Natural products inducing nucleolar stress: implications in cancer therapy.

The nucleolus is the site of ribosome biogenesis and is found to play an important role in stress sensing. For over 100 years, the increase in the size and number of nucleoli has been considered as a marker of aggressive tumors. Despite this, the contribution of the nucleolus and the biologic processes mediated by it to cancer pathogenesis has been largely overlooked. This state has been changed over the recent decades with the demonstration that the nucleolus controls numerous cellular functions associated with cancer development. Induction of nucleolar stress has recently been regarded as being superior to conventional cytotoxic/cytostatic strategy in that it is more selective to neoplastic cells while sparing normal cells. Natural products represent an excellent source of bioactive molecules and some of them have been found to be able to induce nucleolar stress. The demonstration of these nucleolar stress-inducing natural products has paved the way for a new therapeutic approach to more delicate tumor cell-killing. This review provides a contemporary summary of the role of the nucleolus as a novel promising target for cancer therapy, with particular emphasis on natural products as an exciting new class of anti-cancer drugs with nucleolar stress-inducing properties.

Macrolide Resistance in Treponema pallidum Correlates With 23S rDNA Mutations in Recently Isolated Clinical Strains.

BACKGROUND: High rates of 23S rDNA mutations implicated in macrolide resistance have been identified in Treponema pallidum samples from syphilis patients in many countries. Nonetheless, some clinicians have been reluctant to abandon azithromycin as a treatment for syphilis, citing the lack of a causal association between these mutations and clinical evidence of drug resistance. Although azithromycin resistance has been demonstrated in vivo for the historical Street 14 strain, no recent T. pallidum isolates have been tested. We used the well-established rabbit model of syphilis to determine the in vivo efficacy of azithromycin against 23S rDNA mutant strains collected in 2004 to 2005 from patients with syphilis in Seattle, Wash. METHODS: Groups of 9 rabbits were each infected with a strain containing 23S rDNA mutation A2058G (strains UW074B, UW189B, UW391B) or A2059G (strains UW228B, UW254B, and UW330B), or with 1 wild type strain (Chicago, Bal 3, and Mexico A). After documentation of infection, 3 animals per strain were treated with azithromycin, 3 were treated with benzathine penicillin G, and 3 served as untreated control groups. Treatment efficacy was documented by darkfield microscopic evidence of T. pallidum, serological response, and rabbit infectivity test. RESULTS: Azithromycin uniformly failed to cure rabbits infected with strains harboring either 23S rDNA mutation, although benzathine penicillin G was effective. Infections caused by wild type strains were successfully treated by either azithromycin or benzathine penicillin G. CONCLUSIONS: A macrolide resistant phenotype was demonstrated for all strains harboring a 23S rDNA mutation, demonstrating that either A2058G or A2059G mutation confers in vivo drug resistance.

Ellagic Acid-Changed Epigenome of Ribosomal Genes and Condensed RPA194-Positive Regions of Nucleoli in Tumour Cells.

We studied the effect of ellagic acid (EA) on the morphology of nucleoli and on the pattern of major proteins of the nucleolus. After EA treatment of HeLa cells, we observed condensation of nucleoli as documented by the pattern of argyrophilic nucleolar organizer regions (AgNORs). EA also induced condensation of RPA194-positive nucleolar regions, but no morphological changes were observed in nucleolar compartments positive for UBF1/2 proteins or fibrillarin. Studied morphological changes induced by EA were compared with the morphology of control, non-treated cells and with pronounced condensation of all nucleolar domains caused by actinomycin D (ACT-D) treatment. Similarly as ACT-D, but in a lesser extent, EA induced an increased number of 53BP1-positive DNA lesions. However, the main marker of DNA lesions, γH2AX, was not accumulated in body-like nuclear structures. An increased level of γH2AX was found by immunofluorescence and Western blots only after EA treatment. Intriguingly, the levels of fibrillarin, UBF1/2 and γH2AX were increased at the promoters of ribosomal genes, while 53BP1 and CARM1 levels were decreased by EA treatment at these genomic regions. In the entire genome, EA reduced H3R17 dimethylation. Taken together, ellagic acid is capable of significantly changing the nucleolar morphology and protein levels inside the nucleolus.

Nicotinamide induces Fob1-dependent plasmid integration into chromosome XII in Saccharomyces cerevisiae.

In the ribosomal DNA (rDNA) array of Saccharomyces cerevisiae, DNA replication is arrested by the Fob1 protein in a site-specific manner that stimulates homologous recombination. The silent information regulator Sir2, which is loaded at the replication arrest sites by Fob1, suppresses this recombination event. A plasmid containing Fob1-binding sites, when propagated in a yeast strain lacking SIR2 is integrated into the yeast chromosome in a FOB1-dependent manner. We show that addition of nicotinamide (NAM) to the culture medium can stimulate such plasmid integration in the presence of SIR2. Pulsed-field gel electrophoresis analysis showed that plasmid integration occurred into chromosome XII. NAM-induced plasmid integration was dependent on FOB1 and on the homologous recombination gene RAD52. As NAM inhibits several sirtuins, we examined plasmid integration in yeast strains containing deletions of various sirtuin genes and observed that plasmid integration occurred only in the absence of SIR2, but not in the absence of other histone deacetylases. In the absence of PNC1 that metabolizes NAM, a reduced concentration of NAM was required to induce plasmid integration in comparison with that required in wild-type cells. This study suggests that NAD metabolism and intracellular NAM concentrations are important in Fob1-mediated rDNA recombination.

Identification of dendrobium species used for herbal medicines based on ribosomal DNA internal transcribed spacer sequence.

Stems of genus Dendrobium (Orchidaceae) have been traditionally used as an herbal medicine (Dendrobii Herba) in Eastern Asia. Although demand for Dendrobium is increasing rapidly, wild resources are decreasing due to over-collection. This study aimed to identify plant sources of Dendrobii Herba on the market based on sequences of the internal transcribed spacer (ITS) regions of nuclear ribosomal DNA. We constructed an ITS1-5.8S-ITS2 sequence database of 196 Dendrobium species, and the database was employed to identify 21 herbal samples. We found that 13 Dendrobium species (D. catenatum, D. cucullatum, D. denudans, D. devonianum, D. eriiflorum, D. hancockii, D. linawianum, D. lituiflorum, D. loddigesii, D. polyanthum, D. primulinum, D. regium, and D. transparens) were possibly used as plant sources of Dendrobii Herba, and unidentified species allied to D. denudans, D. eriiflorum, D. gregulus, or D. hemimelanoglossum were also used as sources. Furthermore, it is clear that D. catenatum is one of the most important sources of Dendrobii Herba (5 out of 21 samples).

Cyclin-dependent kinases govern formation and maintenance of the nucleolus.

In higher eukaryotic cells, the nucleolus is a nuclear compartment assembled at the beginning of interphase, maintained during interphase, and disorganized during mitosis. Even if its structural organization appears to be undissociable from its function in ribosome biogenesis, the mechanisms that govern the formation and maintenance of the nucleolus are not elucidated. To determine if cell cycle regulators are implicated, we investigated the putative role of the cyclin-dependent kinases (CDKs) on ribosome biogenesis and nucleolar organization. Inhibition of CDK1-cyclin B during mitosis leads to resumption of rDNA transcription, but is not sufficient to induce proper processing of the pre-rRNA and total relocalization of the processing machinery into rDNA transcription sites. Similarly, at the exit from mitosis, both translocation of the late processing machinery and pre-rRNA processing are impaired in a reversible manner by CDK inhibitors. Therefore, CDK activity seems indispensable for the building of functional nucleoli. Furthermore, inhibition of CDKs in interphasic cells also hampered proper pre-rRNA processing and induced a dramatic disorganization of the nucleolus. Thus, we propose that the mechanisms governing both formation and maintenance of functional nucleoli involve CDK activities and couple the cell cycle to ribosome biogenesis.

Different chromatin structures along the spacers flanking active and inactive Xenopus rRNA genes.

The accessibility of DNA in chromatin to psoralen was assayed to compare the chromatin structure of the rRNA coding and spacer regions of the two related frog species Xenopus laevis and Xenopus borealis. Isolated nuclei from tissue culture cells were photoreacted with psoralen, and the extent of cross-linking in the different rDNA regions was analyzed by using a gel retardation assay. In both species, restriction fragments from the coding regions showed two distinct extents of cross-linking, indicating the presence of two types of chromatin, one that contains nucleosomes and represents the inactive gene copies, and the other one which is more cross-linked and corresponds to the transcribed genes. A similar cross-linking pattern was obtained with restriction fragments from the enhancer region. Analysis of fragments including these sequences and the upstream portions of the genes suggests that active genes are preceded by nonnucleosomal enhancer regions. The spacer regions flanking the 3' end of the genes gave different results in the two frog species. In X. borealis, all these sequences are packaged in nucleosomes, whereas in X. laevis a distinct fraction, presumably those flanking the active genes, show a heterogeneous chromatin structure. This disturbed nucleosomal organization correlates with the presence of a weaker terminator at the 3' end of the X. laevis genes compared with those of X. borealis, which allows polymerases to transcribe into the downstream spacer.

Glucocorticoids selectively inhibit translation of ribosomal protein mRNAs in P1798 lymphosarcoma cells.

When P1798 murine lymphosarcoma cells are exposed to 10(-7) M dexamethasone, there is a dramatic inhibition of rRNA synthesis, which is completely reversible when the hormone is withdrawn. In the present experiments we examined whether dexamethasone treatment causes any alteration in the accumulation or utilization of mRNAs that encode ribosomal proteins (rp mRNAs). No effect on the accumulation of six different rp mRNAs was detected. However, the translation of five of six rp mRNAs was selectively inhibited in the presence of the hormone, as judged by a substantial decrease in ribosomal loading. Normal translation of rp mRNA was resumed within a few hours after hormone withdrawal. In untreated or fully recovered cells, the distribution of rp mRNAs between polyribosomes and free ribonucleoprotein is distinctly bimodal, suggesting that rp mRNAs are subject to a particular form of translational control in which they are either translationally inactive or fully loaded with ribosomes. A possible relationship between this mode of translational control and the selective suppression of rp mRNA translation by glucocorticoids is discussed.

First report of homoanatoxin-a and associated dog neurotoxicosis in New Zealand.

In November 2005, at least five dogs died rapidly after contact with water from the Hutt River (lower North Island, New Zealand). Necropsy performed 24h later on one of the dogs (a 20-month-old Labrador) revealed few findings of interest, except for copious amounts of froth in the respiratory tract down to the bifurcation of the trachea and large quantities of algal material in the dog's stomach. Low and relatively stable flows in the Hutt River during spring had resulted in the proliferation of benthic cyanobacteria that formed large black/brown mats along the river edge. Samples from the Labrador's stomach contents and cyanobacterial mats were analysed microscopically and screened using chemical and biochemical assays for cyanotoxins: anatoxin-a, homoanatoxin-a, cylindrospermopsins, saxitoxins and microcystins. Liquid chromatography-mass spectrometry (LC-MS) confirmed the presence of the neurotoxic cyanotoxins anatoxin-a and homoanatoxin-a and their degradation products, dihydro-anatoxin-a and dihydro-homoanatoxin-a. This is the first report of homoanatoxin-a and associated degradation product in New Zealand. Based on morphology, the causative species was identified as Phormidium sp. Subsequent phylogenetic analysis of 16S rRNA gene sequences demonstrated that the causative organism was most similar to Phormidium autumnale. Further investigations led to the detection of homoanatoxin-a and anatoxin-a in cyanobacterial mats from four other rivers in the Wellington region (lower North Island, New Zealand). Access restrictions were placed on over 60% of river catchments in the western Wellington region, severely affecting recreational users.

Specific inhibition of pre-ribosomal RNA processing in extracts from the lymphosarcoma cells treated with 5-fluorouracil.

To elucidate the molecular mechanism by which the potent anticancer drug, 5-fluorouracil (5-FUra), inhibits cell proliferation, the effect of its metabolite, 5-fluorouridine triphosphate, on transcription of rat rRNA gene and processing of pre-rRNA was investigated in S-100 extract from the mouse lymphosarcoma cells. The in vitro processing of pre-rRNA substrate synthesized from the T3 promoter occurred at the correct primary processing site. Replacement of UMP with 5-fluorouridine monophosphate in the rRNA substrate did not affect the pre-rRNA processing. Similar result was obtained when coupled transcription-processing was studied. When the coupled reaction was examined using extracts from the cells treated with 5-FUra, rRNA processing was abolished whereas transcription of rRNA gene was unaffected. Treatment of cells with thymidine along with 5-FUra did not reverse the inhibitory effect of the drug on rRNA processing. In contrast to the effect on rRNA processing, treatment of cells with 5-FUra did not impede the 3' end processing of pre-mRNA. These data show that inhibition of pre-rRNA processing is a major mechanism of action of 5-FUra and suggest that the activity and/or synthesis of a trans-acting factor(s) involved in this reaction is altered by the anticancer drug.

rDNA Copy Number Variants Are Frequent Passenger Mutations in Saccharomyces cerevisiae Deletion Collections and de Novo Transformants.

The Saccharomyces cerevisiae ribosomal DNA (rDNA) locus is known to exhibit greater instability relative to the rest of the genome. However, wild-type cells preferentially maintain a stable number of rDNA copies, suggesting underlying genetic control of the size of this locus. We performed a screen of a subset of the Yeast Knock-Out (YKO) single gene deletion collection to identify genetic regulators of this locus and to determine if rDNA copy number correlates with yeast replicative lifespan. While we found no correlation between replicative lifespan and rDNA size, we identified 64 candidate strains with significant rDNA copy number differences. However, in the process of validating candidate rDNA variants, we observed that independent isolates of our de novo gene deletion strains had unsolicited but significant changes in rDNA copy number. Moreover, we were not able to recapitulate rDNA phenotypes from the YKO yeast deletion collection. Instead, we found that the standard lithium acetate transformation protocol is a significant source of rDNA copy number variation, with lithium acetate exposure being the treatment causing variable rDNA copy number events after transformation. As the effects of variable rDNA copy number are being increasingly reported, our finding that rDNA is affected by lithium acetate exposure suggested that rDNA copy number variants may be influential passenger mutations in standard strain construction in S. cerevisiae.

Induction and recovery of double-strand breaks in barley ribosomal DNA.

Barley nucleolus organizing regions (NORs) were previously found to behave as prominent aberration hot-spots after treatment with some restriction endonucleases. The ability of MspI for directed induction of double-strand breaks in barley ribosomal DNA was further analyzed. Ionizing radiation-produced strand breakage within the ribosomal gene clusters was also a subject of investigation. Reconstructed barley karyotypes T1586 and T35 with normal and increased expression of rRNA genes were utilized to evaluate the relationship between transcriptional activity and damage induction. Scanning densitometry of the hybridization profiles revealed that MspI is generating double-strand breaks in barley rDNA with efficiency being independent from the NOR activity. Damage induction observed after treatment with gamma-rays was also not influenced by the transcriptional status of the ribosomal genes. A tendency towards restoration of rDNA integrity after irradiation of both germinating and dry seeds was observed which is indicative for the efficient recovery of double-strand breaks in barley ribosomal DNA.

Zinc induces a bend within the transcription factor IIIA-binding region of the 5 S RNA gene.

Binding of Zn2+ to the 5 S RNA gene sequence of Xenopus borealis results in strong bending of the DNA, as inferred from transient electric birefringence data. The effect is specific for Zn2+; several other divalent ions are not able to induce a bend of a similar magnitude. Using five different fragments that span the binding sequence, we are able to estimate a bend magnitude of at least 55 degrees centered at base-pair +65 within the gene. This places the bend within the binding domain of the gene-regulatory protein transcription factor (TF) IIIA. Recent evidence has shown that the protein-DNA complex is also bent. Although our data do not allow us directly to link the two bends, our results suggest that TFIIIA could form a folded structure by stabilizing the same bent conformation that is induced by binding of Zn2+. The chemistry of Zn2+ binding to DNA, and the sequence around the bend center, suggest that the bend is most probably caused by joint co-ordination of Zn2+ to the N-7 groups of stacked purine residues.

Yeast precursor ribosomal RNA. Molecular cloning and probing the higher-order structure of the internal transcribed spacer I by kethoxal and dimethylsulfate modification.

Plasmids were constructed in which a HindIII fragment of rDNA (6.4 x 10(3) base-pairs) was inserted into vectors pGEM-1 and 2 in both orientations. The DNA insert encoded the yeast 35 S precursor rRNA beginning 180 bases upstream from the 5' end of the mature 18 S rRNA and ending 289 bases beyond the 3' end of the mature 25 S rRNA. The precursor rRNA molecules produced in vitro consisted of 6430 nucleotides, with about 15 residues derived from the Gemini vector on both ends. The general extent of secondary structure of the precursor rRNA was examined by ethidium fluorescence and compared to that of the mature rRNAs. Both precursor and mature rRNAs responded similarly to changes in magnesium ion concentration and to digestion by cobra venom and T1 ribonucleases. The higher-order structure of the internal transcribed spacer-1 (ITS-1) region of the 35 S rRNA molecule was further examined by kethoxal and dimethylsulfate modifications and primer extension. Accessible adenine and guanine residues were located by primer extension analysis with avian myeloblastosis virus reverse transcriptase. On the basis of experimental data and computer-generated structures, a secondary structure model was proposed for the ITS-1 region. In this model, six hairpin stems involving adjacent nucleotides are present. A long-range interaction between nucleotides at the middle of the ITS-1 region and an, as yet, unidentified sequence located at another region of the precursor rRNA is suggested also. A candidate for this interacting sequence is that previously proposed, on a theoretical basis, to be involved in the removal of the precursor 18 S rRNA species for 35 S precursor molecule.

Studies on cycloheximide-sensitive and cycloheximide-resistant ribosomes in the yeast Candida maltosa.

Cycloheximide sensitivity or resistance in yeast is under the control of genes encoding different forms of ribosomal protein L41. In our previous studies, we have shown by isolating L41-Q1a, L41-P1a and their respective allelic genes, L41-Q1b and L41-P1b, from the partial diploid genome of C. maltosa, that this species, which is inducibly resistant to CYH, has both types of the L41 genes and that the expression of at least one of the L41-Q genes is induced by CYH, whereas L41-P genes are constitutively expressed. Here, we have identified another L41 (L41-Q2a), its allelic gene (L41-Q2b) and a third gene (L41-Q3) from the genome of C. maltosa. By gene disruption experiments, we now show that L41-Q1a and L41-Q1b are not responsible for the resistance to CYH and that the DeltaL41-Ps strain, which has only functional L41-Q genes, shows constitutive resistance to CYH, but grows more slowly than the DeltaL41-Qs strain, which has only functional L41-P genes, in the absence of CYH. Our results also show that in vitro, ribosomes containing L41-Q-type are less active in translation than those containing L41-P-type, although only the former ribosomes are active in the presence of CYH. These data suggest that ribosomes containing L41-Q-type are less active under normal growth conditions, but that this activity is not affected in the presence of CYH. We discuss the possible multi-step evolutionary event(s) by which C. maltosa has acquired the property of inducible resistance to CYH.

Brassinolide is a selective ribosomal cistron regulator in onion leaf base tissue.

Outer epidermal cells from the basal, equatorial, near-apical, and apical regions of the third turgid onion (Allium cepa L. var. yellow, sweet Spanish) leaf base were treated (3 and 6 h in the dark = T3 and T6, respectively) with brassinolide (Br, a brassinosteroid plant growth regulator; effects on excised pieces compared with those in water controls: there were no statistical differences between the T3 and T6 results). Br induced increases in the volume and changes in morphologies of the major nucleoli to a greater extent than observed for major nucleoli in basal through near-apical controls. No major nucleoli were activated in control or Br-treated apical tissue. Minor nucleolar organizer regions in control and Br-treated tissue remained inactive in all locations. We propose that Br is a major ribosomal cistron regulator.

Region-specific chromatin decondensation and micronucleus formation induced by 5-azacytidine in human TIG-7 cells.

A human diploid lung fibroblast cell strain, TIG-7, has a heteromorphic chromosome 15 with an extra short arm carrying a homogeneously staining region (15p+hsr). We demonstrated previously that the 15p+hsr consists of an inactive and G+C-rich rDNA cluster characterized by fluorescence in situ hybridization (FISH) and various chromosome banding techniques. Thus, it was suggested that the region could contain highly methylated DNA. To observe methylation status on the target region directly under the microscope, we used a demethylating agent, 5-azacytidine (5-azaC), to induce decondensation of the chromatin containing methylated DNA. At 24 h after treatment with 0.5 microM 5-azaC, marked decondensation of the 15p+hsr was observed in almost all of the metaphases. Furthermore, we observed micronuclei, which were equivalent to the rDNA of the 15p+hsr demonstrated by FISH in the same preparation. In contrast, the DNA cross-linking agent mitomycin C (MMC) preferentially induced 15p+hsr-negative micronuclei. These findings indicated that chromatin decondensation and subsequent DNA strand breakage induced by the demethylating effect of 5-azaC led specifically to 15p+hsr-positive micronuclei.

Studies on the chemopreventive potentials of vegetable oils and unsaturated fatty acids against breast cancer carcinogenesis at initiation.

The effect of dietary fat on breast cancer is a longstanding and an unresolved issue. We found that 17beta-estradiol (E2) could be activated by the epoxide-forming oxidant dimethyldioxirane (DMDO) to bind DNA-forming DNA adducts both in vitro and in vivo, and to inhibit nuclear RNA synthesis. We proposed that E2 epoxidation is the underlying mechanism for the initiation of breast cancer carcinogenesis (Carcinogenesis 17, 1957-61, 1996). This report is on the transcriptional and DNA-binding properties of vegetable oils and fatty acids, and on the potentials of these compounds to prevent the formation of E2 epoxide. The results show that vegetable oils, having no effect on nuclear RNA synthesis either before or after DMDO treatment, were all able to prevent the formation of E2 epoxide independent of their mono- or polyunsaturated fatty acid content. Similarly, unsaturated fatty acids, regardless of chain length and number of double bonds, were all able to prevent the formation of E2 epoxide as reflected by the loss of the ability of [3H]E2 to bind DNA. In contrast to vegetable oils, the results indicated that the unsaturated fatty acids palmitoleic, oleic, linoleic, linolenic and arachidonic acid could be activated by DMDO to inhibit nuclear RNA synthesis, and that the mono-unsaturated fatty acids (i.e. palmitoleic and oleic acid) were stronger inhibitors than fatty acids with more than one double bond (e.g. linoleic, linolenic and arachidonic acid). [32P]Post-labeling analysis revealed that under identical DMDO activation, the DNA adducts formed for oleic acid were 17098 adducts/10(8) nucleotides, which was 20-fold more than palmitoleic acid (815), and 120-fold more than alpha-linolenic acid (142). This result strongly suggests that oleic acid could be a potential initiating carcinogen after epoxidation.

Ribosome-inactivating proteins.

The main results of the research performed in the last 30 years on ribosome-inactivating proteins (RIPs) are reviewed, with emphasis on the new, controversial and uncertain aspects. The nature, distribution, mechanism of action and properties of these proteins are briefly reported, together with their possible applications. A pattern appears of a still largely unexplored subject, whose role in nature is probably important, and not limited to the biology of plants, since RIPs have been found also in other organisms.

E1BF/Ku interacts physically and functionally with the core promoter binding factor CPBF and promotes the basal transcription of rat and human ribosomal RNA genes.

We have previously characterized an RNA polymerase (pol) I transcription factor, E1BF, from rat cells. This protein is immunologically related to Ku autoantigen and is required in pol-I directed transcription of rodent ribosomal RNA gene (rDNA). Glycerol density gradient fractionation and in situ UV cross-linking analysis of the purified factor showed directly that it consists of a heterodimer of 85 and 72 kDa polypeptides. E1BF also interacted with the human core promoter and augmented transcription of human rDNA as much as fivefold in HeLa nuclear extract, whereas transcription from adenovirus major late promoter, CMV or SV40 early promoters by pol II and of U6 and 5S RNA genes by pol III were either unaffected or minimally inhibited by the antibodies. Purified rat E1BF partially restored the suppression of human rDNA transcription by anti-Ku antibodies. Immunoprecipitation of rat cell extract with the anti-Ku antibodies followed by SDS-PAGE of the precipitated proteins and Southwestern analysis showed that E1BF interacts with CPBF, a core promoter binding factor. When the majority of CPBF and E1BF was removed from the reaction mixture by preincubation with a core promoter oligo nucleotide fragment, rDNA transcription was severely impaired. Addition of exogenous CPBF or E1BF to such a reaction resulted in significant restoration of the transcription, whereas inclusion of both factors caused further enhancement of rDNA transcription. These data demonstrate that E1BF is a basal pol I transcription factor that interacts with a core promoter binding factor both physically and functionally, and that is not a general pol II or pol III transcription factor.