The polarity and dynamics of microtubule assembly in the budding yeast Saccharomyces cerevisiae.

Microtubule assembly in Saccharomyces cerevisiae is initiated from sites within spindle pole bodies (SPBs) in the nuclear envelope. Microtubule plus ends are thought to be organized distal to the SPBs, while minus ends are proximal. Several hypotheses for the function of microtubule motor proteins in force generation and regulation of microtubule assembly propose that assembly and disassembly occur at minus ends as well as at plus ends. Here we analyse microtubule assembly relative to the SPBs in haploid yeast cells expressing green fluorescent protein fused to alpha-tubulin, a microtubule subunit. Throughout the cell cycle, analysis of fluorescent speckle marks on cytoplasmic astral microtubules reveals that there is no detectable assembly or disassembly at minus ends. After laser-photobleaching, metaphase spindles recover about 63% of the bleached fluorescence, with a half-life of about 1 minute. After anaphase onset, photobleached marks in the interpolar spindle are persistent and do not move relative to the SPBs. In late anaphase, the elongated spindles disassemble at the microtubule plus ends. These results show for astral and anaphase interpolar spindle microtubules, and possibly for metaphase spindle microtubules, that microtubule assembly and disassembly occur at plus, and not minus, ends.

Chromatin conformation of yeast centromeres.

The centromere region of Saccharomyces cerevisiae chromosome III has been replaced by various DNA fragments from the centromere regions of yeast chromosomes III and XI. A 289-base pair centromere (CEN3) sequence can stabilize yeast chromosome III through mitosis and meiosis. The orientation of the centromeric fragments within chromosome III has no effect on the normal mitotic or meiotic behavior of the chromosome. The structural integrity of the centromere region in these genomic substitution strains was examined by mapping nucleolytic cleavage sites within the chromatin DNA. A nuclease-protected centromere core of 220-250 base pairs was evident in all of the genomic substitution strains. The position of the protected region is determined strictly by the centromere DNA sequence. These results indicate that the functional centromere core is contained within 220-250 base pairs of the chromatin DNA that is structurally distinct from the flanking nucleosomal chromatin.

Fractionation and characterization of chromosomal proteins by the hydroxyapatite dissociation method.

A method was developed which enables the characterization and fractionation of chromosomal proteins according to their chromatin binding properties. The method is based on the ability of hydroxyapatite to bind native chromatin in solutions which do not dissocciate chromosomal proteins from the DNA. The proteins are then selectively dissociated from the immobilized chromatin by treatment with NaCl, urea, or guanidine HCl. The hydroxyapatite dissociation method represents a rapid one-step fractionation procedure which results in the quantitative recovery of chromosomal proteins devoid of nucleic acids and is suitable for large preparations. The hydroxyapatite dissociation method provides a versatile procedure for the study and preparation of chromosomal proteins. The patterns of dissociation of both histones and nonhistone chromosomal proteins by NaCl and urea from chicken oviduct chromatin were characterized by this method. In addition, this technique enabled the purification of the major histone species in a single operation. Partial purification of specific nonhistone proteins, including the estrogen receptor, was also achieved. We suggest that this method will be a useful tool in elucidation of the chemical and biological properties of the proteins from chromatin.

Yeast centromere DNA is in a unique and highly ordered structure in chromosomes and small circular minichromosomes.

We have examined the chromatin structure of the centromere regions of chromosomes III and XI in yeast by using cloned functional centromere DNAs (CEN3 and CEN11) as labeled probes. When chromatin from isolated nuclei is digested with micrococcal nuclease and the resulting DNA fragments separated electrophoretically and blotted to nitrocellulose filters, the centromeric nucleosomal subunits are resolved into significantly more distinct ladders than are those from the bulk of the chromatin. A discrete protected region of 220-250 bp of CEN sequence flanked by highly nuclease-sensitive sites was revealed by mapping the exact nuclease cleavage sites within the centromeric chromatin. On both sides of this protected region, highly phased and specific nuclease cutting sites exist at nucleosomal intervals (160 bp) for a total length of 12-15 nucleosomal subunits. The central protected region in the chromatin of both centromeres spans the 130 bp segment that exhibits the highest degree of sequence homology (71%) between functional CEN3 and CEN11 DNAs. This unique chromatin structure is maintained on CEN sequences introduced into yeast on autonomously replicating plasmids, but is not propagated through foreign DNA sequences flanking the inserted yeast DNA.

Hormonal regulation of the conformation of the ovalbumin gene in chick oviduct chromatin.

We have examined the effects of steroid hormones in the chromatin sensitivity of the ovalbumin gene to micrococcal nuclease and have attempted to define the importance of the nucleosome core, higher order chromatin folding, and transcription in the maintenance of the nuclease-sensitive conformation of the ovalbumin chromatin. Solution hybridization studies demonstrated that the sensitivity of the ovalbumin gene in oviduct nuclei to micrococcal nuclease paralleled the hormone-dependent transcription of the ovalbumin gene in the immature chick. Blot hybridization analysis also revealed a hormone-dependent change in this chromatin region since ovalbumin DNA fragments from nuclease-treated hen and estrogen-stimulated chick oviduct nuclei exhibited nucleosomal repeat patterns that were less discrete than those observed for the ovalbumin specific fragments from liver and hormone-withdrawn oviducts. This transcription-related conformation was not the result of enhanced sensitivity of the ovalbumin-containing nucleosomal cores since the bulk of the nucleosomes associated with the ovalbumin chromatin were not preferentially cleaved internally by micrococcal nuclease. Rather, an analysis of the fragmentation of the ovalbumin chromatin as a function of digestion extent suggested a mechanism in which the heightened sensitivity resulted from the collective expansion of the nuclease cutting sites in the linker regions of the ovalbumin chromatin because the gene was in an unfolded conformation. The transcription-specific conformation was not merely a consequence of RNA synthesis per se since the selective sensitivity of the gene was unaffected by treatment of oviduct nuclei with alpha-amanitin, actinomycin D, or RNase. In addition, the presence of the transcriptional complex on the ovalbumin chromatin was presumably not required for selective nuclease recognition since preferential cleavage was observed under conditions expected to deplete oviduct nuclei of template-bound RNA polymerase and nascent RNA chains. These results are consistent with a model in which the expressed ovalbumin gene is in an unfolded polynucleosomal structure whose formation is related to transcriptional activity but not dependent on the transcriptional process.

Change in size distribution of active polyribosomes associated with puff induction in Drosophila melanogaster salivary glands.

The polytene cells of Drosophila melanogaster larvae are ideally suited for the study of gene information flow during differentiation, in that gene derepression is visualized in the form of chromosomal modifications called puffs. One special group of temperature-sensitive puffs can be experimentally induced within 5 min after transfer of salivary glands from 24-37 degrees C. Glands at 37 degrees C also begin synthesizing several new polypeptides which are of higher molecular weight than the prominent polypeptides being synthesized in glands at 24 degrees C [1]. The present study demonstrates that there is also a shift toward the utilization of heavier or more rapidly sedimenting polyribosomes for protein synthesis in glands transferred from 24-37 degrees C. As a result of such studies it is reasonable to assume that the polyribosome redistribution after a heat shock results from the translation of larger mRNA molecules synthesized by the temperature-sensitive loci. Further studies are suggested to describe the role of heat-induced gene activity in maintaining homeostasis, as well as the manner by which such activity is induced, in cells subjected to dramatic temperature fluctuations.

Chromatin structures of Kluyveromyces lactis centromeres in K. lactis and Saccharomyces cerevisiae.

We have investigated the chromatin structure of Kluyveromyces lactis centromeres in isolated nuclei of K. lactis and Saccharomyces cerevisiae by using micrococcal nuclease and DNAse I digestion. The protected region found in K. lactis is approximately 270 bp long and encompasses the centromeric DNA elements, KlCDEI, KlCDEII, and KlCDEIII, but not KlCDE0. Halving KlCDEII to 82 bp impaired centromere function and led to a smaller protected structure (210 bp). Likewise, deletion of 5 bp from KlCDEI plus adjacent flanking sequences resulted in a smaller protected region and a decrease in centromere function. The chromatin structures of KlCEN2 and KlCEN4 present on plasmids were found to be similar to the structures of the corresponding centromeres in their chromosomal context. A different protection pattern of KlCEN2 was detected in S. cerevisiae, suggesting that KlCEN2 is not properly recognized by at least one of the centromere binding proteins of S. cerevisiae. The difference is mainly found at the KlCDEIII side of the structure. This suggests that one of the components of the ScCBF3-complex is not able to bind to KlCDEIII, which could explain the species specificity of K. lactis and S. cerevisiae centromeres.