DNA replication defects delay cell division and disrupt cell polarity in early Caenorhabditis elegans embryos.

In early Caenorhabditis elegans embryos, asymmetric cell divisions produce descendants with asynchronous cell cycle times. To investigate the relationship between cell cycle regulation and pattern formation, we have identified a collection of embryonic-lethal mutants in which cell divisions are delayed and cell fate patterns are abnormal. In div (for division delayed) mutant embryos, embryonic cell divisions are delayed but remain asynchronous. Some div mutants produce well-differentiated cell types, but they frequently lack the endodermal and mesodermal cell fates normally specified by a transcriptional activator called SKN-1. We show that mislocalization of PIE-1, a negative regulator of SKN-1, prevents the specification of endoderm and mesoderm in div-1 mutant embryos. In addition to defects in the normally asymmetric distribution of PIE-1, div mutants also exhibit other losses of asymmetry during early embryonic cleavages. The daughters of normally asymmetric divisions are nearly equal in size, and cytoplasmic P-granules are not properly localized to germline precursors in div mutant embryos. Thus the proper timing of cell division appears to be important for multiple aspects of asymmetric cell division. One div gene, div-1, encodes the B subunit of the DNA polymerase alpha-primase complex. Reducing the function of other DNA replication genes also results in a delayed division phenotype and embryonic lethality. Thus the other div genes we have identified are likely to encode additional components of the DNA replication machinery in C. elegans.

The aurora-related kinase AIR-2 recruits ZEN-4/CeMKLP1 to the mitotic spindle at metaphase and is required for cytokinesis.

BACKGROUND: The Aurora/Ipl1p-related kinase AIR-2 is required for mitotic chromosome segregation and cytokinesis in early Caenorhabditis elegans embryos. Previous studies have relied on non-conditional mutations or RNA-mediated interference (RNAi) to inactivate AIR-2. It has therefore not been possible to determine whether AIR-2 functions directly in cytokinesis or if the cleavage defect results indirectly from the failure to segregate DNA. One intriguing hypothesis is that AIR-2 acts to localize the mitotic kinesin-like protein ZEN-4 (also known as CeMKLP1), which later functions in cytokinesis. RESULTS: Using conditional alleles, we established that AIR-2 is required at metaphase or early anaphase for normal segregation of chromosomes, localization of ZEN-4, and cytokinesis. ZEN-4 is first required late in cytokinesis, and also functions to maintain cell separation through much of the subsequent interphase. DNA segregation defects alone were not sufficient to disrupt cytokinesis in other mutants, suggesting that AIR-2 acts specifically during cytokinesis through ZEN-4. AIR-2 and ZEN-4 shared similar genetic interactions with the formin homology (FH) protein CYK-1, suggesting that AIR-2 and ZEN-4 function in a single pathway, in parallel to a contractile ring pathway that includes CYK-1. Using in vitro co-immunoprecipitation experiments, we found that AIR-2 and ZEN-4 interact directly. CONCLUSIONS: AIR-2 has two functions during mitosis: one in chromosome segregation, and a second, independent function in cytokinesis through ZEN-4. AIR-2 and ZEN-4 may act in parallel to a second pathway that includes CYK-1.

Metaphase to anaphase (mat) transition-defective mutants in Caenorhabditis elegans.

The metaphase to anaphase transition is a critical stage of the eukaryotic cell cycle, and, thus, it is highly regulated. Errors during this transition can lead to chromosome segregation defects and death of the organism. In genetic screens for temperature-sensitive maternal effect embryonic lethal (Mel) mutants, we have identified 32 mutants in the nematode Caenorhabditis elegans in which fertilized embryos arrest as one-cell embryos. In these mutant embryos, the oocyte chromosomes arrest in metaphase of meiosis I without transitioning to anaphase or producing polar bodies. An additional block in M phase exit is evidenced by the failure to form pronuclei and the persistence of phosphohistone H3 and MPM-2 antibody staining. Spermatocyte meiosis is also perturbed; primary spermatocytes arrest in metaphase of meiosis I and fail to produce secondary spermatocytes. Analogous mitotic defects cause M phase delays in mitotic germline proliferation. We have named this class of mutants "mat" for metaphase to anaphase transition defective. These mutants, representing six different complementation groups, all map near genes that encode subunits of the anaphase promoting complex or cyclosome, and, here, we show that one of the genes, emb-27, encodes the C. elegans CDC16 ortholog.

MAP kinase and Wnt pathways converge to downregulate an HMG-domain repressor in Caenorhabditis elegans.

The signalling protein Wnt regulates transcription factors containing high-mobility-group (HMG) domains to direct decisions on cell fate during animal development. In Caenorhabditis elegans, the HMG-domain-containing repressor POP-1 distinguishes the fates of anterior daughter cells from their posterior sisters throughout development, and Wnt signalling downregulates POP-1 activity in one posterior daughter cell called E. Here we show that the genes mom-4 and lit-1 are also required to downregulate POP-1, not only in E but also in other posterior daughter cells. Consistent with action in a common pathway, mom-4 and lit-1 exhibit similar mutant phenotypes and encode components of the mitogen-activated protein kinase (MAPK) pathway that are homologous to vertebrate transforming-growth-factor-beta-activated kinase (TAK1) and NEMO-like kinase (NLK), respectively. Furthermore, MOM-4 and TAK1 bind related proteins that promote their kinase activities. We conclude that a MAPK-related pathway cooperates with Wnt signal transduction to downregulate POP-1 activity. These functions are likely to be conserved in vertebrates, as TAK1 and NLK can downregulate HMG-domain-containing proteins related to POP-1.

Purification of a WD repeat protein, EMAP, that promotes microtubule dynamics through an inhibition of rescue.

The major microtubule-associated protein in echinoderms is a 77-kDa, WD repeat protein, called EMAP. EMAP-related proteins have been identified in sea urchins, starfish, sanddollars, and humans. We describe the purification of sea urchin EMAP and demonstrate that EMAP binding to microtubules is saturable at a molar ratio of 1 mol of EMAP to 3 mol of tubulin dimer. Unlike MAP-2, MAP-4, or tau proteins, EMAP binding to microtubules is not lost by cleavage of tubulin with subtilisin. In addition to binding to the microtubule polymer, EMAP binds to tubulin dimers in a 1:1 molar ratio. The abundance of EMAP in the egg suggests that it could function to regulate microtubule assembly. To test this hypothesis, we examined the effects of EMAP on the dynamic instability of microtubules nucleated from axoneme fragments as monitored by video-enhanced differential interference contrast microscopy. Addition of 2.2 microM EMAP to 21 microM tubulin results in a slight increase in the elongation and shortening velocities at the microtubule plus ends but not at the minus ends. Significantly, EMAP inhibits the frequency of rescue 8-fold without producing a change in the frequency of catastrophe. These results indicate that EMAP, unlike brain microtubule-associated proteins, promotes microtubule dynamics.

Characterization of the sea urchin major vault protein: a possible role for vault ribonucleoprotein particles in nucleocytoplasmic transport.

Vaults are large ribonucleoprotein particles that have been identified in a wide range of eukaryotic organisms. Although present in thousands of copies per cell, their function remains unknown. In this report, we identify the major vault protein in sea urchins as a 107-kDa polypeptide that copurifies with microtubules and ribosomes. Although initially identified in microtubule preparations, the sea urchin major vault protein is not predominantly microtubule-associated in vivo. Rather, the sea urchin major vault protein is present throughout the cytoplasm in eggs and embryos and in the nucleus in adult somatic cells. Within the nucleus, the sea urchin major vault protein is concentrated in the region of the nucleolus and to punctate regions of the nuclear envelope. In addition, the vault protein localizes to short linear strings juxtaposed to the exterior of the nucleus and extending outward into the cytoplasm. Based on their copurification and intracellular distribution, vaults may be involved in the nucleocytoplasmic transport of ribosomes and/or mRNA.

Identification and characterization of lipopolysaccharide-binding proteins on human peripheral blood cell populations.

Previous research in this laboratory, using photoactivatable radioiodinated lipopolysaccharide derivatized with sulfosuccinimidyl-2-(p-azidosalicylamide)-1,3'-dithiopropionate (125I-ASD-LPS), has resulted in the identification of a specific LPS receptor with a molecular mass of approximately 73 kDa on murine lymphocytes and splenic macrophages. The experiments presented in this report investigated whether a similar LPS-binding protein was also expressed on human peripheral blood populations, including monocytes, lymphocytes, neutrophils, platelets, and erythrocytes. Each cell population was incubated with 125I-ASD-LPS, UV irradiated, washed, reduced, and solubilized, and the cell lysates were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis followed by autoradiography. On all of the cell populations, except erythrocytes, a similar 73-kDa LPS-binding protein was present. In addition, each population also expressed lower-molecular-weight secondary LPS-binding proteins, some of which were conserved among the populations. Binding of the photoactivatable LPS probe was found to be both time and temperature dependent. These data support the concept that the 73-kDa LPS-binding protein is conserved on multiple cell types from a variety of species.

Effect of the spin trap 5,5 dimethyl-1-pyrroline-N-oxide (DMPO) on human neutrophil function: novel inhibition of neutrophil stimulus-response coupling?

Previously we had utilized the spin trap 5,5 dimethyl-1-pyrroline-N-oxide (DMPO) to detect superoxide (.O2-) formation by human neutrophils stimulated with phorbol myristate acetate (PMA) or opsonized zymosan. When N-formyl-methionyl-leucyl-phenylalanine (FMLP) or concanavalin A were substituted as the neutrophil stimulus spin trap evidence of neutrophil free radical production was not detected. Consequently, the hypothesis that DMPO interfered with neutrophil stimulus response coupling was examined. DMPO exhibited a concentration-related inhibition of neutrophil .O2- secretion (ferricytochrome C reduction) following exposure to six different stimuli. The extent of inhibition was stimulus dependent--large (FMLP, concanavalin A), moderate (PMA, opsonized zymosan, A23187), and mild (arachidonic acid). Inhibition was reversible. Onset was nearly instantaneous and was observed even if DMPO was added after stimulus-induced .O2- formation was ongoing. DMPO had only minimal effect on .O2- production by a cell-free NADPH-oxidase membrane preparation. DMPO also inhibited the neutrophil degranulation response for elastase and lactoferrin but not vitamin B12 binding protein. DMPO-mediated inhibition of neutrophil function was not related to alteration in stimulus binding (FMLP or concanavalin A). DMPO had minimal impact on the stimulus-induced rise in intracellular calcium. However, the presence of DMPO resulted in a concentration-dependent depolarization of the resting neutrophil membrane and blunting of the depolarization response to each stimulus examined. These data are of importance to investigators applying spin-trapping techniques to phagocytic cells and suggest DMPO could be used as a tool for investigating neutrophil stimulus-response mechanisms.

Neutrophil degranulation inhibits potential hydroxyl-radical formation. Relative impact of myeloperoxidase and lactoferrin release on hydroxyl-radical production by iron-supplemented neutrophils assessed by spin-trapping techniques.

Hydroxyl radical (.OH) formation by neutrophils in vitro requires exogenous iron. Two recent studies [Britigan, Rosen, Thompson, Chai & Cohen (1986) J. Biol. Chem. 261, 17026-17032; Winterbourn (1987) J. Clin. Invest. 78, 545-550] both reported that neutrophil degranulation could potentially inhibit the formation of .OH, but differed in their conclusions as to the responsible factor, myeloperoxidase (MPO) or lactoferrin (LF). By using a previously developed spin-trapping system which allows specific on-line detection of superoxide anion (O2-) and .OH production, the impact of MPO and LF release on neutrophil .OH production was compared. When iron-diethylenetriaminepenta-acetic acid-supplemented neutrophils were stimulated with phorbol myristate acetate or opsonized zymosan, .OH formation occurred, but terminated prematurely in spite of continued O2- generation. Inhibition of MPO by azide increased the magnitude, but not the duration, of .OH formation. No azide effect was noted when MPO-deficient neutrophils were used. Anti-LF antibody increased both the magnitude and duration of .OH generation. Pretreatment of neutrophils with cytochalasin B to prevent phagosome formation did not alter the relative impact of azide or anti-LF on neutrophil .OH production. An effect of azide or anti-LF on spin-trapped-adduct stability was eliminated as a confounding factor. These data indicate that neutrophils possess two mechanisms for limiting .OH production. Implications for neutrophil-derived oxidant damage are discussed.

The interaction of 5,5-dimethyl-1-pyrroline-N-oxide with human myeloperoxidase and its potential impact on spin trapping of neutrophil-derived free radicals.

Activation of human neutrophils leads to secretion of myeloperoxidase (MPO) with resulting generation of several oxidant species including OCl-. Spin trapping techniques employing 5,5-dimethyl-1-pyrroline-N-oxide (DMPO) are being applied increasingly to the investigation of free radical production by in vitro and in vivo experimental systems which contain neutrophils. Because such knowledge is critical to the interpretation of these data, we examined the impact of MPO and MPO-derived oxidants on DMPO spin adduct formation and stability. Addition of increasing concentrations of OCl- to DMPO yielded a number of EPR-detectable products including DMPO-OH. However, the concentration of OCl- required was in excess of that expected under physiologic conditions. Addition of purified human MPO and H2O2 to DMPO yielded EPR spectra consisting of small DMPO-OH peaks. The addition of MPO and H2O2 to preformed DMPO-OH and DMPO-CH3 resulted in rapid destruction of these spin adducts. Thus MPO/H2O2 appeared to both generate and destroy DMPO spin adducts. Neutrophils stimulated with phorbol myristate acetate or opsonized zymosan generated large DMPO-OOH and DMPO-OH peaks as well as small DMPO-CH3 peaks. Addition of the MPO inhibitor azide to the reaction mixture had no effecting on resulting DMPO-OH or DMPO-CH3 peak amplitudes but increased that of DMPO-OOH. These data suggest that MPO-derived oxidants likely have little impact on the nature of EPR spectra resulting from DMPO spin trapping of free radical species following neutrophil stimulation. Because MPO oxidants did appear to react with DMPO the ability of DMPO to protect a biologic target from in vitro MPO injury was examined. DMPO (greater than 10 mM) significantly decreased MPO/H2O2/Cl- -mediated erythrocyte hemolysis as assessed by 51Cr release. The experimental and/or pharmacologic implications of this observation require further study.