The effects of open leaf burning on spirometric measurements in asthma.

The purpose of our study was to determine the effects of open leaf burning on asthmatic subjects. Seven subjects with known asthma of varying severity, along with three normal control subjects, were walked 0.5 mile with and without exposure on the same day, under very similar environmental conditions. An acute spirometric broncho-constrictive response was observed within 30 min of exercise with exposure to leaf burning in two of the seven asthmatic subjects. Five of the seven showed an overall drop in parameters measured. No significant change in the FEV1 was seen in the normal subjects with either protocol, nor in the asthmatic subjects during low level exercise alone. The results of our study suggest that open leaf burning under normal community-allowed conditions may represent a significant health hazard for some asthmatic subjects.

Tubulin-colchicine complex (TC) inhibits microtubule depolymerization by a capping reaction exerted preferentially at the minus end.

The effects of colchicine and tubulin-colchicine complex (TC) on microtubule depolymerization were studied using the axoneme-subunit system described previously [Bergen LG, Borisy GG; J Cell Biol 84:141-150, 1980]. This system allows the independent analysis of the polymerization kinetics at both the plus and minus ends of a microtubule. Depolymerization was induced by isothermal dilution with 10 volumes of an experimental solution containing colchicine, TC, or buffer alone. Colchicine alone (5-100 microM) blocked depolymerization at the minus end, whereas depolymerization at the plus end occurred at almost control rates. A similar effect was produced by TC (0.4:1-1:1 molar ratio to free tubulin). High molar ratios of TC to tubulin (10:1) blocked depolymerization at both plus and minus ends, and intermediate molar ratios of TC:T allowed depolymerization of the plus ends but at attenuated rates. The blockage was not readily reversible; TC-affected ends neither shortened upon dilution nor grew longer upon incubation with additional tubulin. We conclude that TC at suprastoichiometric ratios to tubulin inhibits microtubule depolymerization by a capping reaction and that this effect is exerted preferentially at the minus end.

Genes selectively expressed in proliferating Dictyostelium amoebae.

Few eukaryotic genes are expressed only during cell growth and division. We found that the slime mold Dictyostelium discoideum is unusual in that it expresses many genes only during proliferation. Thirty-two percent (304/950) of the sequences in a cDNA library made from vegetative mRNA were homologous to RNAs that are present at high levels during growth but at low or undetectable levels during differentiation when no cell growth occurs. In vitro translation assays confirmed that one-third of the vegetative cell mRNAs decreased in steady-state levels during differentiation. These vegetative cell-specific transcripts identified a diverse coordinately regulated class of genes: (i) 9 of the 10 cDNAs tested hybridized to unique small transcripts ranging from 400 to 620 bases long; (ii) the sequences showed various degrees of homology to related species; (iii) transcript levels synchronously fell by a factor of greater than 20 during development and synchronously increased during germination. This class of genes may play important roles in normal cell proliferation.

Effects of mitotic and tubulin mutations on microtubule architecture in actively growing protoplasts of Aspergillus nidulans.

We used immunofluorescent microscopy to characterize microtubule (MT) architecture in wild-type and mutant protoplasts of Aspergillus nidulans at interphase and at mitosis. Because the visualization of MTs by immunofluorescence is technically difficult in intact hyphae of A. nidulans, we developed a method for removing the cell wall under conditions that do not perturb cell physiology, as evidenced by the fact that the resulting protoplasts undergo nuclear division at a normal rate and that cell cycle mutant phenotypes are expressed at restrictive temperature. Interphase cells exhibited an extensive network of cytoplasmic MTs. During mitosis the cytoplasmic MTs mostly disappeared and an intranuclear mitotic spindle appeared. We have previously shown that the benA 33 beta-tubulin mutation causes hyperstabilization of the mitotic spindle, and we have presented additional indirect evidence that suggested that the tubA1 and tubA4 alpha-tubulin mutations destabilize spindle MTs. In this paper, we show that the benA33 mutation increases the stability of cytoplasmic MTs as well as spindle MTs and that the tubA1 and tubA4 mutations destabilize both spindle and cytoplasmic MTs.

S-phase, G2, and nuclear division mutants of Aspergillus nidulans.

Twenty-two temperature-sensitive cell cycle mutants of the fungus Aspergillus nidulans, which block in interphase at restrictive temperature, were analyzed by the reciprocal shift method of Jarvik and Botstein (Proc. Nath Acad. Sci. U.S.A. 70:2046-2050, 1973) and Hereford and Hartwell (J. Mol. Biol. 84:445-461, 1974) to determine whether these mutations were blocked at the G1, S, or G2 phase of the cell cycle. We found five mutants to be blocked in S and nine to be blocked in G2. Two of the G2 mutants were atypical in that they were not able to accomplish the G2 to M transition at restrictive temperature but nevertheless could initiate subsequent cycles of DNA replication. None was blocked in G1. There were nine strains that could not be classified. The block imposed by restrictive temperature was irreversible in three of these strains, and the six other strains were unclassifiable due to their aberrant terminal nuclear phenotypes.

Kinetics of the nuclear division cycle of Aspergillus nidulans.

We have analyzed the cell cycle kinetics of Aspergillus nidulans by using the DNA synthesis inhibitor hydroxyurea (HU) and a temperature-sensitive cell cycle mutant nimT that blocks in G2. HU rapidly inhibits DNA synthesis (S), and as a consequence progression beyond S to mitosis (M) is blocked. Upon removal of HU the inhibition is rapidly reversible. Conidia (asexual spores) of nimT were germinated at restrictive temperature to synchronize germlings in G2 and then downshifted to permissive temperature in the presence of HU. This procedure synchronizes the germlings at the beginning of S in the second cell cycle after spore germination. We have measured the total duration of S, G2, and M as the time required for these cells to recover from the HU block and undergo the next nuclear division. The duration of S was defined by the time course of sensitivity to reintroduction of HU during recovery from the initial HU block. The cell cycle time was measured as the nuclear doubling time, and the duration of mitosis was determined from the mitotic index. The duration of G1 was calculated by subtracting the combined durations of S, G2, and M from the nuclear doubling time, and the length of G2 was calculated by subtracting S and M from the aggregate length of S, G2, and M. We have also determined the duration of the phases of the cell cycle during the first cycle after spore germination. In these experiments spores were germinated directly in HU without first being blocked in G2. Because the durations of G1, S, G2, and M for the first cell cycle after spore germination were identical with those previously determined for spores presynchronized at the beginning of S in the second cell cycle, we conclude that dormant conidia of A. nidulans are arrested at, or before, the start of S.

Tubulin-colchicine complex inhibits microtubule elongation at both plus and minus ends.

We studied the mechanism by which tubulin-colchicine complex (TC) inhibits microtubule polymerization in vitro by using the axoneme-directed polymerization system (Bergen, L. G., and Borisy, G. G. (1980) J. Cell Biol. 84, 141-150). With this system, the growth properties of each microtubule end can be determined from the direct visual analysis of changes in lengths of seeded microtubules. The rate of growth at both ends was inhibited equally by TC and the magnitude of the inhibition increased progressively with the molar ratio of TC to tubulin dimer (TC:T). At a TC:T ratio of approximately 0.12, all microtubule polymerization was inhibited at both ends. Therefore, substoichiometric poisoning of microtubule elongation is both a nonpolar and graded phenomenon. We determined the four association and dissociation rate constants in the presence and absence of TC and found that TC inhibits the overall growth of microtubules by reducing the association rate constants at both ends under conditions that do not alter the dissociation rate constants. Therefore, by an independent analytical method, we have confirmed Sternlicht and Ringel's hypothesis of TC action (Sternlicht, H., and Ringel, I. (1979) J. Biol. Chem. 254, 10540-10550), and have extended this hypothesis 1) by demonstrating that net growth of both ends are equally inhibited by TC, and 2) by determining which changes in the separate rate constants were responsible for the net inhibition.

Head-to-tail polymerization of microtubules in vitro. Electron microscope analysis of seeded assembly.

Microtubules are polar structures, and this polarity is reflected in their biased directional growth. Following a convention established previously (G. G. Borisy, 1978, J. Mol. Biol. 124:565--570), we define the plus (+) and minus (-) ends of a microtubule as those equivalent in structural orientation to the distal and proximal ends, respectively, of the A subfiber of flagellar outer doublets. Rates of elongation were obtained for both ends using flagellar axonemes as seeds and porcine brain microtubule protein as subunits. Since the two ends of a flagellar seed are distinguishable morphologically, elongation of each end may be analyzed separately. By plotting rates of elongation at various concentrations of subunit protein, we have determined the association and dissociation rate constants for the plus and minus ends. Under our conditions at 30 degrees C, the association constants were 7.2 X 10(6) M-1 s-1 and 2.25 X 10(6) M-1 s-1 for the plus and minus ends, respectively, and the dissociation constants were 17 s-1 and 7 s-1. From these values and Wegner's equations (1976, J. Mol. Biol. 108:139--150), we identified the plus end of the microtubule as its head and calculated "s," the head-to-tail polymerization parameter. Surprisingly small values (s = 0.07 +/- 0.02) were found. The validity of models of mitosis based upon head-to-tail polymerization (Margolis et al., 1978, Nature (Lond.) 272:450--452) are discussed in light of a small value for s.

Polarity of microtubules nucleated by centrosomes and chromosomes of Chinese hamster ovary cells in vitro.

The structural and growth polarities of centrosomal and chromosomal microtubules were studied by analyzing the kinetics of growth of these microtubules and those initiated by flagellar seeds. By comparing rates of elongation of centrosomal and flagellar-seeded microtubules, we determined whether the centrosomal microtubules were free to grow at their plus ends only, minus ends ony, or at both ends. Our results show that centrosomal microtubules elongate at a rate corresponding to the addition of subunits at the plus end only. The depolymerization rate was also equivalent to that for the plus end only. Chromosomal microtubule elongation was similar to the centrosome-initiated growth. Since the data do not support the hypothesis that both ends of these spindle microtubules are able to interact with monomer in solution, then growth must occur only distal or only proximal to the organizing centers, implying tha the opposite ends in unavailable for exchange of subunits. Experiments with flagellar-seeded microtubules serving as internal controls indicated that the inactivity of the minus end could not be accounted for by a diffusible inhibitor, suggesting a structural explanation. Since there is no apparent way in which the distal ends may be capped, whereas the proximal ends are embedded in the pericentriolar cloud, we conclude that centrosomal microtubules are oriented with their plus ends distal to the site of nucleation. A similar analysis for chromosomal microtubules suggests that they too must be oriented with their plus ends distal to the site of initiation.