Immunofluorescence examination of beta tubulin expression and marginal band formation in developing chicken erythroblasts.

Chicken erythrocyte beta tubulin, a tubulin variant with unique biochemical and assembly properties, is found to be specifically contained in two chicken blood cell types--erythrocytes and thrombocytes. The beta tubulin variant is absent or present in low amounts in a variety of white blood cell types and other body tissues, as determined by immunofluorescence microscopy and a semi-quantitative immunoblotting procedure. During differentiation in the marrow the beta tubulin variant appears suddenly in mid-stage erythroblasts at the onset of hemoglobin synthesis, and forming marginal bands are seen in all subsequent polychromatophilic erythroblast stages. The developmental sequence of events in marginal band formation entails microtubule nucleation at the centrosome, followed by microtubule elongation, consolidation of loose parallel microtubules into a compact bundle, and microtubule association with the cell membrane.

Identity and Origin of the ATPase activity associated with neuronal microtubules. I. The ATPase activity is associated with membrane vesicles.

Microtubule protein purified from brain tissue by cycles of in vitro assembly-disassembly contains ATPase activity that has been postulated to be associated with microtubule-associated proteins (MAPs) and therefore significant for studies of microtubule-dependent motility. In this paper we demonstrate that greater than 90% of the ATPase activity is particulate in nature and may be derived from contaminating membrane vesicles. We also show that the MAPs (MAP-1, MAP-2, and tau factors) and other high molecular weight polypeptides do not contain significant amounts of ATPase activity. These findings do not support the concept of "brain dynein" or of MAPs with ATPase activity.

Identity and origin of the ATPase activity associated with neuronal microtubules. II. Identification of a 50,000-dalton polypeptide with ATPase activity similar to F-1 ATPase from mitochondria.

We determined that the ATPase activity contained in preparations of neuronal microtubules is associated with a 50,000-dalton polypeptide by four different methods: (a) photoaffinity labeling of the pelletable ATPase fraction with [gamma-32P]-8-azido-ATP; (b) analysis of two-dimensional gels (native gel X SDS slab gel) of an ATPase fraction solubilized by treatment with dichloromethane; (c) ATPase purification by glycerol gradient sedimentation and gel filtration chromatography of a solvent-released ATPase fraction, (d) demonstration of the binding of affinity-purified antibody to the 50-kdalton polypeptide to ATPase activity in vitro. Beginning with preparations of microtubules we have purified the ATPase activity greater than 700-fold and estimate that the purified enzyme has a specific activity of 20 mumol Pi x mg-1 x min-1 and comprises 80-90% of the total ATPase activity associated with neuronal microtubules. With affinity-purified antibody we also demonstrate cross-reactivity to the 50-kdalton subunits of mitochondrial F-1 ATPase and show that the antibody specifically labels mitochondria in PtK-2 cells. Biochemical comparisons of the enzymes reveal similar but not identical subunit composition and sensitivity to mitochondrial ATPase inhibitors. These studies indicate that the principal ATPase activity associated with microtubules is not contained in high molecular weight proteins such as dynein or MAPs and support the hypothesis that the 50-kdalton ATPase is a membrane protein and may be derived from mitochondria or membrane vesicles with F-1-like ATPase activity.

Copolymerization of two distinct tubulin isotypes during microtubule assembly in vitro.

Cells contain multiple tubulin isotypes that are the products of different genes and posttranslational modifications. It has been proposed that tubulin isotypes become segregated into different classes of microtubules each adapted to specific activities and functions. To determine if mixtures of tubulin isotypes segregate into different classes of polymers in vitro, we used immunoelectron microscopy to examine the composition of microtubule copolymers that assembled from mixtures of purified tubulin subunits from chicken brain and erythrocytes, each of which has been shown to exhibit distinct assembly properties in vitro. We observed that (a) the two isotypes coassemble rapidly and efficiently despite the fact that each isotype exhibits its own unique biochemical and assembly properties; (b) at low monomer concentrations the ratio of tubulin isotypes changes along the lengths of elongating copolymers resulting in gradients in immuno-gold labeling; (c) two distinct classes of copolymers each containing a distinct ratio of isotypes assemble simultaneously in the same subunit mixture; and (d) subunits and polymers of different isotypes associate nearly equally well with each other, there being only a slight bias favoring interactions among subunits and polymers of the same isotype. The observations agree with previous studies on the homogeneous distribution of multiple isotypes within cells and suggest that if segregation of isotypes does occur in vivo, it is most likely directed by cell-specific microtubule-associated proteins (MAPs) or specialized intracellular conditions.

Intracellular distribution of kinesin in chromaffin cells.

In this paper we examined the association of the microtubule motor protein kinesin with organelles in chromaffin cells. Approximately 15% of kinesin was associated with membranes as determined by differential and equilibrium centrifugation on sucrose gradients. Kinesin was not enriched in a particular organelle fraction but cofractionated with a variety of organelle markers including markers for early and late endosomes, smooth and rough endoplasmic reticulum (ER) and the Golgi apparatus. Surprisingly, low amounts of kinesin were present in fractions of purified chromaffin granules. The absence of kinesin from the bulk of chromaffin granules was also indicated by immunostaining of tissue sections. A polyclonal antibody that specifically recognized the 120 kDa kinesin heavy chain labeled predominantly a perinuclear region that is typical for most of the kinesin-binding organelles identified by cell fractionation (endosomes, Golgi, ER). Since these organelles are compartments with high membrane turnover, we speculate that kinesin might be involved in certain aspects of trafficking of these membrane systems.

Erythrocyte microtubule assembly in vitro. Tubulin oligomers limit the rate of microtubule self-assembly.

Chicken erythrocyte tubulin containing a unique beta tubulin variant polymerizes with greater efficiency (lower critical concentration) but at a slower rate than chicken brain tubulin. In a previous study we demonstrated that the low net rate of assembly is partly due to the presence of large oligomers and rings which reduce the initial rate of subunit elongation on microtubule seeds (Murphy, D.B., and Wallis, K.T. (1985) J. Biol. Chem. 260, 12293-12301). In this study we show that erythrocyte tubulin oligomers also retard the rate of microtubule nucleation and the net rate of self-assembly. The inhibitory effect is most likely to be due to the increased stability of erythrocyte tubulin oligomers, including a novel polymer of coiled rings that forms during the rapid phase of microtubule polymerization. The slow rate of dissociation of rings and coils into dimers and small oligomers appears to limit both the nucleation and elongation steps in the self-assembly of erythrocyte microtubules.

Brain and erythrocyte microtubules from chicken contain different beta-tubulin polypeptides.

beta-Tubulin subunits isolated from chicken brain tissue and erythrocytes are distinguishable as unique biochemical species by electrophoretic and peptide mapping procedures. 1) The subunits of beta-tubulin exhibit major differences in electrophoretic mobility on sodium dodecyl sulfate-polyacrylamide gels that vary according to the pH and ionic strength of the gel. 2) The isoelectric points of urea-denatured beta subunits from brain tissue and erythrocytes are pH 5.1 and 5.4, respectively, whereas those of both alpha subunits are approximately pH 5.2.3) Two-dimensional peptide maps prepared with alpha-chymotrypsin or V8 protease show that alpha-tubulin peptides are indistinguishable, whereas beta-tubulin peptides are very different. Only one-third of the 15 major tyrosine-containing beta-tubulin peptides prepared with alpha-chymotrypsin are common to both beta-tubulin species. The data indicate that the beta-tubulin subunits of brain tissue and erythrocytes are biochemically distinct and may be different gene products. The presence of tubulin variants in brain tissue and erythrocytes may indicate special requirements for microtubule assembly and function in different cell types.

Isolation of microtubule protein from chicken erythrocytes and determination of the critical concentration for tubulin polymerization in vitro and in vivo.

Microtubule protein isolated from nucleated chicken erythrocytes was examined with respect to composition and assembly properties to determine its significance in a microtubule bundle called the marginal band. 1) The protein contains greater than 95% tubulin with small amounts of tau polypeptides and no high molecular weight polypeptides. 2) Microtubule assembly in vitro at 37 degrees C is characterized by low levels of nucleation, despite an abundance of ring oligomers at 5 degrees C, as indicated by long lag times, slow assembly rates, and microtubules that are twice as long as brain microtubules assembled under the same conditions. 3) By radioimmunoassay and sodium dodecyl sulfate gel analysis we determined that 0.6% of erythrocyte protein is tubulin of which three-quarters is in a nonextractable form and is associated with the microtubule bundle and the cell cortex. From these values the in vivo concentrations of total tubulin and tubulin dimer subunits are 2.4 and 0.7 mg/ml, respectively. The value of 0.7 mg/ml is close to the range of values of 0.1-0.6 mg/ml for the critical concentration of erythrocyte microtubule protein in vitro, suggesting that the assembly properties of tubulin in vitro and in vivo are similar.

Erythrocyte microtubule assembly in vitro. Determination of the effects of erythrocyte tau, tubulin isoforms, and tubulin oligomers on erythrocyte tubulin assembly, and comparison with brain microtubule assembly.

Two tubulin variants, isolated from chicken brain and erythrocytes and known to have different peptide maps and electrophoretic properties, are demonstrated to exhibit different assembly properties in vitro: 1) erythrocyte tubulin assembles with greater efficiency (lower critical concentration, greater elongation rate) but exhibits a lower nucleation rate than brain tubulin, and 2) erythrocyte tubulin readily forms oligomers whose presence significantly retards the rate of elongation, suggesting that tubulin oligomers may also be important for determining the rate of assembly and the length of microtubules in erythrocytes. Erythrocyte tubulin isolated by cycles of in vitro assembly-disassembly is also demonstrated to contain a 67-kDa tau factor that greatly enhances microtubule nucleation but has little effect on elongation rates or critical concentration. Immunofluorescence microscopy with tau antibody indicates that tau is specifically associated with marginal band microtubules, suggesting that it may be important for determining microtubule function in vivo.

The sequence and expression of the divergent beta-tubulin in chicken erythrocytes.

We report here the complete sequence of a highly divergent chicken erythrocyte beta-tubulin, c beta 6, which appears to represent a major exception to the observation that the primary sequences and sites of expression of beta-tubulin isotypes are conserved within vertebrates. The amino acid sequence was deduced from overlapping cloned cDNAs identified in a chicken erythroblast cDNA library contained in the expression vector, lambda gt11. Compared with other chicken beta-tubulins, among which the maximum sequence divergence is only 8%, c beta 6-tubulin is more hydrophobic, contains seven fewer net negative charges, and exhibits a surprising 17% overall divergence in its amino acid sequence. DNA and RNA blot analyses show that c beta 6-tubulin is present as a single gene copy in the chicken genome and is specifically expressed in the bone marrow. Comparisons of RNA blots and immunoblots of various cells and tissues confirm that this beta-tubulin isotype is contained specifically in erythrocytes and thrombocytes and accounts for 75% of the beta-tubulin mRNA species contained in developing erythroblasts. Interestingly, c beta 6-tubulin exhibits 18% amino acid sequence divergence relative to MB1, the analogous hematopoietic beta-tubulin contained in mouse.

The mechanism of equilibrium binding of microtubule-associated protein 2 to microtubules. Binding is a multi-phasic process and exhibits positive cooperativity.

The mechanism of binding of microtubule-associated protein 2 (MAP2) to taxol-stabilized microtubules (MTs) was examined through Scatchard analysis of equilibrium binding and by immunoelectron microscopy. We demonstrate the following. 1) Binding is a cooperative process as indicated by sigmoidal binding curves, prominent humps in Scatchard plots, and an all-or-none response in binding during ligand titrations. At high tubulin/MAP2 ratios, the Kd for noncontiguous binding (5-25 microM) is estimated to be 100-1500 times greater than that predicted for contiguous binding, suggesting a high degree of cooperativity. 2) Cooperativity is indicated independently by a highly clustered or patchy distribution of MAP2 on MTs as revealed by immunoelectron microscopy. 3) The binding of truncated constructs of mouse MAP2 protein suggests that a domain of MAP2 conferring cooperativity is located in or near the MT binding site near the carboxyl terminus. We speculate that in the cell, cooperativity may generate MTs with uniform biochemical properties and contribute to the segregation of MAPs in neuronal cell processes.

HIRA, a DiGeorge syndrome candidate gene, is required for cardiac outflow tract septation.

DiGeorge syndrome (DGS) is a congenital disease characterized by defects in organs and tissues that depend on contributions by cell populations derived from neural crest for proper development. A number of candidate genes that lie within the q11 region of chromosome 22 commonly deleted in DGS patients have been identified. Orthologues of the DGS candidate gene HIRA are expressed in the neural crest and in neural crest-derived tissues in both chick and mouse embryos. By exposing a portion of the premigratory chick neural crest to phosphorothioate end-protected antisense oligonucleotides, ex ovo, followed by orthotopic backtransplantation to the untreated embryos, we have shown that the functional attenuation of cHIRA in the chick cardiac neural crest results in a significantly increased incidence of persistent truncus arteriosus, a phenotypic change characteristic of DGS, but does not affect the repatterning aortic arch arteries, the ventricular function, or the alignment of the outflow tract.

Conotruncal myocardium arises from a secondary heart field.

The primary heart tube is an endocardial tube, ensheathed by myocardial cells, that develops from bilateral primary heart fields located in the lateral plate mesoderm. Earlier mapping studies of the heart fields performed in whole embryo cultures indicate that all of the myocardium of the developed heart originates from the primary heart fields. In contrast, marking experiments in ovo suggest that the atrioventricular canal, atria and conotruncus are added secondarily to the straight heart tube during looping. The results we present resolve this issue by showing that the heart tube elongates during looping, concomitant with accretion of new myocardium. The atria are added progressively from the caudal primary heart fields bilaterally, while the myocardium of the conotruncus is elongated from a midline secondary heart field of splanchnic mesoderm beneath the floor of the foregut. Cells in the secondary heart field express Nkx2.5 and Gata-4, as do the cells of the primary heart fields. Induction of myocardium appears to be unnecessary at the inflow pole, while it occurs at the outflow pole of the heart. Accretion of myocardium at the junction of the inflow myocardium with dorsal mesocardium is completed at stage 12 and later (stage 18) from the secondary heart field just caudal to the outflow tract. Induction of myocardium appears to move in a caudal direction as the outflow tract translocates caudally relative to the pharyngeal arches. As the cells in the secondary heart field begin to move into the outflow or inflow myocardium, they express HNK-1 initially and then MF-20, a marker for myosin heavy chain. FGF-8 and BMP-2 are present in the ventral pharynx and secondary heart field/outflow myocardium, respectively, and appear to effect induction of the cells in a manner that mimics induction of the primary myocardium from the primary heart fields. Neither FGF-8 nor BMP-2 is present as inflow myocardium is added from the primary heart fields. The addition of a secondary myocardium to the primary heart tube provides a new framework for understanding several null mutations in mice that cause defective heart development.