Evidence-based Complementary and Alternative Medicine

eCAM Advance Access first published online on July 13, 2009
This version published online on July 15, 2009
eCAM, doi:10.1093/ecam/nep069

This Article Abstract Full Text (PDF) All Versions of this Article: nep069v2    most recent nep069v1 E-letters: Submit a response Alert me when this article is cited Alert me when E-letters are posted Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Add to My Personal Archive Download to citation manager Request Permissions Google Scholar Articles by Qaddouri, B. Articles by Bellaoui, M. Search for Related Content PubMed PubMed Citation Articles by Qaddouri, B. Articles by Bellaoui, M. Social Bookmarking          What's this?

© The Author 2009. Published by Oxford University Press. All rights reserved. For permissions, please email: journals.permissions@oxfordjournals.org

The Budding Yeast ‘Saccharomyces cerevisiae’ as a Drug Discovery Tool to Identify Plant-Derived Natural Products with Anti-Proliferative Properties

Bouchra Qaddouri¹, Abdelkarim Guaadaoui¹, Ahmed Bellirou¹, Abdellah Hamal¹, Ahmed Melhaoui², Grant W. Brown^3,4 and Mohammed Bellaoui^1,5

¹Laboratoire de Génétique et Biotechnologies, ²Département de Biologie, Faculté des Sciences, Université Mohamed Premier, Oujda 60000, Morocco, ³Department of Biochemistry, ⁴Terrence Donnelly Centre for Cellular and Biomolecular Research, University of Toronto, Toronto, ON M5S 1A8, Canada and ⁵Faculté Pluridisciplinaire de Nador, Université Mohamed Premier, B.P: 300 Selouane 62700, Morocco

	Abstract

Top Abstract Introduction Selection of Growth-Inhibitory... Mechanism of Action Conclusion Acknowledgements References

 
The budding yeast Saccharomyces cerevisiae is a valuable system to study cell-cycle regulation, which is defective in cancer cells. Due to the highly conserved nature of the cell-cycle machinery between yeast and humans, yeast studies are directly relevant to anticancer-drug discovery. The budding yeast is also an excellent model system for identifying and studying antifungal compounds because of the functional conservation of fungal genes. Moreover, yeast studies have also contributed greatly to our understanding of the biological targets and modes of action of bioactive compounds. Understanding the mechanism of action of clinically relevant compounds is essential for the design of improved second-generation molecules. Here we describe our methodology for screening a library of plant-derived natural products in yeast in order to identify and characterize new compounds with anti-proliferative properties.

Keywords: anticancer agents – mechanisms of action – medicinal plants – toxicity screen

	Introduction

Top Abstract Introduction Selection of Growth-Inhibitory... Mechanism of Action Conclusion Acknowledgements References

 
Despite an increasing awareness and expenditure of resources, the incidence of cancer has not declined in decades, and, in fact, is rising in some areas at an alarming rate. Despite enormous outlays of research dollars, the number of novel cancer drugs has remained flat over the past two decades. Screening natural products for potential new drugs represents the best avenue to discover new, inexpensive and effective drugs to treat cancer (1,2).

Morocco is very rich in medicinal plants widely used in folk medicine to prevent or cure many diseases. Morocco's unique geography comprises all bioclimatic stages in the Mediterranean zone, with an extraordinarily abundant and diverse vegetation represented by 42 000 plant species. Estimates of the number of medicinal plants used by Moroccan healers suggest that several hundreds of species containing several thousand bio-active compounds could be useful in treating human disease (3–8). However, it is often difficult to identify these bioactive natural compounds and to study their effect at the cellular level or their mechanism of action. Therefore, understanding the role of these natural compounds requires the development of high resolution yet cost-effective biological assay systems.

The budding yeast Saccharomyces cerevisiae is an excellent model system for identifying and studying antifungal compounds because of the functional conservation of fungal genes. Therefore, to accelerate the discovery of bioactive compounds with antifungal activity, Gassner et al. (9) have developed an automated yeast toxicity screen which they call high-throughput (HT) yeast halo assay. Yeast studies have also contributed greatly to our understanding of the biological targets and modes of action of bioactive compounds (10–14). Understanding the mechanism-of-action of clinically relevant compounds is essential for the design of improved second-generation molecules. Yeast-based functional genomics technologies are excellent means for mechanistic studies of clinically relevant compounds. Due to the highly conserved nature of the cell-cycle machinery between yeast and humans, the budding yeast is also an excellent model system to study cell-cycle regulation (15–17), which is defective in cancer cells. Therefore, yeast studies are directly relevant to anticancer-drug discovery (10,18). Here we show, through an example, our procedure for the identification and characterization of new plant-derived natural products with anti-proliferative properties using the budding yeast as a drug discovery tool.

	Selection of Growth-Inhibitory Compounds

Top Abstract Introduction Selection of Growth-Inhibitory... Mechanism of Action Conclusion Acknowledgements References

 
In order to identify new molecules of potential therapeutic interest, we first constructed a library of chemical molecules provided by phytochemists. We next assessed the growth-inhibition effects of these molecules in yeast to identify compounds with antifungal activity. Thus, from 40 plant extracts and 14 purified plant-derived natural molecules analyzed, we identified 14 plant extracts and 8 natural molecules that have clear growth-inhibitory effects. We show here the characterization of Lyc, a plant-derived natural alkaloid product. To assess the effect of Lyc on yeast growth, yeast cells in logarithmic phase were incubated with or without Lyc. As shown in Fig. 1, addition of Lyc resulted in a significantly reduced growth rate of yeast cells, indicating that Lyc exhibited bioactivity in yeast, resulting in inhibition of growth. Using this screen we selected a number of growth-inhibitory compounds that were further characterized in order to understand their mode of action.

View larger version (10K): [in this window] [in a new window] [Download PowerPoint slide]   Figure 1. Growth of wild-type (OD 600 nm) as a function of time. Wild-type cells were diluted from an overnight culture to an OD600 of 0.01 and allowed to grow until the OD600 reached 0.05, ensuring that the cells were in logarithmic phase. Drug was then added and growth rate was measured as the optical density of cells (OD600) as a function of time (h) in rich medium. All compounds were diluted in 100% DMSO, and all assays, including the ‘no compound’ control, contained 1% DMSO. The growth in the presence of 100 µg/ml of natural compound Lyc is presented.

 

	Mechanism of Action

Top Abstract Introduction Selection of Growth-Inhibitory... Mechanism of Action Conclusion Acknowledgements References

 
Cell-Cycle Analysis

Cell-cycle analysis was first undertaken to determine whether a compound causes cell-cycle perturbation. In S. cerevisiae, it is easy to monitor cell-cycle progression by measuring DNA content using Fluorescence-Activated Cell Sorting (FACS) (18). For example, abnormal accumulation of cells with 1C DNA content of an exponentially growing culture usually indicates a defect in the G1 phase of the cell cycle. Thus, to further investigate the growth defect caused by Lyc treatment, cell-cycle progression was assessed using FACS analysis. Logarithmically growing cultures were incubated in the presence or absence of Lyc. At the indicated times samples were fixed and the DNA contents of cells in each sample were measured by flow cytometry (Fig. 2). In comparison with the no drug control culture, an increase in the number of cells with a 1C (or G1) DNA content was observed, starting at 2 h and persisting for the duration of the experiment. After 4 and 8 h of Lyc treatment, accumulation of cells with abnormal DNA contents (neither 1C nor 2C) was evident. Thus, these results suggest that Lyc perturb cells-cycle progression.

View larger version (35K): [in this window] [in a new window] [Download PowerPoint slide]   Figure 2. Cell-cycle analysis. In the presence of Lyc, cells show aberrant DNA content. Cells treated with Lyc display cell-cycle perturbation. Wild-type strain was incubated in the presence or absence of Lyc. Samples at the indicated time points were analyzed by flow cytometry to measure DNA content (1C and 2C peaks are indicated).

 
Phenotypic Analysis

Saccharomyces cerevisiae divides by budding and shows specific cell morphologies at different stages of the cell cycle. Unbudded cells are in the G1 phase, small budded cells are in the S phase, and large budded cells are in the G2/M phase of the cell cycle (Fig. 3A). Thus, it is easy to monitor cell-cycle progression by simply observing cells using fluorescence and differential interference contrast microscopy. Therefore, to further investigate the effect of Lyc on cell-cycle progression, yeast cells in logarithmic phase were incubated with or without Lyc and then visualized by differential interference contrast (DIC) microscopy. We discovered that cells treated with Lyc exhibit a characteristic morphological alteration, with most cells either unbudded or abnormal with multiple buds (Fig. 3A). Additionally, DAPI staining of cellular DNA revealed that treated cells typically had a fragmented nucleus (Fig. 3A). Most cells had two or more DAPI-staining nuclear fragments, indicating that Lyc disrupts the integrity of the nucleus, consistent with the accumulation of cells with abnormal DNA contents observed by FACS analysis of the same cell sample (Fig. 3B). Furthermore, we scored the proportion of unbudded (G1), small budded (S), large budded (G2/M) and abnormal cells in the presence or absence of Lyc. As shown in Fig. 3C and in comparison with the no drug control, most cells treated with Lyc were abnormal (41% large unbudded and 22% multi-budded cells) and only few cells were in S or G2/M phases of the cell cycle. Together, these data suggest that treatment with Lyc impairs normal cell-cycle progression, perhaps as a result of nuclear fragmentation. However, for more detailed analysis of the effect of Lyc on cell-cycle progression, cells should be arrested in specific stages of the cell cycle and then released synchronously into the cell cycle (19–21). To detect G1 or S phase progression defects, cells can be arrested in G1 with the mating pheromone alpha factor, then released into media with or without Lyc. In contrast, mitotic defects can be detected following arrest in G2 using the microtubule inhibitor nocodazole, then released into media with or without Lyc.

View larger version (49K): [in this window] [in a new window] [Download PowerPoint slide]   Figure 3. Phenotypic analysis. (A) Representative images of asynchronously growing wild-type cells in the absence or presence of Lyc for 8 h. Cells treated with Lyc exhibit strong morphological alteration and fragmented nuclei. For each field of cells, differential interference contrast (left) and DAPI staining of DNA (right) images were taken. Specific cell morphologies at different stages of the cell cycle are shown for the no drug control. (B) FACS profile of cells from the experiment in (A). (C) Budding index was measured for growing wild-type cells from the experiment in (A). Cells were counted in each of two experiments, and the average of the two experiments is showed.

 
Chemical-Genetic Profiling

Yeast-based functional genomics technologies are excellent means for mechanistic studies of compounds with antifungal activity. In particular, chemical-genetic profiling has been used to study the mode of action of a number of growth-inhibitory compounds. Recently, in a proof-of-concept manuscript, we demonstrated that chemical-genetic profiling in yeast contributes greatly to understand the modes of action of bioactive compounds in human cells (10). Briefly, in these assays, a pooled collection of homozygous (or MAT haploid) viable deletion mutants, each in a different gene, is first grown in the presence or absence of a growth-inhibitory compound. Then, following growth, deletion strains that are under-represented, and therefore sensitive, in the presence of compound relative to the control condition are identified by hybridizing the unique DNA sequences which flank each deletion to their complements on a DNA microarray (10–14). This system identifies a set of deletion mutant strains hypersensitive to a given compound, referred to as the chemical-genetic profile. The results of these studies typically determine which pathways are important for drug resistance and therefore give insights into compound mode-of-action. In order to identify the drug target chemical-genetic profiling is carried out using a complete collection of heterozygous deletion strains. In this second type of profiling, referred to as HaploInsufficiency Profiling (HIP), a pooled collection of all 6000 heterozygous deletion mutants, each in a different gene, can be grown in the presence or absence of a drug. Then, strain fitness can be determined by DNA microarray analysis of the PCR-amplified barcodes incorporated into each strain. Heterozygous strains most sensitive to drug carry deletions in genes which encode the likely drug targets (11).

Therefore, in order to determine the mode of action of Lyc chemical-genetic profiling was performed using the complete pool of barcoded MAT haploid viable deletion strains. Preliminary data show that the most sensitive mutants to Lyc are involved in translation regulation, suggesting that this compound may affect protein biosynthesis. Further investigation is required to confirm this result and to determine the precise target of Lyc.

	Conclusion

Top Abstract Introduction Selection of Growth-Inhibitory... Mechanism of Action Conclusion Acknowledgements References

 
The budding yeast S. cerevisiae is an excellent model system for identifying plant-derived natural products with anti-proliferative properties. As proof of principle, we showed that yeast cells treated with Lyc exhibited cell-cycle perturbation, fragmented nuclei, and morphological alterations. Compounds with these properties are excellent candidates for further study, as they might target components of the cell-cycle regulation machinery, and so could have anti-proliferative properties of therapeutic value. Such compounds could be useful in treating proliferative diseases such as cancers, or in treating fungal infections.

	Footnotes

 
For reprint and all correspondence: Mohammed Bellaoui, Faculté Pluridisciplinaire de Nador, Université Mohamed Premier, B.P: 300 Selouane 62700, Morocco. Tel: +212-72-09-70-69; Fax: +212-36-50-06-03; E-mail: bmbellaoui{at}gmail.com

	Acknowledgements

Top Abstract Introduction Selection of Growth-Inhibitory... Mechanism of Action Conclusion Acknowledgements References

 
The authors are grateful to Richelle Sopko for help with the microscopy. M.B. would like to thank the Academy of Sciences for the Developing World (TWAS) and ‘la Commission Universitaire pour le Développement (CUD, Belgium)’ for their support.

	References

Top Abstract Introduction Selection of Growth-Inhibitory... Mechanism of Action Conclusion Acknowledgements References

 

1. Newman DJ, Cragg GM. Natural products as sources of new drugs over the last 25 years. J Nat Prod ( 2007;) 70:: 461–77.[CrossRef][Medline]
2. Cooper EL. Drug discovery, CAM and natural products. eCAM ( 2004;) 1:: 215–17.[Medline]
3. Samane S, Noe J, Charrouf Z, Amarouch H, Haddad PS. Insulin-sensitizing and anti-proliferative effects of Argania spinosa seed extracts. eCAM ( 2006;) 3:: 317–27.[Medline]
4. Merzouki A, Ed-derfoufi F, Molero Mesa J. Contribution to the knowledge of Rifian traditional medicine. II: Folk medicine in Ksar Lakbir district (NW Morocco). Fitoterapia ( 2000;) 71:: 278–307.[CrossRef][Web of Science][Medline]
5. Jouad H, Haloui M, Rhiouani H, El Hilaly J, Eddouks M. Ethnobotanical survey of medicinal plants used for the treatment of diabetes, cardiac and renal diseases in the North centre region of Morocco (Fez–Boulemane). J Ethnopharmacol ( 2001;) 77:: 175–82.[CrossRef][Web of Science][Medline]
6. Eddouks M, Maghrani M, Lemhadri A, Ouahidi ML, Jouad H. Ethnopharmacological survey of medicinal plants used for the treatment of diabetes mellitus, hypertension and cardiac diseases in the south–east region of Morocco (Tafilalet). J Ethnopharmacol ( 2002;) 82:: 97–103.[CrossRef][Web of Science][Medline]
7. El-Hilaly J, Hmammouchi M, Lyoussi B. Ethnobotanical studies and economic evaluation of medicinal plants in Taounate province (Northern Morocco). J Ethnopharmacol ( 2003;) 86:: 149–58.[CrossRef][Web of Science][Medline]
8. Tahraoui A, El-Hilaly J, Israili ZH, Lyoussi B. Ethnopharmacological survey of plants used in the traditional treatment of hypertension and diabetes in south-eastern Morocco (Errachidia province). J Ethnopharmacol ( 2007;) 110:: 105–17.[CrossRef][Web of Science][Medline]
9. Gassner NC, Tamble CM, Bock JE, Cotton N, White KN, Tenney K, et al. Accelerating the discovery of biologically active small molecules using a high-throughput yeast Halo assay. J Nat Prod ( 2007;) 70:: 383–90.[CrossRef][Medline]
10. Yu L, Lopez A, Anaflous A, El Bali B, Hamal A, Ericson E, et al. Chemical-genetic profiling of imidazo[1,2-a]pyridines and -pyrimidines reveals target pathways conserved between yeast and human cells. PLoS Genet ( 2008;) 4:: e1000284.[CrossRef][Medline]
11. Giaever G, Shoemarker DD, Jones TW, Liang H, Winzeler EA, Astromoff A, et al. Genomic profiling of drug sensitivities via induced haploinsufficiency. Nat Genet ( 1999;) 21:: 278–83.[CrossRef][Web of Science][Medline]
12. Giaever G, Flaherty P, Kumm J, Proctor M, Nislow C, Jaramillo DF, et al. Chemogenomic profiling: identifying the functional interactions of small molecules in yeast. Proc Natl Acad Sci USA ( 2004;) 101:: 793–98.[Abstract/Free Full Text]
13. Lum PY, Armour CD, Stepaniants SB, Cavet G, Wolf MK, Butler JS, et al. Discovering modes of action for therapeutic compounds using a genome-wide screen of yeast heterozygotes. Cell ( 2004;) 116:: 121–37.[CrossRef][Web of Science][Medline]
14. Parsons AB, Lopez A, Givoni IE, Williams DE, Gray CA, Porter J, et al. Exploring the mode-of-action of bioactive compounds by chemical-genetic profiling in yeast. Cell ( 2006;) 126:: 611–25.[CrossRef][Web of Science][Medline]
15. Chang M, Bellaoui M, Charles Boone C, Brown GW. A genomewide screen for methyl methanesulfonate sensitive mutants reveals genes required for S phase progression in the presence of DNA damage. Proc Natl Acad Sci USA ( 2002;) 99:: 16934–9.[Abstract/Free Full Text]
16. Bellaoui M, Chang M, Ou J, Xu H, Boone C, Brown GW. Elg1 forms an alternative RFC complex important for DNA replication and genome integrity. EMBO J ( 2003;) 16:: 4304–13.
17. Chang M, Bellaoui M, Zhang C, Desai R, Morozov P, Delgado-Cruzata L, et al. NCE4, a suppressor of genomic instability, encodes a member of the RecQ Helicase/Topo III complex. EMBO J ( 2005;) 24:: 2024–33.[CrossRef][Web of Science][Medline]
18. Hartwell LH. Nobel Lecture: Yeast and cancer. Biosci Rep ( 2002;) 22:: 373–94.[CrossRef][Web of Science][Medline]
19. Haase SB, Lew DJ. Flow cytometric analysis of DNA content in budding yeast. Methods Enzymol ( 1997;) 283:: 322–32.[Web of Science][Medline]
20. Jacobs C W, Adams AE, Szaniszlo PJ, Pringle JR. Functions of microtubules in the Saccharomyces cerevisiae cell cycle. J Cell Biol ( 1988;) 107:: 1409–26.[Abstract/Free Full Text]
21. Breeden LL. Alpha-factor synchronization of budding yeast. Methods Enzymol ( 1997;) 283:: 332–41.[Web of Science][Medline]

Received November 25, 2008; accepted May 28, 2009

CiteULike    Connotea    Del.icio.us    What's this?

This Article Abstract Full Text (PDF) All Versions of this Article: nep069v2    most recent nep069v1 E-letters: Submit a response Alert me when this article is cited Alert me when E-letters are posted Alert me if a correction is posted Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Add to My Personal Archive Download to citation manager Request Permissions Google Scholar Articles by Qaddouri, B. Articles by Bellaoui, M. Search for Related Content PubMed PubMed Citation Articles by Qaddouri, B. Articles by Bellaoui, M. Social Bookmarking          What's this?

Online ISSN 1741-4288 - Print ISSN 1741-427X

Copyright © 2010 Oxford University Press

Oxford Journals Oxford University Press

• Site Map
• Privacy Policy
• Frequently Asked Questions

Other Oxford University Press sites: Oxford University Press Oxford Journals China Oxford Journals Japan American National Biography Booksellers' Information Service Children's Fiction and Poetry Children's Reference Corporate & Special Sales Dictionaries Dictionary of National Biography Digital Reference English Language Teaching Higher Education Textbooks Humanities International Education Unit Law Medicine Music Online Products Oxford English Dictionary Reference Rights and Permissions Science School Books Social Sciences Very Short Introductions World's Classics