations are profoundly reduced in some mutants (16 and 1.2% of control pro-B and pre-B cells, respectively), normal levels are found in other individuals. In the affected mutants, some reductions are observed in many stages of B cell development. The response of B cell precursors to the cytokine interleukin-7 is variably affected while that of several other cytokines (stem cell factor, interleukin-3, GM-CSF, G-CSF, and erythropoietin) is normal in c-abl mutants. The population defects caused by the c-abl mutation can be recreated in normal mice by the transfer of adult bone marrow but, surprisingly, not fetal liver. These studies demonstrate that c-Abl signaling pathways may play a role in the earliest stages of B cell development in a developmental stage-specific manner. In spite of these variable abnormalities, however, the hemopoietic system of c-abl mutant animals is surprisingly intact.

Abnormal peripheral lymphocyte function in c-abl mutant mice.

The proto-oncogene c-abl encodes a tyrosine kinase that is hypothesized to function in proliferation-stimulatory signaling pathways. Previous work on mice homozygous for targeted mutations in the c-abl gene (ablml and abl2 mutant strains) has demonstrated multiple defects, including a susceptibility to infections that results in a high mortality rate after weaning. FACS analysis of the hemopoietic system of c-abl mutants demonstrated variable reductions in B and T lymphocytes in adult bone marrow, thymus, spleen, and peripheral blood. In addition, bone marrow from mutants showed a decreased ability to respond to interleukin-7. We further found that B cells from ablm1 mice had a reduced ability to respond to lipopolysaccharide (decreased to 10% of control response) that was dependent on the culture conditions and the tissue of origin of B cells. Peripheral blood from the mutants also had a reduced response to the T cell mitogen concanavalin A. Immune response in ablm1 mice as determined by the mixed lymphocyte response and the sheep red blood cell plaque-forming assay was grossly normal. These findings suggest that although specific signaling pathways in lymphocytes may involve c-Abl, the immune system can function in the absence of a normal c-abl gene product.

Mice homozygous for the ablm1 mutation show poor viability and depletion of selected B and T cell populations.

The c-abl gene, originally identified as the cellular homolog of the transforming gene of the Abelson murine leukemia virus, encodes a protein-tyrosine kinase of unknown function that is expressed in all mammalian tissues. We have previously described the introduction of a mutation in the c-abl gene into the mouse germline via targeted gene disruption of embryonic stem cells. We now show that mice homozygous for this mutation are severely affected, displaying increased perinatal mortality, runtedness, and abnormal spleen, head, and eye development. We have examined components of the immune system and have found major reductions in B cell progenitors in the adult bone marrow, with less dramatic reductions in developing T cell compartments.