Michel Kress

Phosphorylation by p34cdc2 regulates spindle association of human Eg5, a kinesin-related motor essential for bipolar spindle formation in vivo

We have isolated a human homolog of Xenopus Eg5, a kinesin-related motor protein implicated in the assembly and dynamics of the mitotic spindle. We report that microinjection of antibodies against human Eg5 (HsEg5) blocks centrosome migration and causes HeLa cells to arrest in mitosis with monoastral microtubule arrays. Furthermore, an evolutionarily conserved cdc2 phosphorylation site (Thr-927) in HsEg5 is phosphorylated specifically during mitosis in HeLa cells and by p34cdc2/cyclin B in vitro. Mutation of Thr-927 to nonphosphorylatable residues prevents HsEg5 from binding to centrosomes, indicating that phosphorylation controls the association of this motor with the spindle apparatus. These results indicate that HsEg5 is required for establishing a bipolar spindle and that p34cdc2 protein kinase directly regulates its localization.

The translational regulator CPEB1 provides a link between dcp1 bodies and stress granules

The cytoplasmic polyadenylation element-binding protein (CPEB) has been characterized in Xenopus laevis as a translational regulator. During the early development, it behaves first as an inhibitor and later as an activator of translation. In mammals, its closest homologue is CPEB1 for which two isoforms, short and long, have been described. Here we describe an additional isoform with a different RNA recognition motif, which is differentially expressed in the brain and ovary. We show that all CPEB1 isoforms are found associated with two previously described cytoplasmic structures, stress granules and dcp1 bodies. This association requires the RNA binding ability of the protein, whereas the Aurora A phosphorylation site is dispensable. Interestingly, the rck/p54 DEAD box protein, which is known as a CPEB partner in Xenopus and clam, and as a component of dcp1 bodies in mammals, is also present in stress granules. Both stress granules and dcp1 bodies are involved in mRNA storage and/or degradation, although so far no link has been made between the two, in terms of neither morphology nor protein content. Here we show that transient CPEB1 expression induces the assembly of stress granules, which in turn recruit dcp1 bodies. This dynamic connection between the two structures sheds new light on the compartmentalization of mRNA metabolism in the cytoplasm.

Translationally Repressed mRNA Transiently Cycles through Stress Granules during Stress

In mammals, repression of translation during stress is associated with the assembly of stress granules in the cytoplasm, which contain a fraction of arrested mRNA and have been proposed to play a role in their storage. Because physical contacts are seen with GW bodies, which contain the mRNA degradation machinery, stress granules could also target arrested mRNA to degradation. Here we show that contacts between stress granules and GW bodies appear during stress-granule assembly and not after a movement of the two preassembled structures. Despite this close proximity, the GW body proteins, which in some conditions relocalize in stress granules, come from cytosol rather than from adjacent GW bodies. It was previously reported that several proteins actively traffic in and out of stress granules. Here we investigated the behavior of mRNAs. Their residence time in stress granules is brief, on the order of a minute, although stress granules persist over a few hours after stress relief. This short transit reflects rapid return to cytosol, rather than transfer to GW bodies for degradation. Accordingly, most arrested mRNAs are located outside stress granules. Overall, these kinetic data do not support a direct role of stress granules neither as storage site nor as intermediate location before degradation.

Secretion of a transplantation-related antigen

Analysis of mouse cDNA clones has led to the identification of a class I (H-2)-related gene that encodes a truncated transplantation-like antigen. Unlike the products of the class I genes (H-2K, H-2D, and H2-L), which are synthesized and displayed on the surface of all cells, the class I-related gene product is expressed only in liver cells and is secreted. The region of the secreted molecule corresponding to the extracellular domain of the membrane-bound class I antigens shows unusual amino acid substitutions at positions otherwise invariably conserved. There is also loss of a glycosylation site that is used in all class I antigens. Within the region corresponding to the transmembrane domain are multiple nonconservative substitutions of hydrophobic residues, alterations that render the encoded protein incapable of inserting into the plasma membrane. Toward the end of the same domain, the polypeptide chain terminates abruptly and thus lacks the intracellular domain present on all class I antigens. A candidate for this secreted molecule, detected using various heteroantisera against class I antigens, has been identified. A potential role for this serum protein in mediating active tolerance is discussed.

Unravelling the ultrastructure of stress granules and associated P-bodies in human cells

Stress granules are cytoplasmic ribonucleoprotein granules formed following various stresses that inhibit translation. They are thought to help protecting untranslated mRNAs until stress relief. Stress granules are frequently seen adjacent to P-bodies, which are involved in mRNA degradation and storage. We have previously shown in live cells that stress granule assembly often takes place in the vicinity of pre-existing P-bodies, suggesting that these two compartments are structurally related. Here we provide the first ultrastructural characterization of stress granules in eukaryotic cells by electron microscopy. Stress granules resulting from oxidative stress, heat-shock or protein overexpression are loosely organised fibrillo-granular aggregates of a moderate electron density, whereas P-bodies are denser and fibrillar. By in situ hybridization at the electron microscopic level, we show that stress granules are enriched in poly(A)+ mRNAs, although these represent a minor fraction of the cellular mRNAs. Finally, we show that, despite close contact with P-bodies, both domains remain structurally distinct and do not interdigitate.

Nucleocytoplasmic Traffic of CPEB1 and Accumulation in Crm1 Nucleolar Bodies

The translational regulator CPEB1 plays a major role in the control of maternal mRNA in oocytes, as well as of subsynaptic mRNAs in neurons. Although mainly cytoplasmic, we found that CPEB1 protein is continuously shuttling between nucleus and cytoplasm. Its export is controlled by two redundant NES motifs dependent on the nuclear export receptor Crm1. In the nucleus, CPEB1 accumulates in a few foci most often associated with nucleoli. These foci are different from previously identified nuclear bodies. They contain Crm1 and were called Crm1 nucleolar bodies (CNoBs). CNoBs depend on RNA polymerase I activity, indicating a role in ribosome biogenesis. However, although they form in the nucleolus, they never migrate to the nuclear envelope, precluding a role as a mediator for ribosome export. They could rather constitute a platform providing factors for ribosome assembly or export. The behavior of CPEB1 in CNoBs raises the possibility that it is involved in ribosome biogenesis.

Expression of the mitotic kinesin Kif15 in postmitotic neurons: implications for neuronal migration and development.

Kif15 is a kinesin-related protein whose mitotic homologues are believed to crosslink and immobilize spindle microtubules. We have obtained rodent sequences of Kif15, and have studied their expression and distribution in the developing nervous system. Kif15 is indeed expressed in actively dividing fibroblasts, but is also expressed in terminally postmitotic neurons. In mitotic cells, Kif15 localizes to spindle poles and microtubules during prometaphase to early anaphase, but then to the actin-based cleavage furrow during cytokinesis. In interphase fibroblasts, Kif15 localizes to actin bundles but not to microtubules. In cultured neurons, Kif15 localizes to microtubules but shows no apparent co-localization with actin. Localization of Kif15 to microtubules is particularly good when the microtubules are bundled, and there is a notable enrichment of Kif15 in the microtubule bundles that occupy stalled growth cones and dendrites. Studies on developing rodent brain show a pronounced enrichment of Kif15 in migratory neurons compared to other neurons. Notably, migratory neurons have a cage-like configuration of microtubules around their nucleus that is linked to the microtubule array within the leading process, such that the entire array moves in unison as the cell migrates. Since the capacity of microtubules to move independently of one another is restricted in all of these cases, we propose that Kif15 opposes the capacity of other motors to generate independent microtubule movements within key regions of developing neurons.

Characterization of five distinct cDNA clones encoding for class I RT1 antigens

Class I transplantation antigens of the major histocompatibility complex (MHC) are cell surface glycoproteins which present antigens to cytotoxic T cells (Schwartz 1985). They are heterodimeric and composed of a polymorphic, MHC-encoded, -45 000 heavy chain, noncovalently associated with a 1 2 000 beta-2 microglobulin (B2m) light chain (Nathenson et al. 1981). The H-2 system of the mouse and the HLA system of the human have been studied extensively; nevertheless, a better understanding of the rat MHC (the RT1 system) is also interesting since the rat is an experimental model for disease and transplantation, as well as for the study of evolutionary aspects of the MHC. Serological and genetic analyses of the RT1 system have led to the identification of six class I loci, A, Pa, F, E, G, and C, and two class II loci, B and D (for a review, see Gill et al. 1987). Their organization is similar to that of the mouse: the class I RT1-A and RT1-E loci that appear to define the conventional limits of the MHC are separated by the class II region, while the RT1-G and RT1-C loci are situated distally to the RT1-E locus and appear to be comparable to the Qa and T/a regions of the mouse. In contrast to the mouse H-2 complex, the rat RT1 system exhibits a restricted allelic polymorphism. Nevertheless, studies of the RT1 system by Southern blot hybridization have revealed a high number of class I genes in the rat genome (Palmer et al. 1983, Gtinther et al. 1985, Wettstein et al. 1985). We have undertaken the analysis of the RT1 class I genes by cDNA cloning procedures. The nucleotide sequence of a rat B2m cDNA clone has already been determined (Mauxion and Kress 1987), and we report here the characterization of five distinct cDNA clones encoding class I antigen heavy chains. Three oligo-dT primed cDNA libraries synthesized with liver poly(A) ÷ mRNA from Wistar Albinos Glaxo rats (u haplotype, WAG rats were randomly bred in the animal house of our institute and were maintained as a

Mislocalization of human transcription factor MOK2 in the presence of pathogenic mutations of lamin A/C

Background information. hsMOK2 (human MOK2) is a DNA‐binding transcriptional repressor. For example, it represses the IRBP (interphotoreceptor retinoid‐binding protein) gene by competing with the CRX (cone‐rod homeobox protein) transcriptional activator for DNA binding. Previous studies have shown an interaction between hsMOK2 and nuclear lamin A/C. This interaction could be important to explain hsMOK2 ability to repress transcription.

Disruption of the mitotic kinesin Eg5 gene (Knsl1) results in early embryonic lethality.

Eg5, a member of the widely conserved kinesin-5 family, is a plus-end-directed motor involved in separation of centrosomes, and in bipolar spindle formation and maintenance during mitosis in vertebrates. To investigate the requirement for Eg5 in mammalian development, we have generated Eg5 deficient mice by gene targeting. Heterozygous mice are healthy, fertile, and show no detectable phenotype, whereas Eg5(-/-) embryos die during early embryogenesis, prior to the implantation stage. This result shows that Eg5 is essential during early mouse development and cannot be compensated by another molecular motor.