Microtubule dynamics in vivo: a test of mechanisms of turnover

Clarification of the mechanism of microtubule dynamics requires an analysis of the microtubule pattern at two time points in the same cell with single fiber resolution. Single microtubule resolution was obtained by microinjection of haptenized tubulin (fluorescein-tubulin) and subsequent indirect immunofluorescence with an antifluorescein antibody. The two time points in a single cell were, first, the time of photobleaching fluorescein-tubulin, and second, the time of fixation. The pattern of fluorescence replacement in the bleached zone during this time interval revealed the relevant mechanisms. In fibroblasts, microtubule domains in the bleached zone are replaced microtubule by microtubule and not by mechanisms that affect all microtubules simultaneously. Of the models we consider, treadmilling and subunit exchange along the length do not account for this observation, but dynamic instability can since it suggests that growing and shrinking microtubules coexist. In addition, we show that the half-time for microtubule replacement is shortest at the leading edge. Dynamic instability accounts for this observation if in general microtubules do not catastrophically disassemble from the plus end, but instead have a significant probability of undergoing a transition to the growing phase before they depolymerize completely. This type of instability we call tempered rather than catastrophic because, through limited disassembly followed by regrowth, it will preferentially replace polymer domains at the ends of microtubules, thus accounting for the observation that the half-time of microtubule domain replacement is shorter with proximity to the leading edge.     

Immunochemical characterization of related families of glycoproteins in desmosomes

Using several biochemical approaches, we have characterized the relatedness of the various glycoprotein components of the bovine epidermal desomosome. Sodium dodecyl sulfate-polyacrylamide gel electrophoretic analysis of purified epidermal desmosomes reveals 12 proteins, of which 8 are glycosylated. Analysis with monoclonal antibodies indicates that the 8 glycoproteins comprise 3 antigenically distinct protein families. Members of the highest molecular weight glycoprotein family (a triplet of Mr = 150,000) were not distinguishable by partial proteolytic peptide mapping. At least 6 different monoclonal antibodies have been identified that recognize unique antigenic determinants shared by these proteins. Members of a 97,000-118,000-dalton glycoprotein family (about 4 bands) generate very similar but not identical partial proteolytic peptide maps. At least 3 different monoclonal antibodies have been identified that recognize unique antigenic determinants shared by these proteins. A Mr = 22,000 glycoprotein is immunologically unrelated to either of the high molecular weight glycoprotein families. Lectin-binding profiles indicate that within each immunologically related family the glycoproteins are similar in their oligosaccharide composition. Some lectins distinguish among the families. These glycoproteins probably mediate the specific intercellular recognition and adhesive functions of the desmosome.     

Preadipocyte Recruitment in Stromal Vascular Cultures After Depletion of Committed Preadipocytes by Immunocytotoxicity

Glucocorticoids or the glucocorticoid analog dexamethasone (DEX) enhances the differentiation of preadipocytes in the presence of insulin and influences preadipocyte proliferation. The purpose of the present study was to determine if DEX can induce the recruitment of preadipocytes. Using monoclonal antibodies for complement-mediated cytotoxicity, preadipocytes were removed from porcine stromal vascular (S-V) cell cultures. Our experiments demonstrated for the first time that after removal of preadipocytes by cytotoxicity, preadipocytes or fat cells could be induced by DEX or DEX plus insulin but not by insulin alone. However, many more fat cells were induced (258 ± 15/unit area) when DEX was added with fetal bovine serum (FBS) followed with insulin treatment, compared to DEX with insulin (21.3 ± 5.1/ unit area) after removal of preadipocytes. Immunocyto-chemistry with AD-3, a preadipocyte marker, showed that DEX with FBS for 3 days after seeding (i.e., the proliferation phase) produced many more preadipocytes (AD-3 positive, 223 ± 45/unit area) than FBS alone (10.5 ± 1.4/unit area). Bromodeoxyuridine (BrdU) incorporation assays demonstrated that the efficiency of DEX with FBS (i.e., during proliferation) was mitosis dependent. Accordingly, we conclude that: porcine S-V cultures contain preadipocytes at different stages of differentiation and that DEX induced early preadipocyte differentiation depends on mitosis.     

Ultrastructural and biochemical identification of con A receptors in the desmosome

Correlated ultrastructural and biochemical methods were used to identify and localize Concanavalin A (Con A) receptors in the desmosomes of bovine epidermis. Specific carbohydrate residues were labeled with ferritin-Con A in thin sections of tissue embedded in a hydrophilic resin. Quantitative mapping of ferritin distribution in labeled desmosomes revealed that Con A receptors are localized in the intercellular zone and concentrated along the desmosomal midline or central dense stratum. Labeling was almost entirely absent when sections were treated with ferritin-Con A in the presence of 0.1 M α-methyl mannoside, a hapten-inhibitor of Con A. “Whole” desmosomes and desmosomal intercellular regions (desmosomal “cores”) were purified from bovine muzzle epidermis. Sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis reveals a limited number of major desmosomal protein constituents. Certain of these are glycoproteins and are greatly enriched in the core fraction. Almost all the desmosomal glycoproteins are intensely labeled when electrophoretic gels of whole desmosome or core fractions are exposed to fluorescent Concanavalin A.     

Isolation of the intercellular glycoproteins of desmosomes

To characterize the desmosome components that mediate intercellular adhesion and cytoskeletal-plasma membrane attachment, we prepared whole desmosomes and isolated desmosomal intercellular regions (desmosomal "cores") from the living cell layers of bovine muzzle epidermis. The tissue was disrupted in a nonionic detergent at low pH, sonicated, and the insoluble residue fractionated by differential centrifugation and metrizamide gradient centrifugation. Transmission electron microscopic analyses reveal that a fraction obtained after differential centrifugation is greatly enriched in whole desmosomes that possess intracellular plaques. Metrizamide gradient centrifugation removes most of the plaque material, leaving the intercellular components and the adjoining plasma membranes. Sodium dodecyl sulfate polyacrylamide gel electrophoresis coupled with methods that reveal carbohydrate-containing moieties on gels demonstrate that certain proteins present in whole desmosomes are glycosylated. These glycoproteins are specifically and greatly enriched in the desmosome cores of which they are the principal protein constituents, and thus may function as the intercellular adhesive of the desmosome.     

Mps1 promotes poleward chromosome movements in meiotic prometaphase

In prophase of meiosis I, homologous chromosomes pair and become connected by cross-overs. Chiasmata, the connections formed by cross-overs, enable the chromosome pair, called a bivalent, to attach as a single unit to the spindle. When the meiotic spindle forms in prometaphase, most bivalents are associated with one spindle pole and then go through a series of oscillations on the spindle, attaching to and detaching from microtubules until the partners of the bivalent become bioriented—attached to microtubules from opposite sides of the spindle. The conserved kinase, Mps1, is essential for the bivalents to be pulled by microtubules across the spindle in prometaphase. Here we show that MPS1 is needed for efficient triggering of the migration of microtubule-attached kinetochores toward the poles and promotes microtubule depolymerization. Our data support the model Mps1 acts at the kinetochore to coordinate the successful attachment of a microtubule and the triggering of microtubule depolymerization to then move the chromosome.     

Mitosis: MCAK under the aura of Aurora B

Two new studies show that phosphorylation by Aurora B kinase controls the centromere localization and catalytic activity of the microtubule depolymerase MCAK. Physical tension from microtubule attachment may influence access of MCAK to Aurora B kinase and its opposing phosphatases.     

The dephosphorylated form of the anaphase-promoting complex protein Cdc27/Apc3 concentrates on kinetochores and chromosome arms in mitosis

Cell cycle regulated protein ubiquitination and degradation within subcellular domains may be essential for the normal progression of mitosis. Cdc27 is a conserved component of an essential M-phase ubiquitin-protein ligase called the anaphase-promoting complex/cyclosome. We examined the subcellular distribution of Cdc27 in greater detail in mammalian cells and found Cdc27 concentrated at spindle poles and on spindle microtubules as previously described, but also found Cdc27 at kinetochores and along chromosome arms. This localization was not dependent on intact microtubules. While the great majority of Cdc27 protein in M phase cells is highly phosphorylated, only the dephosphorylated form of Cdc27 was found associated with isolated chromosomes. Kinases that also associate with isolated chromosomes catalyzed the in vitro phosphorylation of the chromosome-associated Cdc27. Microinjection of anti-Cdc27 antibody into cells causes arrest at metaphase. Microinjection of cells with anti-Mad2 antibody normally induces premature anaphase onset resulting in catastrophic nondisjunction of the chromosomes. However, coinjection of anti-Cdc27 antibody with anti-Mad2 antibody resulted in metaphase arrest. The association of dephosphorylated APC/C components with mitotic chromosomes suggests mechanisms by which the spindle checkpoint may regulate APC/C activity at mitosis.     

Kinetochore "memory" of spindle checkpoint signaling in lysed mitotic cells

The spindle checkpoint prevents errors in mitosis. Cells respond to the presence of kinetochores that are improperly attached to the mitotic spindle by delaying anaphase onset. Evidence suggests that phosphorylations recognized by the 3F3/2 anti-phosphoepitope antibody may be involved in the kinetochore signaling of the spindle checkpoint. Mitotic cells lysed in detergent in the absence of phosphatase inhibitors rapidly lose expression of the 3F3/2 phosphoepitope. However, when ATP is added to lysed and rinsed mitotic cytoskeletons, kinetochores become rephosphorylated by an endogenous, bound kinase. Kinetochore rephosphorylation in vitro produced the same differential phosphorylation seen in appropriately fixed living cells. In chromosomes not yet aligned at the metaphase plate, kinetochores undergo rapid rephosphorylation, while those of fully congressed chromosomes are under-phosphorylated. However, latent 3F3/2 kinase activity is retained at kinetochores of cells at all stages of mitosis including anaphase. This latent activity is revealed when rephosphorylation reactions are carried out for extended times. The endogenous, kinetochore-bound kinase can be chemically inactivated. Remarkably, a soluble kinase activity extracted from mitotic cells also caused differential rephosphorylation of kinetochores whose endogenous kinase had been chemically inactivated. We suggest that, in vivo, microtubule attachment alters the kinetochore 3F3/2 phosphoprotein, causing it to resist phosphorylation. This kinetochore modification is retained after cell lysis, producing a "memory" of the in vivo phosphorylation state.