Chemically modified tetracyclines act through multiple mechanisms directly on osteoclast precursors.

Chemically modified tetracyclines (CMTs) are thought to inhibit bone resorption primarily through their ability to inhibit matrix metalloproteinases (MMPs). We have previously demonstrated that some tetracycline compounds (TCs) induce apoptosis in mature rabbit osteoclasts and inhibit osteoclastic resorption in mouse osteoblast/marrow co-cultures in vitro. In this report, we now show that non-antibiotic analogues of doxycycline (CMT-3) and minocycline (CMT-8) are potent inhibitors of osteoclastogenesis in vitro from human peripheral blood mononuclear cells (PBMC) stimulated with macrophage colony stimulating factor (MCSF) and receptor activator of NF-kappaB ligand (RANKL), through an action that is independent of osteoblast-osteoclast interactions. Osteoclast formation over 20 days was completely abrogated when CMT-3 or CMT-8 were included in PBMC cultures at a concentration of 250 ng/ml, although doxycycline at this concentration reduced osteoclast formation to ca. 50% of control. CMT-3 and CMT-8 also significantly induced apoptosis over 24 h in mature osteoclasts generated over 20 days when added to cultures at 5 microg/ml or more. In a time-course experiment, apoptosis was evident after a delay of 1-2 h following treatment of mature osteoclasts with CMT-3 at 20 microg/ml. The broad-spectrum MMP inhibitor BB94 (Batimastat) did not recapitulate the apoptosis induced by CMT-3, even at a concentration where MMP-13 activity was completely inhibited. There was no evidence for an anabolic effect of any of the TCs on osteoblast lineage cells in a calcifying fibroblastic colony (CFU-f) formation assay, where CMT-3 partially inhibited CFU-f formation at 5 microg/ml. Our data indicate that inhibition of osteoclast formation and induction of osteoclast apoptosis are pharmacologically significant actions of CMTs in inhibiting bone resorption, and that osteoclast apoptosis cannot be attributed to the ability of CMTs to inhibit MMPs or to actions mediated by osteoblastic lineage cells.

Replication of minichromosomes in Saccharomyces cerevisiae is sensitive to histone gene copy number and strain ploidy.

We have characterized a defect in the mitotic transmission of plasmid minichromosomes in yeast strains deleted for the more highly expressed pair of histone H3 and H4 genes. Several observations indicate that an impairment in DNA replication contributes to the decrease in minichromosome stability. First, the maintenance of ARS plasmids that lack centromeres was also defective. Second, the addition of multiple ARS elements suppressed the defect in plasmid maintenance. Third, a synergistic increase in plasmid loss rate was seen when a plasmid containing an inefficient mutated ARS was tested in a strain deleted for histone genes, implying an interaction between ARS activity and the histone gene deletion. These results support the existence of a histone-dependent step in the initiation of DNA replication. We find that the stability of native chromosomes is not affected in strains deleted for histone genes. We propose that reduced histone H3 and H4 protein decreases the efficiency of initiation at ARS elements on plasmids and chromosomes, but that the presence of multiple origins on chromosomes compensates for the reduced efficiency. We find that decreased minichromosome stability is suppressed by increases in strain ploidy. The greater stability due to ploidy increases is not due to a relative increase in the expression of histone genes. We discuss models for the effect of strain ploidy on minichromosome maintenance.

MGA2 and SPT23 are modifiers of transcriptional silencing in yeast.

Transcriptional silencing at the HM loci and telomeres in yeast depends on several trans-acting factors, including Rap1p and the Sir proteins. The SUM1-1 mutation was identified by its ability to restore silencing to strains deficient in one or more of these trans-acting factors. The mechanism by which SUM1-1 bypasses the requirement for silencing proteins is not known. We identified four loci that when reduced in dosage in diploid strains increase the ability of SUM1-1 strains to suppress silencing defects. Two of the genes responsible for this effect were found to be MGA2 and SPT23. Mga2p and Spt23p were previously identified as functionally related transcription factors that influence chromatin structure. We find that deletion of MGA2 or SPT23 also increases the efficiency of silencing in haploid SUM1-1 strains. These results suggest that Mga2p and Spt23p are antagonists of silencing. Consistent with this proposal we find that deletion of MGA2 or SPT23 also suppresses the silencing defects caused by deletion of the SIR1 gene or by mutations in the HMR silencer sequences. However, we find that Mga2p and Spt23p can positively affect silencing in other contexts; deletion of either MGA2 or SPT23 decreases mating in strains bearing mutations in the HML-E silencer. Mga2p and Spt23p appear to be a novel class of factors that influence disparate pathways of transcriptional control by chromatin.

Hyperactivation of the silencing proteins, Sir2p and Sir3p, causes chromosome loss.

The SIRgene products maintain transcriptional repression at the silent mating type loci and telomeres in Saccharomyces cerevisiae, although no enzymatic or structural activity has been assigned to any of the Sir proteins nor has the role of any of these proteins in transcriptional silencing been clearly defined. We have investigated the functions and interactions of the Sir2, Sir3, and Sir4 proteins by overexpressing them in yeast cells. We find that Sir2p and Sir3p are toxic when overexpressed, while high Sir4p levels have no toxic effect. Epistasis experiments indicate that Sir2p-induced toxicity is diminished in strains lacking the SIR3 gene, while both Sir2p and Sir4p are required for Sir3p to manifest its full toxic effect. In addition, the effects of Sir2 or Sir3 overexpression are exacerbated by specific mutations in the N-terminus of the histone H4 gene. These results are consistent with a model in which Sir2p, Sir3p and Sir4p function as a complex and interact with histones to modify chromatin structure. We find no evidence that toxicity from high levels of the Sir proteins results from widespread repression of transcription. Instead, we find that high levels of Sir2p and/or Sir3p cause a profound decrease in chromosome stability. These results can be appreciated in the context of the effects of Sir2p in histone acetylation and of chromatin structure on chromosome stability.

Silencers are required for inheritance of the repressed state in yeast.

Transcriptional silencers in the yeast Saccharomyces induce position-specific, sequence-independent repression by promoting formation of a heterochromatin-like structure across sequences adjacent to them. We have examined the role of silencers in maintenance and inheritance of repression at the silent mating-type cassettes in yeast by monitoring the expression state of one of these cassettes following in vivo deletion of the adjacent silencer. Our experiments indicate that although silencer sequences are dispensable for the maintenance of repression in the absence of cell-cycle progression, silencers are required for the stable inheritance of a repressed state. That is, silenced loci from which the silencer is deleted most often become derepressed within one generation of losing the silencer. Thus, the heritability of a repressed state is not intrinsic to a silenced locus or to the chromatin encompassing it; rather, heritability of repression appears to be a property of the silencer itself.

Transcriptional silencing in yeast is associated with reduced nucleosome acetylation.

Two classes of sequences in the yeast Saccharomyces cerevisiae are subject to transcriptional silencing: the silent mating-type cassettes and telomeres. In this report we demonstrate that the silencing of these regions is strictly associated with acetylation of the epsilon-amino groups of lysines in the amino-terminal domains of three of the four core histones. Both the silent mating-type cassettes and the Y domains of telomeres are packaged in nucleosomes in vivo that are hypoacetylated relative to those packaging active genes. This difference in acetylation is eliminated by genetic inactivation of silencing: The silent cassettes from sir2, sir3, or sir4 cells show the same level of acetylation as other active genes. The correspondence of silencing and hypoacetylation of the mating-type cassettes is observed even for an allele lacking a promoter, indicating that silencing per se, rather than the absence of transcription, is correlated with hypoacetylation. Finally, overexpression of Sir2p, a protein required for transcriptional silencing in yeast, yields substantial histone deacetylation in vivo. These studies fortify the hypothesis that silencing in yeast results from heterochromatin formation and argue that the silencing proteins participate in this formation.

The chromatin structure of Saccharomyces cerevisiae autonomously replicating sequences changes during the cell division cycle.

The chromatin structures of two well-characterized autonomously replicating sequence (ARS) elements were examined at their chromosomal sites during the cell division cycle in Saccharomyces cerevisiae. The H4 ARS is located near one of the duplicate nonallelic histone H4 genes, while ARS1 is present near the TRP1 gene. Cells blocked in G1 either by alpha-factor arrest or by nitrogen starvation had two DNase I-hypersensitive sites of about equal intensity in the ARS element. This pattern of DNase I-hypersensitive sites was altered in synchronous cultures allowed to proceed into S phase. In addition to a general increase in DNase I sensitivity around the core consensus sequence, the DNase I-hypersensitive site closest to the core consensus became more nuclease sensitive than the distal site. This change in chromatin structure was restricted to the ARS region and depended on replication since cdc7 cells blocked near the time of replication initiation did not undergo the transition. Subsequent release of arrested cdc7 cells restored entry into S phase and was accompanied by the characteristic change in ARS chromatin structure.

Interaction of the H4 autonomously replicating sequence core consensus sequence and its 3'-flanking domain.

Yeast autonomously replicating sequence (ARS) elements are composed of a conserved 11-base-pair (bp) core consensus sequence and a less well defined 3'-flanking region. We have investigated the relationship between the H4 ARS core consensus sequence and its 3'-flanking domain. The minimal sequences necessary and sufficient for function were determined by combining external 3' and 5' deletions to produce a nested set of ARS fragments. Sequences 5' of the core consensus were dispensable for function, but at least 66 bp of 3'-flanking domain DNA was required for full ARS function. The importance of the relative orientation of the core consensus element with respect to the 3'-flanking domain was tested by precisely inverting 14 bp of DNA including the core consensus sequence by oligonucleotide mutagenesis. This core inversion mutant was defective for all ARS function, showing that a fixed relative orientation of the core consensus and 3'-flanking domain is required for function. The 3'-flanking domain of the minimal functional H4 ARS fragment contains three sequences with a 9-of-11-bp match to the core consensus. The role of these near-match sequences was tested by directed mutagenesis. When all near-match sequences with an 8-of-11-bp match or better were simultaneously disrupted by point mutations, the resulting ARS construct retained full replication function. Therefore, multiple copies of a sequence closely related to the core consensus element are not required for H4 ARS function.