Cytoplasmic Partitioning Research Articles

T Cell Receptor Signaling: Beyond Complex Complexes

The adaptive phase of the immune response begins with engagement on CD4 + helper T cells of the T cell antigen receptor (TCR) 1 by its ligand, a small foreign peptide bound to a cell surface protein of the class II major histocompatibility complex (peptide-MHC) expressed on an antigen-presenting cell. This engagement initiates a series of biochemical events that can differentially signal the naive T cell to: 1) enter into a pathway leading to generation of effector T cells with the onset of rapid proliferation and production of effector cytokines; 2) enter into a state of antigenic non-responsiveness known as anergy; or 3) die by apoptosis. The type of response elicited depends on multiple factors including the affinity of the interaction, the duration of the interaction, and the presence or absence of various costimulatory signaling inputs such as those provided by the CD4 coreceptor and the CD28 costimulatory receptor. In this review we provide an overview of the signaling events that are associated with the first of these outcomes: T cell activation. To present an overview of sufficiently broad scope, the depth of discussion of each aspect ofTCR signaling is by necessity limited, and the reader is referred to the reviews cited throughout this text for consideration of these events in more detail.

Manipulation of gene expression in megakaryocytes.

The process of megakaryocyte generation in the bone marrow and subsequent differentiation leading to platelet production is little understood. Known as megakaryo-poiesis, it involves a number of unique biological features, including an increase in the nuclear DNA content (endoreplication) and partitioning of cytoplasm and membranes into platelets. Abnormalities of thrombosis and hemostasis can occur as a result of alterations in the number of platelets generated and maintained in the circulation or through aberrations in the functional behavior of the platelet itself. Although some of these abnormalities are most likely indirect in their etiology (for example, immune thrombocytopenias), many are directly linked to an inherited or acquired genetic effect operating at some point during megakaryopoiesis. Inherited mutations affecting megakaryocytes and platelets are relatively rare, although there is increasing interest in the association between genetic polymorphisms in platelet proteins that have no profound phenotype but may be linked to an increased thrombotic risk. Specific genetic changes leading to deregulation of proliferation and/or differentiation at some point during megakaryopoiesis are also implicated in several acquired conditions, including leukemias, preleukemic states, and dysplasias.

Regulation of poly(A) polymerase by 14-3-3epsilon.

Poly(A) polymerase (PAP) is a key enzyme responsible for the addition of the poly(A) at the 3' end of pre-mRNA. The C-terminal region of mammalian PAP carries target sites for protein-protein interaction with the 25 kDa subunit of cleavage factor I and with splicing factors U1A and U2AF65. We used a yeast two-hybrid screen to identify 14-3-3epsilon as an additional protein binding to the C-terminal region of PAP. Interaction between PAP and 14-3-3epsilon was confirmed by both in vitro and in vivo binding assays. This interaction is dependent on PAP phosphorylation. Deletion analysis of PAP suggests that PAP contains multiple binding sites for 14-3-3epsilon. The binding of 14-3-3epsilon to PAP inhibits the polyadenylation activity of PAP in vitro, and overexpression of 14-3-3epsilon leads to a shorter poly(A) mRNA tail in vivo. In addition, the interaction between PAP and 14-3-3epsilon redistributes PAP within the cell by increasing its cytoplasmic localization. These data suggest that 14-3-3epsilon is involved in regulating both the activity and the nuclear/ cytoplasmic partitioning of PAP through the phosphorylation-dependent interaction.

The Caenorhabditis elegans spe-39 gene is required for intracellular membrane reorganization during spermatogenesis.

Caenorhabditis elegans spermatid formation involves asymmetric partitioning of cytoplasm during the second meiotic division. This process is mediated by specialized ER/Golgi-derived fibrous body-membranous organelles (FB-MOs), which have a fibrous body (FB) composed of bundled major sperm protein filaments and a vesicular membranous organelle (MO). spe-39 mutant spermatocytes complete meiosis but do not usually form spermatids. Ultrastructural examination of spe-39 spermatocytes reveals that MOs are absent, while FBs are disorganized and not surrounded by the membrane envelope usually observed in wild type. Instead, spe-39 spermatocytes contain many small vesicles with internal membranes, suggesting they are related to MOs. The spe-39 gene was identified and it encodes a novel hydrophilic protein. Immunofluorescence with a specific SPE-39 antiserum reveals that it is distributed through much of the cytoplasm and not specifically associated with FB-MOs in spermatocytes and spermatids. The spe-39 gene has orthologs in Drosophila melanogaster and humans but no homolog was identified in the yeast genome. This suggests that the specialized membrane biogenesis steps that occur during C. elegans spermatogenesis are part of a conserved process that requires SPE-39 homologs in other metazoan cell types.

PDZ domain polarity complexes

What are they? Three protein complexes, each containing at least one PDZ protein–protein interaction domain, are critical regulators of cell polarity in animals. Each complex can be referred to by one of its primary components: the Par-3 or Baz complex, including Par-6 and aPKC; the Crb complex, including Sdt; and the Scrib complex, including Dlg. The Lgl protein, which has activities similar to the Scrib complex, seems to physically associate not with the Scrib but with the Baz complex. Are they conserved across species? Yes: orthologous complexes are found in worms, flies and vertebrates. Not only is the composition of the complexes conserved, but there is also remarkable conservation of their localization, particularly in epithelial cells. Nevertheless, the mutant phenotypes caused by defects in components of the complexes vary across species, suggesting that the story may be more complicated. How were they identified? Primarily through genetic screens in model organisms. Mutations of Crb, Sdt and Baz cause polarity defects in Drosophila embryonic epithelia, while those of Par-3 and Par-6 disrupt cytoplasmic partitioning in the early Caenorhabditis elegans zygote. A mammalian Par-3 homolog physically associates with aPKC, while Baz is the fly Par-3 homolog. Dlg and Lgl were first isolated as Drosophila tumor suppressors that cause overgrowth and disorganization of imaginal epithelia. Scrib and its worm ortholog Let-413 were identified in screens for epithelial shape defects. What cells are they active in? All three complexes are required for polarization of the Drosophila embryonic and ovarian epithelia, though some fly epithelia that require the Scrib complex, such as wing imaginal discs, develop well without either the Crb or Baz complex. Worm epithelia require the Scrib complex; requirements for the Baz and Crb complexes have not yet been reported. In zebrafish, mutations in aPKC and Sdt homologs cause disorganization of certain endodermal, mesodermal and retinal epithelia. Outside of epithelia, the Baz and Scrib complexes are both involved in polarization of Drosophila neuroblasts and, later, in organization of the neuromuscular junction. Finally, the Baz complex is required for polarization of both the one-cell worm zygote and the Drosophila oocyte. Where are they found in the cell? In epithelial tissues, the Crb complex is found along the apical-most region of the lateral plasma membrane, corresponding to the tight junction in vertebrates or the marginal zone in Drosophila. The Baz complex is found at either the tight junction or the zonula adherens, while the Scrib complex is found along the basolateral domain. In the fly neuroblast and worm zygote, the Baz complex is polarized along one side of the cell (apical or posterior, respectively). The Scrib complex is localized throughout the cortex of fly neuroblasts. In mature neurons, Scrib and Baz are restricted to synapses. Lgl is broadly associated throughout the cell membrane in most cell types. Do the complexes interact? The three complexes can coordinate polarizing activities through positive and negative cross-regulation, as shown in the fly embryo. This regulation may be mediated by physical interactions amongst members of different complexes, such as that between the mammalian Par-6 and Sdt orthologs. A particularly intriguing case is Lgl, which physically interacts with the Baz complex but whose subcellular localization is controlled by the Scrib complex. How do they function in polarity? The mechanism by which the complexes mediate polarity at the cell biological level is not understood. The PDZ proteins act as scaffolds, without clear effector activities. It is suspected that polarizing activity is mediated by effector partners, such as the kinase aPKC and its substrate Lgl, which may be involved in vesicle transport or cytoskeletal regulation. Other effector partners, particularly those that interface with basic cell biological machinery, remain to be identified. Might they be involved in human disease? Mutations in a human Crb gene, CRB1, cause retinal degeneration in one class of retinitis pigmentosa patients. Indirect evidence hints at a role of the complexes in oncogenesis: Par-6 can potentiate transformation, while Scrib complex proteins are targets of oncovirus-mediated protein degradation. A third possibility is raised by the circletail mutant mouse, which carries a mutation in Scrib and displays severe neural tube defects. Further implication of the PDZ polarity complexes in developmental or pathological defects awaits reverse genetic approaches in vertebrate organisms. Where can I find out more?

Unusual cytological patterns of microsporogenesis in Brachiaria decumbens: abnormalities in spindle and defective cytokinesis causing precocious cellularization.

Cytogenetic studies carried out in the tetraploid accession BRA001068 of Brachiaria decumbens, also known as cv. Basilisk, revealed an unusual pattern of microsporogenesis. The spindle in metaphase I and anaphase I became heavily stained with propionic carmine. In telophase I, the interzonal microtubules continued to be intensely stained, and during the phragmoplast formation the fibers were pushed to the cell wall, persisting until prophase II, even after cytokinesis. Due to its tetraploid condition, the accession presented many cells with precocious chromosome migration to the poles in metaphase I and laggards in anaphase I that gave rise to micronuclei in telophase I. While in other polyploid accessions of Brachiaria micronuclei remained in this condition until the second cytokinesis, the micronuclei in this accession organized their own spindle in the second division. In several microsporocytes, the micronuclei with their minispindle were divided further into microcytes by additional cytokinesis. Some curious planes of cytokinesis were found in some cells, with partitioning of cytoplasm into cells of irregular shape. The result consisted of a high frequency of abnormal products of meiosis. Quadrivalents were observed in diakinesis at low frequency, which suggests a segmental allotetraploid and the inability of both genomes to co-ordinate their activities, leading to multiple spindle and precocious cellularization. In spite of abnormal meiotic products reducing pollen fertility, seed production was normal. Enough normal pollen was available to fertilize the central-cell nucleus of the embryo sac and produce normal endosperm in this pseudogamous aposporous apomictic accession.

MES-1, a protein required for unequal divisions of the germline in early C. elegans embryos, resembles receptor tyrosine kinases and is localized to the boundary between the germline and gut cells.

During Caenorhabditis elegans embryogenesis the primordial germ cell, P(4), is generated via a series of unequal divisions. These divisions produce germline blastomeres (P(1), P(2), P(3), P(4)) that differ from their somatic sisters in their size, fate and cytoplasmic content (e.g. germ granules). mes-1 mutant embryos display the striking phenotype of transformation of P(4) into a muscle precursor, like its somatic sister. A loss of polarity in P(2) and P(3) cell-specific events underlies the Mes-1 phenotype. In mes-1 embryos, P(2) and P(3) undergo symmetric divisions and partition germ granules to both daughters. This paper shows that mes-1 encodes a receptor tyrosine kinase-like protein, though it lacks several residues conserved in all kinases and therefore is predicted not to have kinase activity. Immunolocalization analysis shows that MES-1 is present in four- to 24-cell embryos, where it is localized in a crescent at the junction between the germline cell and its neighboring gut cell. This is the region of P(2) and P(3) to which the spindle and P granules must move to ensure normal division asymmetry and cytoplasmic partitioning. Indeed, during early stages of mitosis in P(2) and P(3), one centrosome is positioned adjacent to the MES-1 crescent. Staining of isolated blastomeres demonstrated that MES-1 was present in the membrane of the germline blastomeres, consistent with a cell-autonomous function. Analysis of MES-1 distribution in various cell-fate and patterning mutants suggests that its localization is not dependent on the correct fate of either the germline or the gut blastomere but is dependent upon correct spatial organization of the embryo. Our results suggest that MES-1 directly positions the developing mitotic spindle and its associated P granules within P(2) and P(3), or provides an orientation signal for P(2)- and P(3)-specific events.

Regulation of cytokinesis.

At the end of mitosis, daughter cells are separated from each other by cytokinesis. This process involves equal partitioning and segregation of cytoplasm between the two cells. Despite years of study, the mechanism driving cytokinesis in animal cells is not fully understood. Actin and myosin are major components of the contractile ring, the structure at the equator between the dividing cells that provides the force necessary to constrict the cytoplasm. Despite this, there are also tantalizing results suggesting that cytokinesis can occur in the absence of myosin. It is unclear what the roles are of the few other contractile ring components identified to date. While it has been difficult to identify important proteins involved in cytokinesis, it has been even more challenging to pinpoint the regulatory mechanisms that govern this vital process. Cytokinesis must be precisely controlled both spatially and temporally; potential regulators of these parameters are just beginning to be identified. This review discusses the recent progress in our understanding of cytokinesis in animal cells and the mechanisms that may regulate it.

The presenilin protein family member SPE-4 localizes to an ER/Golgi derived organelle and is required for proper cytoplasmic partitioning during Caenorhabditis elegans spermatogenesis.

During Caenorhabditis elegans spermatogenesis, asymmetric partitioning of cellular components principally occurs via ER/Golgi-derived organelles, named fibrous body-membranous organelles. In C. elegans spe-4 mutants, morphogenesis of fibrous body-membranous organelle complexes is defective and spermatogenesis arrests at an unusual cellular stage with four haploid nuclei within a common cytoplasm. The spe-4 encoded integral membrane protein is a diverged member of the presenilin family implicated in early onset Alzheimer's disease. Specific antisera were used to show that SPE-4 resides within the fibrous body-membranous organelles membranes during wild-type spermatogenesis. Several spe-4 recessive mutants were examined for SPE-4 immunoreactivity and a deletion mutant lacks detectable SPE-4 while either of two missense mutants synthesize and localize immunoreactive SPE-4 within their fibrous body-membranous organelles. One of these missense mutations is located within a motif that is common to all presenilins. spe-4 mutants were also examined for other partitioning defects and tubulin was found to accumulate in unusual deposits close to the plasma membrane. These results suggest that wild-type SPE-4 is required for proper localization of macromolecules that are subject to asymmetric partitioning during spermatogenesis.

The let-99 gene is required for proper spindle orientation during cleavage of the C. elegans embryo.

The orientation of cell division is a critical aspect of development. In 2-cell C. elegans embryos, the spindle in the posterior cell is aligned along the long axis of the embryo and contributes to the unequal partitioning of cytoplasm, while the spindle in the anterior cell is oriented transverse to the long axis. Differing spindle alignments arise from blastomere-specific rotations of the nuclear-centrosome complex at prophase. We have found that mutations in the maternally expressed gene let-99 affect spindle orientation in all cells during the first three cleavages. During these divisions, the nuclear-centrosome complex appears unstable in position. In addition, in almost half of the mutant embryos, there are reversals of the normal pattern of spindle orientations at second cleavage: the spindle of the anterior cell is aligned with the long axis of the embryo and nuclear rotation fails in the posterior cell causing the spindle to form transverse to the long axis. In most of the remaining embryos, spindles in both cells are transverse at second cleavage. The distributions of several asymmetrically localized proteins, including P granules and PAR-3, are normal in early let-99 embryos, but are perturbed by the abnormal cell division orientations at second cleavage. The accumulation of actin and actin capping protein, which marks the site involved in nuclear rotation in 2-cell wild-type embryos, is abnormal but is not reversed in let-99 mutant embryos. Based on these data, we conclude that let-99(+) is required for the proper orientation of spindles after the establishment of polarity, and we postulate that let-99(+) plays a role in interactions between the astral microtubules and the cortical cytoskeleton.

The Caenorhabditis elegans spe-5 gene is required for morphogenesis of a sperm-specific organelle and is associated with an inherent cold-sensitive phenotype.

The nonrandom segregation of organelles to the appropriate compartment during asymmetric cellular division is observed in many developing systems. Caenorhabditis elegans spermatogenesis is an excellent system to address this issue genetically. The proper progression of spermatogenesis requires specialized intracellular organelles, the fibrous body-membranous organelle complexes (FB-MOs). The FB-MOs play a critical role in cytoplasmic partitioning during the asymmetric cellular division associated with sperm meiosis II. Here we show that spe-5 mutants contain defective, vacuolated FB-MOs and usually arrest spermatogenesis at the spermatocyte stage. Occasionally, spe-5 mutants containing defective FB-MOs will form spermatids that are capable of differentiating into functional spermatozoa. These spe-5 spermatids exhibit an incomplete penetrance for tubulin mis-segregation during the second meiotic division. In addition to morphological and FB-MO segregation defects, all six spe-5 mutants are cold-sensitive, exhibiting a more penetrant sterile phenotype at 16 degrees than 25 degrees. This cold sensitivity could be an inherent property of FB-MO morphogenesis.

Transformation of the germ line into muscle in mes-1 mutant embryos of C. elegans

Mutations in the maternal-effect sterile gene mes-1 cause the offspring of homozygous mutant mothers to develop into sterile adults. Lineage analysis revealed that mutant offspring are sterile because they fail to form primordial germ cells during embryogenesis. In wild-type embryos, the primordial germ cell P4 is generated via a series of four unequal stem-cell divisions of the zygote. mes-1 embryos display a premature and progressive loss of polarity in these divisions: P0 and P1 undergo apparently normal unequal divisions and cytoplasmic partitioning, but P2 (in some embryos) and P3 (in most embryos) display defects in cleavage asymmetry and fail to partition lineage-specific components to only one daughter cell. As an apparent consequence of these defects, P4 is transformed into a muscle precursor, like its somatic sister cell D, and generates up to 20 body muscle cells instead of germ cells. Our results show that the wild-type mes-1 gene participates in promoting unequal germ-line divisions and asymmetric partitioning events and thus the determination of cell fate in early C. elegans embryos.

Extracellular association and cytoplasmic partitioning of the IpaB and IpaC invasins of S. flexneri

Shigella species cause bacillary dysentery in humans by invading colonic epithelial cells. IpaB and IpaC, two major invasins of these pathogens, are secreted into the extracellular milieu. We show here that IpaB and IpaC form a complex in the extracellular medium and that each binds independently to a 17 kDa polypeptide, IpgC, in the bacterial cytoplasm. The IpgC polypeptide was found to be necessary for bacterial entry into epithelial cells, to stabilize the otherwise unstable IpaB protein, and to prevent the proteolytic degradation of IpaC that occurs through its association with unprotected IpaB. We propose that IpgC, which is not secreted and thus acts as a molecular chaperone, serves as a receptor that prevents premature oligomerization of IpaB and IpaC within the cytoplasm of Shigella cells.

Identification of grandchildless loci whose products are required for normal germ-line development in the nematode Caenorhabditis elegans.

To identify genes that encode maternal components required for development of the germ line in the nematode Caenorhabditis elegans, we have screened for mutations that confer a maternal-effect sterile or "grandchildless" phenotype: homozygous mutant hermaphrodites produced by heterozygous mothers are themselves fertile, but produce sterile progeny. Our screens have identified six loci, defined by 21 mutations. This paper presents genetic and phenotypic characterization of four of the loci. The majority of mutations, those in mes-2, mes-3 and mes-4, affect postembryonic germ-line development; the progeny of mutant mothers undergo apparently normal embryogenesis but develop into agametic adults with 10-1000-fold reductions in number of germ cells. In contrast, mutations in mes-1 cause defects in cytoplasmic partitioning during embryogenesis, and the resulting larvae lack germ-line progenitor cells. Mutations in all of the mes loci primarily affect the germ line, and none disrupt the structural integrity of germ granules. This is in contrast to grandchildless mutations in Drosophila melanogaster, all of which disrupt germ granules and affect abdominal as well as germ-line development.