GR1009201B - High-efficiency mass control method for factors able to break and/or inhibit the formation of a geminin-cdt1 complex - Google Patents

Abstract

The present invention provides methods for the automated mass high-efficiency control aiming at the identification of the inhibitors of the Geminin-Cdt1 protein interaction, which inhibitors are accompanied with complementary specifications serving for the characterization of the selected inhibitors as to their specificity, activity mechanism and inhibitory effects affecting the multiplication of the uncontrollably divided cells. Likewise, the present invention provides a kit for the determination of the capability of a factor to break and/or inhibit the formation of the Geminin-Cdt1 complex. The methods and the kit of the present invention are particularly useful for the identification of the factors regulating and/or hindering the multiplication of the uncontrollably divided cells.

Description

A high-throughput mass screening method for agents capable of cleaving and/or inhibiting formation of a Geminin-Cdt1 complex

DESCRIPTION

Technical Field

The present invention relates to automated high-throughput mass screening methods for the identification of inhibitors of the Geminin-Cdt1 protein interaction. It also refers to assays performed in addition to the high-throughput mass screening to characterize the selected inhibitors in terms of their specificity, mechanism of action, and their inhibitory effect on the proliferation of uncontrollably dividing cells such as cancer cells.

Technical Background

Accurate copying of the genome is vital to the cell. This is a tightly controlled process that ensures that the duplication of the genetic material will only take place once in each cell cycle. Geminin and Cdt1 proteins are two central regulators of the cell cycle and contribute to the maintenance of genomic stability through the regulation of DMA replication.

In particular, the correct local and temporal initiation of the replication of the genetic material is ensured through the process of licensing the replication (licensing). This process involves the assembly of a polyprotein complex at the origins of replication, which is called the pre-replicative complex (pre-RC). Formation of the pre-RC is completed by the recruitment to chromatin of the MCM2-7 hexamer, which has been shown in vitro to possess helicase activity and is postulated to induce unwinding of the DNA double-stranded helix ahead of the replication fork. The recruitment of MCMs is mediated by the Cdc6 and Cdt1 protein subunits of the pre-transcriptional complex (Blow JJ and Dutta A, Nat Rev Mol Cell Biol. 2005, Vol. 6(6), pp 476-86).

Tight regulation of the licensing factor Cdt1 is necessary to prevent ectopic resumption of DNA replication. A mechanism of negative regulation of Cdt1 in metazoans relies on the action of the Geminin protein. Geminin is the natural inhibitor of Cdt1, as it strongly binds to the latter thereby inhibiting the assembly of the pre-replicative complex (Wohlschlegel JA et al. Science. 2000, Vol. 290(5500), pp 2309-12).

Dysregulation of the replication licensing process promotes genomic instability, which in turn contributes to the molecular mechanism of carcinogenesis. In fact, disruption of the expression levels of the central regulators of the cell cycle Geminin and Cdt1 has been observed in cancer cell lines as well as in cases of human cancer.

However, there are indications that pharmacologically induced genomic instability through the mechanism of replicative stress (replicative stress), may be a promising approach for the implementation of a targeted and effective anticancer therapy (reviewed by Dobbelstein and Sorensen, Nat Rev Drug Discov. 2015 , Vol. 6, pp. 405-23). The term replicative stress refers to the induction of structural damage to DNA and the consequent activation of the DNA Damage Response (DDR) mechanism.

Most of today's widely used anticancer drugs work by contributing to the creation of replicative stress by causing damage to the integrity of DNA. Examples of such drugs are alkylating agents, platinum complexes and nucleotide analogues, which, although highly effective, lack high specificity. Thus, the need arises to create an alternative way of inducing replicative stress, with higher specificity. One such way could be the deregulation of the licensing system through the use of pharmacological molecules with targeted action against the licensing factors, and in particular the Geminin and Cdt1 proteins that play a central role in the regulation of transcriptional licensing.

Induction of replicative stress through disruption of Geminin-Cdt1 balance may induce a differential response between cancer and normal cells. In particular, it has been shown that inhibition of licensing through overexpression of Geminin causes cell cycle arrest in normal cells while inducing apoptosis in cancer cells. Also, Geminin silencing causes genome hyperduplication and induces apoptosis in cancer cells but not in normal ones. Regarding the deregulation of Cdt1, it has been shown that overexpression of the protein causes in cancer cells genome hyperduplication and induction of apoptosis, while in the case of normal cells genome hyperduplication is not caused although chromosomal abnormalities are observed.

In conclusion, disruption of the Geminin-Cdt1 balance can cause replicative stress and indeed this can lead to a different response between cancer and normal cells. The regulation of this balance and the action of the two proteins is based on the interaction between them. Therefore, the Geminin-Cdt1 complex constitutes an attractive and promising target molecule since inhibitors of this protein interaction may cause a disturbance in the balance of the two proteins and be used as pharmacological molecules with selective anticancer activity.

So far there have been some studies on finding molecules that inhibit the Geminin-Cdt1 interaction. Specifically, it has been shown by Mizushina V et al. that coenzyme Q10 (Biochim Biophys Acta. 2008, Vol. 1780(2), pp 203-13) spinach glycolipid SQDG (Biochimie. 2008, Vol. 90(6) pp 947-56) and oleic acid (C1 8:1) (Int J Mol Med. 2008, Vol. 21(3), pp 281-90) inhibit the interaction of the two proteins in vitro, through their binding to the Cdt1 factor.

In the above studies, the inhibitory effect of the specific biomolecules on the Geminin-Cdt1 protein interaction was studied through the ELISA (Enzyme Linked Immuno Sorbent Assay) method. It is a method that makes it possible to study protein interactions, but shows significant limitations in terms of its compatibility with automated techniques applied in high throughput screening protocols. The main limiting factors are related to basic technical characteristics of the method such as heterogeneity and especially the multiple washing steps necessary to remove non-specifically bound reagents.These characteristics make ELISA particularly uneconomical as a high-throughput mass screening method, in terms of time and cost parameters.

Given that the Geminin-Cdt1 complex constitutes an attractive target molecule for the discovery of pharmacological molecules with anticancer activity, there is a need for the development and application of a high-throughput method that makes possible and reliable mass screening of available libraries of synthetic chemical compounds (compound libraries). This would significantly contribute to the discovery of new inhibitors of the Geminin-Cdt1 interaction with drug-like properties. Synthetic chemical compounds (compounds) due to their pharmacological properties can be developed into suitable and effective drugs for potential experimental and/or clinical application through medicinal chemistry methods. It should be noted that coenzyme Q10, spinach glycolipid SQDG and oleic acid, unlike synthetic chemical compounds, lack pharmacological properties due to their natural origin. This fact points to the need to identify inhibitors of the Geminin-Cdt1 complex, mainly small molecules, which have the possibility of pharmacological development and optimization.

As for the inhibitory effect of the above molecules on the Geminin-Cdt1 interaction, it is limited only to inhibiting the formation of the protein complex, without showing the ability to break it down. However, in the context of an effective anticancer treatment, the identification of pharmacological molecules with the ability to break down the Geminin-Cdt1 protein complex is particularly important and necessary. This is because in an asynchronous population of cancer cells - as is the case in vivo conditions - the two proteins will be found in a complex in a significant percentage of these cells.

An additional important need that arises regarding the study of small molecule inhibitors of the Geminin-Cdt1 interaction is the development and use of appropriate cellular study systems (cellular assays) to determine the specificity and mechanism of their action ex vivo. This is necessary because it is possible that their in vitro inhibitory effect is not observed ex vivo given the limited permeability of the cell membrane, the specificity of the intracellular conditions and their non-specific effect due to the interaction between the different signaling monolayers. This necessity is reinforced by the fact that one of the molecules-inhibitors of the Geminin-Cdt1 interaction, the glycolipid SQDG has also been shown to be a very strong inhibitor of DNA polymerase ε [Mizushina et al., Biochem J 370:299-305 ( 2003)]. Therefore, the non-specific activity of this inhibitor may limit its efficacy ex vivo. However, none of the Q10 inhibitors, SQDG and oleic acid have been studied ex vivo. Therefore, it is understood that in addition to the identification of small molecule inhibitors of the Geminin-Cdt1 protein interaction, their ex vivo characterization through suitable cellular study systems is also necessary.

In addition, Q10 inhibitors, SQDG and oleic acid have not been studied for their effect on the cell cycle progression of cancer and normal cells. However, this is necessary in order to establish any anti-tumor activity as well as to determine the selectivity of their action between cancerous and normal cells.

The problem solved by the present invention concerns the need for the development and application of a suitable high-throughput mass screening method for the identification of small molecule inhibitors of the Geminin-Cdt1 interaction. In addition, it concerns the need to develop and apply appropriate cell study systems for the ex vivo study of the specificity, mechanism and selectivity of the action of these inhibitors.

The solution provided by the present invention to the hitherto lack of pharmacological inhibitors of the Geminin-Cdt1 interaction stemming from the lack of suitable methods for their identification is a suitably tailored homogeneous high-throughput mass screening method accompanied by a series of secondary assays of inhibitor potency and specificity .

Homogeneous techniques are characterized by homogeneity (do not include washing steps) and extremely high sensitivity (higher than heterogeneous methods such as classical ELISA). These features make them compatible with automated or semi-automated techniques and ideal for the implementation of high-throughput bulk screening protocols.

Summary of the Invention

The object of the present invention is to provide high-throughput automated mass screening methods for the identification of inhibitors of the Geminin-Cdt1 protein interaction, as well as complementary assays for the characterization of the selected inhibitors as to their specificity, mechanism of action and their inhibitory effect on proliferation of uncontrollably dividing cells. An object of the present invention is also to provide kits for determining the ability of an agent to disrupt and/or inhibit the formation of a complex of Geminin-Cdt1 proteins. The methods and kits of the present invention are particularly useful in identifying factors that regulate and/or inhibit the proliferation of aberrantly dividing cells.

Description of the Plans

The present invention will now be described with reference to certain embodiments thereof illustrated in the accompanying drawings. It should be noted that the attached drawings illustrate preferred embodiments of the invention, therefore they should not be considered as limiting the scope of the invention.

Fig. 1 depicts the results of the study of the conditions (concentration of the protein complex, beads, DMSO and length of incubation time) for optimal application of the AlphaScreen™ method.

Fig. 2 illustrates the statistical description of the results and the reliability assessment of the high-throughput mass screening.

Fig. 3 illustrates the structural formula of the synthetic compound AF-615/30368009.

Fig. 4 illustrates the structural formula of the synthetic chemical compound AN-689/41741104. .

Fig. 5 illustrates the results of the in vitro study of the specificity and potency of the synthetic chemical compounds (A) AF-615/30368009 and (B) AN-689/41741104, through the Surface Plasmon Resonance technique , SPR).

Fig. 6 illustrates the results of the ex vivo study of the specificity of the action of the synthetic chemical compounds (A) AF-61 5/30368009 and (B) AN-689/41741104, by means of the fluorescent resonant energy transfer technique following photobleaching of the "receiver » (FRET Acceptor Photobleaching). The symbol "*" refers to a p-value ≤0.05.

Fig. 7 illustrates the results of the ex vivo study of the mechanism of action of the synthetic chemical compounds (A) AF-615/30368009 and (B) AN-689/41741104, through their effect on the intracellular distribution of exogenous Geminin. Symbols “*”, “**” and “***” refer to p values ≤0.05, ≤0.005 and ≤0.0005, respectively.

Fig. 8 illustrates the results of the effect of the synthetic chemical compounds AF-6 15/30368009 (B & E) and AN-689/41741104 (C & Z) on the cell cycle of cancer and normal cells, by flow cytometry technique.

Detailed Description of the Invention

For the purposes of the present invention the term "Geminin protein" refers to the full-length Geminin protein or a portion thereof that retains the ability to bind to the Cdt1 protein. The Geminin protein of the present invention is from any mammal, including in particular human, mouse and rat for example.

For the purposes of the present invention the term "full-length Geminin protein" refers to the complete amino acid sequence of the Geminin protein. The complete amino acid sequence of the Geminin protein is available in the GenBank database. The accession number for the amino acid sequence of human, mouse and rat for example is NP_001 238920 (Homo sapiens), NP_065592 (mus musculus) and NP_001099582 (rattus norvegicus).

For the purposes of the present invention the term "Cdt1 protein" refers to the full-length Cdt1 protein, a portion thereof that retains the ability to bind to the Geminin protein, or to a mutant form of the Cdt1 protein that exhibits a reduced ability to bind to the Geminin protein. The mutant form of the Cdt1 protein that shows a reduced ability to bind to the Geminin protein can be a point mutant form of the Cdt1 protein, or a deletion that removes some amino acids from the protein sequence. The Cdt1 protein of the present invention is from any mammal, including in particular human, mouse and rat for example.

For the purposes of the present invention the term "full-length Cdt1 protein" refers to the complete amino acid sequence of the Cdt1 protein. The complete amino acid sequence of the Cdt1 protein is available in the GenBank database. The accession number for the amino acid sequence of human, mouse and rat for example is NP_1 12190 (Homo sapiens), NP_080290 (mus musculus) and NP_001099662 (rattus norvegicus).

In one embodiment, the present invention provides the description of a high-throughput mass screening method using homogeneous automated or semi-automated techniques and the optimization of its technical parameters for its optimal application in determining the ability of an agent to break down and/or inhibits the formation of a complex of Geminin-Cdt1 proteins. Said method includes providing a Geminin protein and a Cdt1 protein to a system under conditions that would allow, in the absence of the agent, the formation of a Geminin-Cdt1 protein complex, providing an agent to the system, and determining the amount of complex formed, wherein a decrease in the amount of said complex in the presence of the agent compared to the absence of the agent indicates that said agent disrupts and/or inhibits the formation of a complex of Geminin-Cdt1 proteins.

The term "homogeneous technique" or "homogeneous method" refers to an assay that does not require intermediate washing steps to remove unprogressed reagents, making the assay easier and faster. Also a homogeneous technique allows the detection of low-affinity interactions which may be broken down during washing, and is more amenable to automation.

The said conditions that would allow, in the absence of the factor, the formation of a Geminin-Cdt1 protein complex are mainly: a) the used concentration of the Geminin protein and the Cdt1 protein, as well as the relative concentrations for which it is presented the desired ratio of signal (S, Signal) / noise (B, Background), b) the composition of the buffer solution and mainly the choice and amount of buffering agent, the amount of salt, the amount of BSA (bovine serum albumin) protein that is added to limit non-specific protein interactions, c) the concentration of protein capture reagents (Protein Capture Reagents) such as beads or antibodies as appropriate, or other reagents used when performing mass screening. Also, another parameter that needs to be optimized when performing the high-throughput mass screening is the concentration of each agent tested for its ability to inhibit the formation of the Geminin-Cdt1 protein complex, as well as the concentration of the solvent in which the agents are dissolved .

In a further embodiment of the present invention, the Geminin protein and/or the Cdt1 protein is covalently attached to a peptide epitope or a detectable label. Those of ordinary skill in the art can determine the appropriate epitope or label for a given application.

The most common peptide epitopes are those for which antibodies are available that serve to label the corresponding epitope. Myc, FLAG tag and Hemagglutinin (HA) epitopes belong to this category. There are also systems that do not use antibodies, such as glutathione-S-transferase (GST), which can be isolated using glutathione agarose, the Maltose binding protein tag (which binds to amytose agarose), and the 6-Histidine tag ( bound by a nickel or cobalt chelate).

A detectable tracer is a compound detectable by spectroscopic, photochemical, biochemical, radiochemical, chemical, immunochemical, or any other means. For example, useful labels include luminescent compounds such as luciferase and aequorin, fluorophores such as green fluorescent protein GFP, cyan CFP and yellow YFP, the Alexa Fluor family of dyes (of Molecular Probes), Rhodamine Green, rhodamines B and 6G, the rhodamine derivative TMR, cyanines Cy2, Cy3 and Cy5, Europium cryptate and XL665, electron-dense reagents, and radioisotopes.

Attachment of the epitope or label can be achieved by covalent attachment of the epitope or label to the amino or carboxy terminus of the target protein. This is achieved by inserting the target gene into an expression vector that is specific for the appropriate host cell and that also contains the sequence of the flanking epitope (or multiple copies of the same epitope, or even consecutive copies of different epitopes) or detectable tracer. Expression vectors have been developed and are available for a variety of host types, including the bacterium Escherichia coli, yeasts such as Saccharomyces cerevisiae, insects and mammalian cells.

The technique underlying the high-throughput homogeneous mass screening method is selected from the group consisting of the Amplified Luminescent Proximity Homogeneous Assay (Alphascreen™), Scintillation Proximity Assay, Fluorescence Coordinated Energy Transfer (Fluorescence Resonance Energy Transfer), Homogeneous Time Resolved Fluorescence, Fluorescence Polarization Assay, Fluorescence Correlation Spectroscopy, Enzyme Fragment Complementation, or combinations of these.

In some preferred embodiments, the technique for primary mass screening is based on Perkin Elmer's AlphaScreen™ Luminescence-Enhanced Homogeneous Proximity Assay method. The AlphaScreen™ technique is based on the use of "donor" beads and "acceptor" beads coated with a hydrogel layer that provides functional groups for bioconjugation. When a biological interaction between the molecules (such as protein complex formation) brings the beads into close proximity, a series of chemical reactions takes place to produce a greatly amplified signal. During laser excitation, through a photosensitizer present in the "donor" beads, atmospheric oxygen transitions to the excited state of singlet oxygen. The singlet oxygen molecules diffuse and react with a chemiluminescent substance in the receiver beads that activates additional fluorophores contained within the same beads. The fluorophores then emit light at 520 to 620 nm. Signal detection is achieved using plate readers such as the EnVision™ Multilabel Plate Reader System, the Fusion-Alpha™ Multilabel Reader, or the AlphaQuest® HTS Microplate Analyzer.

Another suitable method for analyzing protein interactions is the Scintillation Proximity Assay (SPA) whose use in high-throughput mass screening is described in several reports (for example Zhang SP et al., J Biomol Screen. 2006 Sep; Vol 11(6), pp. 672-7). In SPA, the proximity of two proteins labeled with probes is detected by the induction of a signal due to the interaction of the probes. For example one protein can be labeled with radioactive iodine<125>\ and the second protein with a suitable quencher. The induced signal is counted in a scintillation counter.

Another also suitable technique is Fluorescence Tuned Energy Transfer, where energy transfer is observed as a decrease in emission intensity and fluorescence lifetime from a higher energy fluorophore (donor) to a lower energy fluorophore (acceptor). For this energy transfer to occur, the emission spectrum of the donor probe must overlap significantly with the absorption spectrum of the acceptor probe, as is the case for example with CFP and YFP probes.

The Homogeneous Time-Resolved Fluorescence Analysis technique combines FRET technology with fluorescence time resolution, which allows quenching of short-lived background fluorescence. The signal is detected using microplate counters designed to perform homogeneous time-resolved fluorescence measurements, such as the PHERAstar and RUBYstar systems from BMG Labtech.

The Fluorescent Light Polarization technique is based on the excitation of a fluorophore with light that is linearly polarized by passing through a polarization excitation filter. Polarized fluorescence is measured by means of an emission polarizer either parallel or perpendicular to the plane of excitation polarization. Two intensity measurements are taken and used to calculate the fluorescence bias. The use of the technique in high-throughput mass screening is described in several reports (such as Wang L. et al. Probe Reports from the NIH Molecular Libraries Program [Internet}. Bethesda (MR); National Center for Biotechnology Information (US); 2010).

Fluorescence Correlation Spectroscopy measures the spontaneous variation of fluorescence intensity caused by very small deviations in physical parameters such as thermal equilibrium. A photomultiplier tube, an Avalanche Photodiode, or a superconducting nanowire single-photon detector is typically used to detect the fluctuations.

According to one embodiment of the present, the agent is a component of a library (collection) of compounds. A compound library suitable for the purposes of the present invention is a small molecule compound library or a subset thereof. A micromolecular compound library consists of organic compounds which have a molecular weight not exceeding 800 g/mol (800 Dalton).

Methods for synthesizing libraries of chemical compounds are provided in the scientific literature (see for example Thompson LA and Elman JA. Chem Rev. 1996 Feb 1; Vol 96(1), pp. 555-600, and Rademacher C, Seeberger PH. Handb Exp Pharmacol. 2015 Sep 2; pp 1-17). Also compound libraries are commercially available from specialized providers as well as from molecular screening centers such as the Broad Institute (MA, USA) and the Scripps Research Institute Molecular Screening Center (FL, USA).

In some embodiments, said system may be a cell-free system. In some embodiment or Geminin protein, the Cdt1 protein or both is provided as an isolated protein. Several techniques are available for protein isolation and include chromatographic techniques, for example affinity chromatography which is also often used to purify proteins bearing the His tag epitope, electrophoresis techniques for example in SDS-PAGE gels, high performance liquid chromatography (HPLC), immunoprecipitation (which is particularly useful for isolating proteins to which a peptide epitope has been covalently attached), etc.

In some other embodiments the Geminin protein, the Cdt1 protein, or both are provided as a cell extract. In one embodiment, the cell extract is from yeast, plant, mammal, or amphibian. In another embodiment, the cell extract is a eukaryotic reticulocyte extract, e.g., rabbit reticulocyte extract. In yet another embodiment, the cell extract is a mammalian tissue cell culture extract, e.g., a cytoplasmic extract (S100) of HeLa cells, which may or may not have been transfected with expression vectors of a Geminin protein, a protein Cdt1, a Geminin protein covalently attached to a peptide epitope or a detectable label, a Cdt1 protein covalently attached to a peptide epitope or a detectable label, or any combination thereof.

In some additional embodiments of the present invention, a second assay is provided to quantify the ability of selected synthetic compounds to disrupt or inhibit formation of the Geminin-Cdt1 complex. This is a procedure to check the specificity and the potency of the action of the selected synthetic chemical compounds in terms of breaking up the Geminin-Cdt1 complex.

In some embodiments said second assay is a suitable cell-free in vitro assay. The in vitro assay can be selected, without limiting the range of possible options, from a group that includes the technique of Surface Plasmon Resonance, Overhauser Nuclear Magnetic Resonance Spectroscopy (Transferred-NOE Nuclear Magnetic Resonance Spectroscopy), Nuclear Magnetic Resonance Spectroscopy Saturation Transfer Difference Nuclear Magnetic Resonance Spectroscopy, Dual Polarization Interferometry, Dynamic Light Scattering, Correlation Fluorescence Spectroscopy, and Microscale Thermophoresis.

In some embodiment the second determination includes the Surface Plasmon Tuning technique. The technique is based on the existence of a transient electromagnetic field on a metal surface, on which it has been attached e.g. a first protein, and in measuring the change in the refractive index of the buffer near the metal surface, due to e.g. the binding of a second protein on the immobilized first protein. When monochromatic, linearly polarized light strikes the surface of the metal conductor, an electromagnetic wave is created that interacts with the cloud of free electrons on the metal surface, creating electron charge density waves called plasmons that reduce the intensity of the reflected light. This technique is automated and does not require the presence of covalently attached probes on the target protein. The reflected light is detected with suitable devices such as e.g. the Biacore T100 or T200 (GE Healthcare).

In some other embodiments of the present invention, said second assay to quantify the ability of the selected synthetic compounds to disrupt or inhibit formation of the Geminin-Cdt1 complex is performed in a cell system. The cell system may include mammalian, such as human, mouse, or rat cells, fungal, or bacterial cells for example. The cells may be normal, such as a culture of primary cells, immortalized cells, such as epithelial cells from breast adenocarcinoma (MCF7), or cancer cells from a tumor.

In some embodiments, to perform the second determination, the Geminin protein, the Cdt1 protein, or both are exogenously provided to the cell by providing the cell with a nucleic acid encoding the Geminin protein, the Cdt1 protein, or both. In some preferred embodiments, two expression vectors are provided to the cell. The first expression vector comprises a polynucleotide encoding a hybrid protein in which a full-length Geminin protein or a fragment thereof has been covalently attached to a detectable label. The second expression vector comprises a polynucleotide encoding a full-length hybrid protein, a fragment thereof capable of binding to the Geminin protein, or a mutant form exhibiting a reduced ability to bind the Geminin protein, in which the Cdt1 protein has been covalently attached to a detectable tracer . The mutant form of the Cdt1 protein that shows reduced ability to bind to the Geminin protein can be a point mutant form of the Cdt1 protein, or a deletion that removes some amino acids from the Cdt1 protein sequence.

The first or second or both expression vectors may be selected, without limiting the range of possible options, from a group comprising bacterial or viral expression vectors, or mammalian, bacillovirus or yeast expression vectors, or a combination thereof. Preferably the expression vectors are mammalian expression vectors.

Appropriate cells can be transiently or permanently transfected with one or more nucleic acids expressing a Geminin protein, a Cdt1 protein, or both. The nucleic acid(s) can be introduced into cells e.g. using a virus as a vector or by transfection including e.g. of chemical transfection (such as with Lipofectamine, Fugene, etc.), electroporation (Electroporation), co-precipitation with calcium phosphate or direct diffusion of the DNA.

In some embodiments, the second determination comprises the Fluorescent Co-ordinated Energy Transfer technique or the Bioluminescence Co-ordinated Energy Transfer technique. In a preferred embodiment, the second assay involves the FRET Acceptor Photobleaching technique. This technique enables the study of protein interactions ex vivo and is based on the recording of the fluorescence intensity of the "donor", before and after photobleaching of the acceptor, which is caused by very strong excitation of the acceptor at the appropriate absorption wavelength. The photobleaching of the molecules of the fluorescent acceptor molecule causes them to lose their fluorescent property and, by extension, their ability to absorb the energy emitted by the "donor". In the absence of photobleaching of the "acceptor", a decay of the fluorescence intensity of the "donor" is observed, due to the fact that the energy it emits is transferred and absorbed by the molecules of the "acceptor". However, in case of photobleaching of the "acceptor" and if at the same time there is a FRET effect, an apparent increase in the fluorescence intensity of the "donor" is observed, since the latter's energy cannot be absorbed by the molecules of the "acceptor".

In some embodiments, the primary mass screening selects compounds with the ability to disrupt and/or inhibit formation of a Geminin-Cdt1 complex, the second assay to quantify the ability of the selected agents to disrupt or inhibit the formation of a Geminin-Cdt1 complex Cdt1 in a system comprising isolated proteins, cell extracts, or a combination thereof, and the second assay to quantify the ability of the selected agents to disrupt or inhibit the formation of a Geminin-Cdt1 complex in a cell system, are performed sequentially:

The present invention also relates to the study of the effect of selected synthetic chemical compounds on the cell cycle of uncontrollably dividing cells such as cancer cells versus normal cells and the selective inhibitory effect of the selected compounds on the cell cycle progression of cancer cells.

Said cells may be of mammalian origin, such as human, mouse, or rat. Cancer cells may be immortalized cells, such as for example epithelial cells from breast adenocarcinoma (MCF7), or cells from a tumor for example, or derived from a primary cell culture. Normal cells may be derived from a culture of primary cells such as embryonic muscle fibroblasts or from normal tissue.

Cells are cultured in the presence of the selected synthetic chemicals under controlled ex vivo conditions. Cancer and normal cells are then separated based on the amount of their genetic material using techniques such as flow cytometry after staining with propidium iodide for example. Cells that are in the G1 phase are characterized by a diploid amount of genetic material (2N), while cells in the M phase are characterized by a double amount of genetic material (4N). S-phase cells show intermediate corresponding characteristics.

In some embodiments, the primary mass screening selects compounds with the ability to disrupt and/or inhibit formation of a Geminin-Cdt1 complex, the second assay to quantify the ability of the selected agents to disrupt or inhibit the formation of a Geminin-Cdt1 complex Cdt1 in a system comprising isolated proteins, cell extracts or egg combination, the second assay to quantify the ability of selected agents to disrupt or inhibit the formation of a Geminin-Cdt1 complex in a cell system, and the cellular assay of the ability of of selected agents to inhibit the proliferation of cancer cells versus normal cells, are performed sequentially.

According to a further embodiment of the present invention, there is provided a method of mass screening for an agent that regulates and/or inhibits abnormal cell proliferation. Said method includes a method for determining the ability of an agent to disrupt and/or inhibit the formation of a Geminin-Cdt1 protein complex, as described in the present invention. The agent is a component of a compound library, such as a small molecule compound library or a subset thereof.

The above method of mass screening for an agent that regulates and/or inhibits aberrant cell proliferation may also include a second assay to quantify the ability of the selected agents to disrupt or<'>inhibit the formation of a Geminin-Cdt1 complex in a system comprising isolated proteins, cell extracts or a combination thereof, as described in the present invention and/or a second assay to quantify the ability of selected agents to disrupt or inhibit the formation of a Geminin-Cdt1 complex in a cell system as described in the present invention. Finally, the mass screening method for an agent that regulates and/or inhibits abnormal cell proliferation may also include a cellular assay of the ability of the selected agents to inhibit the proliferation of cancer cells against normal cells as defined in the present invention.

The present invention also provides kits for determining the ability of an agent to disrupt and/or inhibit the formation of a complex of Geminin-Cdt1 proteins. According to the present invention, what kit comprises a) an expression vector encoding a full-length Geminin protein or a fragment thereof, wherein said Geminin protein has been covalently attached to a peptide epitope or a detectable tracer, b) an expression vector encoding a Cdt1 protein, wherein said Cdt1 protein is a full-length protein, a fragment thereof, or a mutant form that exhibits reduced binding to the Geminin protein, and wherein said Cdt1 protein is covalently attached to a peptide epitope or a detectable tracer , and c) an instruction booklet.

The first or second or both expression vectors may be selected, without limiting the range of possible options, from a group comprising bacterial or viral expression vectors, or mammalian, bacillovirus or yeast expression vectors, or a combination thereof.

Examples

The following examples are provided for purposes of illustration of the various embodiments of the present invention and are in no way intended as limitations of the present invention.

Example 1

Experimental design of the high-throughput mass screening method

The implementation of the high-throughput mass screening method was based on AlphaScreen™ technology. Either mutant ADBGeminin protein and the point mutant protein miniCdt1Y170A were used as target molecules. The ADBGeminin protein form corresponds to the amino acid region 28-209 of the human ortholog of the protein, in other words it lacks amino acid residues 1-27, which have been shown to be essential for protein degradation (McGarry & Kirschner, Cell. 1998, Vol. 93(6), pp 1043-53). Deletion of amino acid residues 1-27 was performed to avoid problems with the stability of the molecule.

The miniCdt1Y170A protein form corresponds to amino acid region 158-396 of the human ortholog of the protein, which carries a point mutation of the tyrosine (Y) to alanine (A) residue at position 170. This protein form has been shown to exhibit reduced binding affinity in Geminin (Lee C et al. Nature. 2004, Vol. 430(7002) pp 913-7). Since the Geminin-Cdt1 complex constitutes a very strong protein interaction, the inventors chose the mutant ΔDBGeminin-miniCdt1Y170A complex to significantly increase the probability and ease of identifying 'promising' synthetic chemical compounds (compound hits) with the ability to disrupt the complex.

ΔDBGeminin and miniCdt1Y170A protein forms were cloned by standard PCR techniques into the plasmid expression vectors pET22b (Novagen) and pET28a (Novagen), respectively. Expression of the ΔDBGemininminiCdt1Y170A protein complex was performed using the bacterial strain E.coli, Rosetta 2(DE3) and its isolation by applying affinity chromatography and molecular filtration techniques. The purity of the isolated protein complex was judged by SDS-PAGE analysis.

The AlphaScreen™ Histidine (Nickel Chelate) Detection Kit (Cat.No.:6760619M), from PerkinElmer, was used to perform the high-throughput mass screening. Labeling of the ΔDBGeminin-miniCdt1Y170A complex with donor and acceptor beads was based on donor beads carrying streptavidin molecules on their surface while acceptor beads carrying nickel ions. Therefore, tethering of ΔDBGeminin to donor beads was performed via its N-terminal FLAG tag epitope and the use of an appropriate biotinylated anti-FLAG antibody, while tethering of the miniCdt1Y170A protein to acceptor beads was performed via its six-histidine tail epitope (6xHis tag), which he brought to its amino terminus.

The signal was calculated based on the equation (S-B)/B, where the value S (Signal) corresponds to the amount of emitted radiation in the presence of the protein complex, the beads and the biotinylated anti-FLAG antibody while the value B (Background) corresponds in the amount of emitted radiation in the presence of only the beads. The value B (Background) determines the 'noise' level. The procedures of stimulating the donor beads as well as detecting the emitted radiation from the receiver beads were done using appropriate equipment (Envision reader, PerkinElmer).

The presence of the ΔDBGeminin-miniCdt1Y170A protein complex brings the globules into proximity, as a result of which it is possible to transfer energy through the excited O2 and, by extension, the detection of a signal (S, Signal) through the emitted radiation. The dissociation of the protein complex, due to the presence of a synthetic chemical compound, entails the return of O2 to its fundamental state, the loss of energy transfer between the two types of beads and, by extension, the attenuation or absence of signal. Therefore, the ability of the synthetic compounds to disrupt the Geminin-Cdt1 protein complex can be assessed by the observed change (decrease or absence) of the AlphaScreen™ signal (S, Signal).

Example 2

Selection of the appropriate technical parameters for optimal application of the high-throughput mass screening method

Different technical parameters were studied in order to find the most suitable ones, which will ensure the high sensitivity and reliability of the high-throughput mass screening method, through the AlphaScreen™ technology.

First, the concentration of the ADBGemininminiCdt1Y170A complex used was studied. A check was made to determine which concentration exhibits the desired signal (S, Signal) / noise (B, Background) ratio. For this reason, different concentrations (10nM, 25nM, 50nM, 100nM, 200nM, 400nM) of the complex were tested and the corresponding increase in signal level was calculated (Fig. 1A). The concentrations of beads and biotinylated anti-FLAG antibody were kept constant. In the concentration range of 200-400nM there was an increase in signal by at least twenty times above the noise level (Fig. 1A). Graph A of Fig. 1 represents the means of triplicate independent measurements and the error bars the standard deviation of the means.

The next parameter studied was the concentration of beads used. Different concentrations of beads (5μg/ml, 10μg/ml, 15μg/ml, 20μg/ml) were tested in order to find a suitable p that ensured the desired signal (S, Signal)/noise (B, Background) ratio. The concentrations of protein complex and biotinylated anti-FLAG antibody were kept constant. A bead concentration of 10 µg/ml showed an increase in signal approximately twenty-fold above the noise level (Fig. 1B). Graph B of Fig. 1 represents the means of triplicate independent measurements and the error bars the standard deviation of the means.

Since the synthetic chemical compounds used in the mass screening procedure were dissolved in DMSO, it was considered appropriate to study the effect of the DMSO concentration used on the signal (S, Signal)/noise (B, Background) ratio. A zero concentration of DMSO was used as a control sample. Different concentrations of DMSO (0.2%, 0.5%, 1 %, 2%, 4%) were tested in order to find the appropriate one, which would not significantly change the signal level. The concentrations of protein complex, beads and biotinylated anti-FLAG antibody were kept constant. The study showed that DMSO concentrations up to 4% did not cause any significant change in signal level (Fig. 1C). Graph C of Fig. 1 represents the means of triplicate independent measurements and the error bars the standard deviation of the means.

In addition, the stability of the reagents with respect to time was tested. Since the bulk screening process can take a long time, the reagents (beads, biotinylated antibody, protein complex) will need to remain for this time in sub-optimal conditions (room temperature vs. 4°C, which is the recommended temperature). For this reason, the effect of increasing the dwell time (1 hr, 2hrs, 6hrs, 10hrs) of the reagents at room temperature was tested before the signal was detected (Fig. 1D). A control sample refers to the zero time the reagents stay at room temperature. As can be seen in graph D (Fig. 1D) the passage of time does not show a negative effect on the stability of the reagents as no degradation of the signal (S, Signal)/noise (B, Background) ratio is observed even after a time interval of 10hrs. Graph D of Fig. 1 represents the means of triplicate independent measurements and the error bars the standard deviation of the means.

When performing the high-throughput mass screening via AlphaScreen™ technology, the final concentrations of reagents were: 300nM ADBGeminin-miniCdt1Y170A complex, 10μg/ml beads ('donors' and 'acceptors') and 5nM biotinylated anti-FLAG antibody (SIGMA, Cat.No.:F-9291). The composition of the buffer solution used was 25mM Hepes pH 7.4, 100mM NaCl and 0.2% BSA. Each synthetic compound was tested at a final concentration of 5 µM and DMSO 0.4%. The final volume of the reaction in each well was 25μl. Each plate was incubated for at least 3hrs in the dark at room temperature before measurement of the AlphaScreen™ signal using appropriate equipment (Envision reader, PerkinElmer).

Example 3

Primary high-throughput mass screening of synthetic chemical compounds

In order to identify chemical compounds capable of cleaving the ΔDBGeminin-miniCdt1Y170A protein complex, a high-throughput screening (HTS) of a library of synthetic chemical compounds was carried out. The library consisted of a total of 23,360 individual samples and was a product of specs (www.specs.net). Mass screening was done with the help of automated techniques and the use of appropriate equipment. A total of 73 384-well plates were used.

The qualitative evaluation of the high-throughput mass control procedure was performed using positive control and negative control samples. The value of the positive control sample (S, Signal) was defined as the value of the AlphaScreen™ signal, which resulted from the combined presence of the ΔDBGeminin-miniCdt1Y170A protein complex, the biotinylated antiFLAG antibody, the two types of beads and DMSO (versus the synthetic chemical union). The value of the negative control sample (B, Background) was defined as the value of the AlphaScreen™ signal, which resulted from the combined presence of only the biotinylated anti-FLAG antibody and both types of beads.

The synthetic chemical compounds which caused a decrease in the AlphaScreen™ signal value compared to the corresponding positive control sample were characterized as 'promising synthetic chemical compounds' (compound hits) for the ability to cleave the hGeminin-hCdt1 complex. From the set of 'promising' compounds, those that caused a reduction (%) of the signal higher than a certain threshold value, based on statistical analysis, were selected. For each synthetic compound the value (%) of the AlphaScreen™ signal was calculated based on the following equation

(1) (AlphaScreen™ signal value % = (signal value for the synthetic chemical compound under study / median signal value for all synthetic chemical compounds)*100].

A percentage value of 50% was set as the selection threshold and a total of 359 synthetic chemical compounds showed a signal value (%) of less than 50%. Fig. 2A represents the distribution of the total values (%) of the AlphaScreen™ signal based on equation (1), for each of the 23,360 synthetic compounds studied. The values (<50%) of the AlphaScreen™ signal of the 359 selected 'promising' synthetic chemical compounds are represented in black. In gray are represented the values (%) of the AlphaScreen™ signal of the remaining synthetic chemical compounds, which did not cause >50% decay.

The statistical evaluation of the reliability of the results (Fig. 2A) of the primary mass screening of the synthetic chemical compounds was performed by analyzing the parameter Z. The value of the parameter Z is obtained from Eq.

(2) Z -1- [(3σc<+>+3σc-)/(μc<+>- μc-)], where σc<+>and σc<->the standard deviation of positive and negative control samples, respectively . Similarly, μc<+> and μs- values correspond to sample means.

In order for the distributions of the positive and negative control samples to be sufficiently separated and their standard deviation sufficiently limited, it has been empirically considered that the Z' value should be equal to or greater than 0.5 (Zhang<'>JH et al., J Biomol Screen. 1999, Vol. 4(2), pp 67-73). Therefore, mass control methods characterized by a value of Z'≥ 0.5 are considered of high quality and reliability.

The mean Z value for all plates studied (total 73) when performing the high-throughput mass screening through AlphaScreen™ technology was equal to 0.6 (Fig. 2B). In Fig. 2B the black dots correspond to the discrete Z values of the plates and the black continuous straight line corresponds to the average of the Z' values. The x-axis represents the different plates, while the y-axis represents the corresponding values of the Z' factor. Regarding the average value of the ratio of signal (S, Signal) to 'noise' (B, Background), this was equal to 42 (S/B=42). These results are indicative of the high quality and reliability of the primary bulk screening as well as the AlphaScreen™ technology as applied for the purposes of the present invention.

Example 4

Evaluation review of selected 'promising' synthetic chemical compounds

Any primary mass screening of synthetic chemical compounds (primary compound screening) results in the detection of 'unspecific promising' samples.

The detection of 'non-specific' synthetic chemical compounds is directly related to the technology (AlphaScreen™) and experimental design, chosen to perform the high-throughput mass screening. In the embodiments of the present invention which refer to the high-throughput mass screening process, as 'specific promising' synthetic chemical compounds are considered those which cause a decrease in the value (%) of the AlphaScreen™ signal, solely and exclusively through the cleavage of the protein complex ADBGeminin- miniCdt1Y170A. As 'non-specific hopefuls' are considered those that cause a decrease in the value (%) of the AlphaScreen™ signal, through any other random mechanism.

Based on the experimental design of the primary mass screening method using AlphaScreen™ technology the main mechanisms of non-specific signal reduction, theoretically, would be:

(a) the competition between the six-histidine tail epitope (6xHis-tag) of the miniCdt1Y170A protein and synthetic compounds whose structure is similar to that of imidazole, for binding to nickel ion-coupled acceptor beads;

(b) the competition between the FLAG tag epitope of the ΔDBGeminin protein and synthetic compounds whose structure is similar to that of biotin, for binding to the streptavidin-conjugated donor beads, (c) the inhibition of the diffusion of the excited form of O2 by synthetic chemical compounds with similar action.

Therefore, in order to be able to separate the 'promising' synthetic chemical compounds of the primary mass screening into 'non-specific' and 'specific', a secondary study system, the product AlphaScreen™ Biotinylated-HIS6 (Cat.No.:6760303M), was applied. by PerkinElmer Company. The particular study system involved the use of a biotinylated peptide with a six histidine tail epitope. Detection of the AlphaScreen™ signal was possible through binding of the peptide to nickel ion-conjugated acceptor beads and streptavidin-conjugated donor beads. The final reagent concentrations were: 20 nM Biotinylated-HIS6 peptide and 10 µg/ml beads {'donors' and 'acceptors'). The composition of the buffer solution used was 25 mM Hepes pH 7.4, 100 mM NaCl and 0.2% BSA. Each synthetic compound was tested at a final concentration of 5 µM and DMSO 0.4%. The final volume of the reaction in each well was 25μl. Each plate was incubated for at least 3hrs in the dark at room temperature before measurement of the AlphaScreen™ signal using appropriate equipment (Envision reader, PerkinElmer).

For each of the selected 'promising' synthetic compounds of the primary mass control (Fig. 2A, black dots) the value (%) of the AlphaScreen™ signal in the presence of the peptide and in the presence of the ADBGeminin-miniCdt1Y170A protein complex was calculated, in triplicate; respectively. Compounds were ranked in descending order based on the quotient value of the following equation

(3) [value (%) of AlphaScreen™ signal in the presence of peptide / value (%) of AlphaScreen™ signal in the presence of ADBGeminin-miniCdtl Y170A protein complex],

% of AlphaScreen™ signal value 100% was defined as the signal value in the absence of the respective synthetic chemical compound. Theoretically, the synthetic chemical compounds which are characterized as 'specific' are expected to cause a decrease in the signal value only in the presence of the protein complex. Conversely, they should not result in a decrease in signal value in the presence of the peptide. Therefore, the higher the value of the quotient (3), the higher the specificity of action of the synthetic chemical compound is expected to be.

Based on the specific classification method, from the 359 'promising' synthetic chemical compounds of the primary mass screening, the compounds AF-6 15/30368009 (Fig. 3) and AN-689/41741104 (Fig. 4) were selected during the re-evaluation as those with the highest specificity of action, regarding the cleavage of the hGeminin-hCdt1 complex. The quotient value of equation (3) for compounds AF-615/30368009 and AN-689/41741 104 were 4.3 and 2.98, respectively.

Example 5

In vitro testing of the specificity and potency of the synthetic chemical compounds AF-61 5/30368009 and AN-689/41741104

The surface plasmon resonance technique was applied, in order to quantitatively study the ability of the synthetic chemical compounds AF-615/30368009 and AN-689/41 741104 to inhibit the binding of Geminin to the miniCdt1 protein, corresponding to the amino acid region 158-396 of the orthologue of Cdt1 protein in humans, by calculating the inhibition constant (KI).

Using a commercial Biacore T 100 analyzer, at a temperature of 25°C, about 6,000 RU of miniCdtl protein was immobilized on a suitable CM5 Chip surface (Biacore) at pH 5.5, through the amino group of the lysine residues of the protein. A range of concentrations of Geminin protein and synthetic compounds were then co-injected across the CM5 Chip surface in the presence of 20mM Hepes pH 7.5 buffer, 200mM NaCl and 0.01% Tween20. The infusion flow rate was 30 µl/min. Geminin protein was used at concentrations of 12, 36, 107, 322, 966 nM and the synthetic compounds at concentrations of 10 µM, 100 µM and 1000 µM. The injection of the samples was carried out in the presence of 20% DMSO, in order to ensure the high solubility of the synthetic chemical compounds.

As can be seen from the binding curves (Fig. 5), the synthetic chemical compounds AF-6 15/30368009 and AN-689/41741 104 used at the concentration of 1000 µM cause a decrease in the binding levels of Geminin to the miniCdt1 protein. In the graphs of Fig. 5 the x-axis represents the different concentrations of Geminin (nM), while the y-axis the binding levels in response units (RU). Based on the constant inhibition value (CI) the synthetic chemical compound AF-61 5/30368009 with CI=0.75±0.19mM (Fig. 5A) seems to show a stronger inhibitory effect in vitro than the synthetic chemical compound AN-689/41741 104 with KI=1.21±0.32mM (Fig. 5B). The results of Fig. 5 indicate the specificity of the in vitro inhibitory effect of the synthetic compounds AF-615/30368009 and AN-689/41741104 on the Geminin-miniCdt1 protein interaction.

Example 6

Ex vivo study of the specificity of the synthetic chemical compounds AF-61 5/30368009 and AN-689/41741 104, through the technique of fluorescent resonant energy transfer

A cellular study system was developed and implemented using breast adenocarcinoma epithelial cells (MCF7), in order to ex vivo study the ability of selected synthetic chemical compounds to induce inhibition of formation and/or dissociation of the exogenous Geminin-Cdt1 complex.

An appropriate number of cells were plated on glass coverslips and the cells were left in culture to adhere. They were then transiently co-transfected with pcDNA3.1 -EGFR and pdiHcRed-N1 expression plasmid vectors containing the coding sequence for the synthesis of Cdt1-GFP and Geminin-dhcRed proteins respectively, where dhcRed is a red fluorescent protein. Three to five hours after co-transfection, the medium was removed and replaced with fresh medium containing the respective synthetic chemical compound. Compounds AF-61 5/30368009 and AN-689/41741 104 were used at a concentration of 100 µM and 25 µM respectively. The difference in the concentration used is due to their different cytotoxicity.

After a 24-hour incubation of the cells in the presence of the synthetic compounds, the coverslips were washed with cold 1X PBS solution (2 times) followed by fixation of the cells by incubation in a 4% paraformaldehyde (PFA) solution, for 10 minutes, at room temperature. Coverslips were then washed with 1X PBS solution (2x) and mounted on slides on Mowiol and stored at 4°C, in the dark, for 16-18 hours.

The culture of MCF7 cells was carried out in conditions of 37°C and 5% CO2 and DMEM (Gibco Cat. No. :41966-029) enriched with 20% by volume fetal bovine serum (FBS, Gibco Cat) was used as the nutrient medium .No.:10106-169). The medium also contained penicillin and streptomycin as antibiotics (P/S, Gibco Cat.No.:15140-122), at a final concentration of 1%.

In the fixed MCF7 cancer cells, as obtained from the above procedure, the technique of fluorescent resonant energy transfer was applied after photobleaching of the receiver. To quantify the efficiency (E) of the FRET effect, the equation was used:

(4) E=(Dpost - Dpre)/Dpost, where Dpre and Dpost are the fluorescence intensity value of the 'donor' before and after photobleaching of the 'acceptor', respectively.

For the purposes of the present invention, the inhibitory effect of the synthetic chemical compounds AF-61 5/30368009 and AN-689/41741104 on the exogenous Geminin-Cdt1 complex was studied through the percentage (%) change in the efficiency (E) of the FRET effect. Two transfection conditions were used as negative control samples. One condition concerned the co-transfection of cells that had not undergone incubation with any synthetic chemical compound, nor with DMSO (control) and the second concerned the co-transfection of cells that had undergone incubation only with DMSO.

A Leica TCS SP5 confocal microscope was used for the application of the fluorescent resonant energy transfer technique after photobleaching of the "receiver". The images were recorded with a 63x1.4 NA diving oil objective lens, 400Hz scanning speed (in both directions), 95.55μm pinhole diameter and 512x512 pixel image resolution. The excitation of the "donor" (Cdt1-GFP) and the acceptor (Geminin-dhcRed) was performed with a laser of wavelength 488nm and 561 nm, respectively (5-7% of the maximum intensity). The "receiver" (Geminin-dhcRed) underwent three consecutive photobleachings of the same duration with 100% intensity of the 561nm wavelength laser. The emission spectrum of the donor (Cdt1-GFP) was set at 500-550nm. The selection of the above parameters was performed through the FRET AB application of the Leica Microsystems LASAF software.

Fig. 6 represents the box plots for the total values of the efficiency (E) of the FRET effect per experimental condition, as indicated in the legend of the diagram. The solid black straight line within each boxplot of terminations corresponds to the median value of the ensemble. For each boxplot of results of each experimental condition, the efficiency (E) of the FRET effect was calculated in at least 40 positively co-transfected cells. Analysis of the results (Fig. 6) showed that the interaction between Cdt1-GFP & Geminin-dhcRed proteins caused an increase in the percentage (%) efficiency (E) of the FRET effect, at least three times compared to the noise level, which corresponds to co-transfection with GFP & dhcRed. This result is a strong indication of the specificity and sensitivity of the specific study cell system, in terms of ex vivo detection and study of Geminin-Cdt1 protein interaction. Furthermore, it indicates the suitability of said study cell system for ex vivo determination of the specificity of action of the synthetic chemical compounds AF-61 5/30368009 and AN-689/41741104.

The synthetic chemical compound AN-689/41 741 104 (Fig. 6B) caused a statistically significant decrease in (E). This reduction indicates inhibition of formation and/or dissociation of the exogenous Geminin-Cdt1 complex and, by extension, is a strong indication for the specificity of its action ex vivo. Since the MCF7 tumor cell population was asynchronous, the decrease in efficiency (E) due to inhibition of complex formation is expected in cells that are in G1/S phase, while the corresponding decrease in efficiency (E) due to dissociation of the complex is expected in cells that are during the S, G2 and M phases of the cell cycle. The synthetic compound AF-615/30368009 (Fig. 6A) also caused a decrease in (E), which was not statistically significant.

Example 7

Ex vivo study of the mechanism of action of the synthetic chemical compounds AF-615/30368009 and AN-689/41 741104, by observing the intracellular distribution of exogenous Geminin

A cellular study system was developed and implemented using epithelial cells from mammary adenocarcinoma (MCF7), in order to ex vivo study the mechanism by which the inhibitory effect of selected synthetic chemical compounds affects the functional significance of the Geminin-Cdt1 interaction.

It is known that the nuclear localization of Geminin is necessary for the manifestation of its action, regarding the regulation of cell proliferation (Yoshida K et al. Genes Cells. 2005, Vol. 10(1) pp 63-73). It has also been shown that the direct interaction of the licensing factor Cdt1 with the Geminin protein causes translocation of the latter to the nucleus, thus suggesting an additional mechanism of regulation of the inhibitor of Geminin licensing, through time-controlled nucleocytoplasmic transport (Dimaki M et al. J Biol Chem. 2013, Vol. 288(33) pp 23953-63).

Therefore, in order to determine the mechanism of action of the synthetic chemical compounds AF-61 5/30368009 and AN-689/41741104, their effect on the nucleocytoplasmic transport mechanism of Geminin was studied ex vivo.]

For the purposes of this experiment, the full-length human Geminin protein and the Cdt1<DEL> protein corresponding to the human ortholog of the protein lacking amino acid residues 170-190 were used. Immunoprecipitation experiments have shown that the mutant CdtIDEL protein interacts more weakly with Geminin, compared to the 'wild-type' protein (Ballabeni A et al. EMBO J. 2004, Vol. 23(15), pp 3122-32).

To apply the study cell system, an appropriate number of cells were plated on glass coverslips and the cells were left in culture to adhere. They were then transiently co-transfected with the plasmid expression vectors pcDNA3.1-EGFP and pdiHcRed-N1 containing Geminin-GFP and Cdt1<DEL>-dhcRed proteins respectively. 3-5 hours after co-transfection, the medium was removed and replaced with fresh medium containing the respective synthetic chemical compound. Compounds AF-615/30368009 and AN-689/41741 104 were used at a concentration of 100 µM and 25 µM respectively. The difference in the concentration used is due to their different cytotoxicity. After a 24-hour incubation of the cells in the presence of the synthetic chemical compounds, the coverslips were washed with cold 1X PBS solution (2 times) followed by fixation of the cells by incubation in a 4% paraformaldehyde (PFA) solution, for 10 minutes, at room temperature. Coverslips were then washed with 1X PBS solution (2x), mounted on slides on mounting medium containing DAPI dye (stains only nuclei), and observed under a fluorescence microscope.

The culture of MCF7 cells was carried out at 37°C and 5% CO2 and DMEM (Gibco Cat.No.:41 966-029) enriched with 20% by volume Fetal Bovine Serum (FBS) was used as the nutrient medium. Gibco Cat.No.:10106-169). The medium also contained penicillin and streptomycin as antibiotics (P/S, Gibco Cat.No.:15140-122), at a final concentration of 1%.

The experimental design involved the transient co-transfection of MCF7 cancer cells with Geminin-GFP & dhcRed and Geminin-GFP & Cdt1DEL-dhcRed. Geminin-GFP & dhcRed co-transfection was used as an internal control of the study cell system, in order to establish that it is possible to detect the change in the intracellular distribution of Geminin-GFP in the presence of CdtI DEL-dhcRed. The study of the intracellular distribution of Geminin was performed by observing the autofluorescence of the GFP molecule. To quantify the intracellular distribution of exogenous Geminin-GFP, at least 100 well co-transfected cells from different fields of view were counted for each condition. Categorization was based on localization of the GFP molecule signal and included three groups: purely nuclear distribution (nuclear localization), purely cytoplasmic distribution (nuclear exclusion), and homogeneous distribution (homogeneous localization) throughout the cell (nucleus and cytoplasm). The graphs in Fig. 7 represent the means of measurements (expressed as %) from at least three independent experiments and the error bars the standard error of the means. The x-axis represents the two different transient co-transfection conditions tested, while the y-axis the percentage (%) of co-transfected cells.

Cells co-transfected with Geminin-GFP & dhcRed showed a higher rate of nuclear exclusion of Geminin than the corresponding cells co-transfected with Geminin-GFP & CdtIDEL-dhcRed (Fig. 7). This observation indicates the suitability and sensitivity of the specific study cell system, regarding the detection of the intracellular distribution of Geminin-GFP.

To study the effect of synthetic chemical compounds on the intracellular distribution of Geminin-GFP, co-transfected cells that had not been incubated with any synthetic chemical compound, nor with DMSO (control) and cells that had been incubated were used as control samples with DMSO only. According to the results (Fig. 7A), the synthetic chemical compound AF-615/30368009 caused a statistically significant increase in the percentage of cells with nuclear localization of Geminin, in the case of Geminin-GFP & dhcRed co-transfection. A possible interpretation of this observation is that the compound's mode of action mimics that of the Cdt1 protein, in terms of its ability to cause Geminin to translocate to the nucleus. In cells co-transfected with Geminin-GFP & CdtI DEL-dhcRed, AF-615/30368009 did not cause a detectable change in the intracellular distribution of Geminin. This fact is probably due to the fact that its action is not so strong as to effectively compensate for the exogenous presence of the Cdt1 protein. The synthetic compound AN-689/41741104 (Fig. 7B) caused a statistically significant increase in the percentage of cells with nuclear exclusion of Geminin, in both Geminin-GFP & dhcRed and Geminin-GFP & Cdt1 DEL-dhcRed co-transfection conditions. This observation indicates its specificity and ability to affect Geminin-Cdt1 protein interaction ex vivo as well as its different mechanism of action, compared to compound AF-615/30368009.

Example 8

Effect of synthetic chemical compounds AF-615/30368009 and AN-689/41741104 on the cell cycle of cancer and normal cells

Since Geminin and Cdt1 proteins are key regulators of the cell cycle, the effect of synthetic chemical compounds on the cell cycle progression of cancer and normal cells was studied. The genetic material of the cells was stained with propidium iodide and the flow cytometry technique was applied to separate them, based on the amount of their genetic material.

MCF7 cells were used as cancer cells and primary cells, specifically Mouse Embryonic Fibroblasts (MEFs), were used as normal cells.

The cells were incubated with each synthetic chemical compound and cultured for 23hrs in a 100mm diameter plate, until 80-90% coverage of the plate surface. The synthetic chemical compounds AF-615/30368009 and AN-689/41741104 were used at a concentration of 100μM and 25μM, respectively, due to their different cytotoxicity. Cells incubated only with DMSO were used as a negative control sample. The next day of incubation, cell dilution was performed using trypsin. After the centrifugation step, the pellet was resuspended in 1X PBS and centrifuged at 800 rpm for 5 min. Then, cells were fixed in 70% ice-cold (4°C) ethanol and stored for at least 16hrs at -20°C. After fixation, washes were performed with 1X PBS (2 times) followed by addition of 2μg/ml propidium iodide and 100μg/ml RNase A. Experiments were performed on a Becton Dickinson flow cytometer and data were analyzed using WinMDi software 2.8.

MEFs cells were cultured at 37°C and 5% CO2 and DMEM (Gibco) enriched with 10% by volume Fetal Bovine Serum (FBS) and 2mM final concentration of glutamine (Gibco, Cat. No.:25030-024). The medium also contained penicillin and streptomycin as antibiotics (P/S, Gibco Cat.No.:15140-122) at a final concentration of 1%.

The plots shown in Fig. 8 are representative of at least two independent experiments. The x-axis represents the intensity of propidium iodide fluorescence and correspondingly the amount of genetic material of the cells, while the y-axis represents the number of events corresponding to each phase of the cell cycle.

The results (Fig. 8) showed that incubation of MCF7 cancer cells with the synthetic chemical compound AF-615/30368009 (Fig. 8B) caused a significant increase in the percentage (%) of G0/G1 and S phase cells compared to the control sample (Fig. 8A). Also, the population of cells corresponding to the G2/M phase of the cell cycle was extremely limited compared to the control (Fig. 8A). The specific results indicate that the synthetic chemical compound AF-615/30368009 causes inhibition of the cell cycle progression of MCF7 cancer cells, during the G1/S transition stage. The synthetic chemical compound AN-689/41741104 caused a decrease in the percentage- (%) of cells in the G0/G1 phase, without, however, causing inhibition of cell cycle progression, as indicated by the significant percentage (%) of cells in in G2/M phase (Fig. 8C).

In order to establish the selectivity of the action of the synthetic chemical compounds between cancer and normal cells, their effect on the cell cycle of primary cells (MEFs) was studied. The results showed that compound AF -615/30368009 (Fig. 8E) did not cause a significant change in the percentage of G0/G1 and S phase cells, but only a slight decrease in the corresponding percentage of G2/M phase compared to the control sample. (Fig. 8D). These results indicate that compound AF-61 5/30368009 does not cause cell cycle progression inhibition in normal cells, as pronounced as observed in the case of MCF7 cancer cells (Fig. 8B). This particular observation is of great importance, as it suggests the selective action of the specific synthetic chemical compound on cancer cells against normal (primary) cells. The synthetic chemical compound AN-689/41741104 (Fig. 8F) did not cause a significant change in the distribution pattern of the cell population compared to the control sample (Fig. 8D).

In conclusion, the present invention is the first to describe the application of a high-throughput mass control (High Throughput Screening), in order to identify specific synthetic chemical compounds with the ability to break down the Geminin-Cdt1 protein complex. It is also the first to report on the development and application of appropriate cellular study systems for the specificity and mechanism of action of synthetic chemical compounds targeting the Geminin-Cdt1 complex. In addition, it is the first to report the selective action of a small molecule inhibitor of the Geminin-Cdt1 interaction, against cancer cells. The observation that AF-615/30368009 selectively inhibits the cell cycle progression of cancer cells suggests its potential future use in the treatment of cancer and other diseases characterized by dysfunction of cell division control mechanisms. The synthetic chemical compound AN-689/41741104 does not appear to affect the progression of the cell cycle of cancer cells, a fact that may be related to its different mechanism of action, as found when studying the intracellular distribution of exogenous Geminin.

Claims (15)

1. A method of determining the ability of an agent to disrupt and/or inhibit the formation of a Geminin-Cdt1 protein complex, wherein said method comprises: - providing a Geminin protein and a Cdt1 protein to a system under conditions that would allow, in the absence of the agent, the formation of a Geminin-Cdt1 protein complex, providing an agent to the system, and determining the amount of complex formed, wherein a decrease in the amount of said complex in the presence of the agent compared to the absence of the agent indicates that said agent disrupts and/or inhibits the formation of a complex of Geminin-Cdt1 proteins, wherein said method comprises a homogeneous mass method high performance control. 2. The method according to claim 1, wherein said Geminin protein is a full-length protein or a portion thereof capable of binding to the Cdt1 protein, and wherein said Cdt1 protein is a full-length protein, a portion thereof capable of binding to the Geminin protein, or a mutant form that exhibits a reduced ability to bind to the Geminin protein. 3.          The method according to claims 1 or 2, wherein said Geminin protein and/or Cdt1 protein has been covalently attached to a peptide epitope or a detectable label. 4. The method according to claim 1, wherein the high-throughput homogeneous mass screening method is selected from the group consisting of Amplified Luminescent Proximity Homogeneous Assay, Scintillation Proximity Assay, Coordinated Energy Transfer Fluorescence Resonance Energy Transfer, Homogeneous Time Resolved Fluorescence, Fluorescence Polarization Assay, Fluorescence Correlation Spectroscopy, Enzyme Fragment Complementation, or combinations thereof. 5. The method according to claim 1, wherein the agent is a component of a library of synthetic compounds, preferably a small molecule library of synthetic compounds. 6. The method according to claim 1, wherein the Geminin protein, the Cdt1 protein or both is provided as an isolated protein and/or a cell extract, or a combination thereof. 7. The method according to claim 1, wherein said method further comprises quantifying the ability of the agent to disrupt or inhibit formation of the Geminin-Cdt1 complex in a second assay. 8. The method according to claim 7, wherein said second determination comprises the technique of Surface Plasmon Tuning. 9.         The method according to claims 1 or 7, wherein said system is a cell. 10. The method according to any one of claims 1-9, wherein the method comprises the method of determining the ability of an agent to disrupt and/or inhibit the formation of a complex of the Geminin-Cdt1 proteins of claim 1, wherein the system is a cell-free system wherein the Geminin protein, the Cdt1 protein, or both are provided as isolated protein and/or as a cell extract, or a combination thereof, and a further method of determining the ability of an agent to disrupt and/or inhibit the formation of a complex of Geminin-Cdt1 proteins of claim 1, wherein the system is a cell. The method according to claim 9 or claim 10, wherein the Geminin protein, the Cdt1 protein, or both are provided to the cell, providing the cell with a nucleic acid encoding the Geminin protein, the Cdt1 protein, or both, preferably in the form of a first expression vector comprising a polynucleotide encoding a hybrid protein in which a full-length Geminin protein or a portion thereof has been covalently linked to a detectable label, and a second expression vector comprising a polynucleotide encoding a hybrid protein in which a Cdt1 protein as defined in claim 2 has been covalently attached to a detectable label. 12. The method according to any one of claims 9-11, wherein the cellular assay comprises the Fluorescence CERT technique or the Bioluminescence CERT technique. 13. The method according to any one of the preceding claims, further comprising determining the ability of the agent to inhibit the proliferation of aberrantly dividing cells versus normal cells. 14.        A method of mass screening for an agent that regulates and/or inhibits abnormal cell proliferation, said method comprising a method according to any one of claims 1 to 13. 15. A kit for determining the ability of an agent to disrupt and/or inhibit the formation of a complex of Geminin-Cdt1 proteins, wherein said kit comprises a) an expression vector encoding a full-length Geminin protein or part thereof, wherein said Geminin protein is covalently attached to a peptide epitope or a detectable marker, b) an expression vector encoding a Cdt1 protein, wherein said Cdt1 protein is a full-length protein, a fragment thereof, or a mutant form that exhibits reduced binding to the Geminin protein, and wherein said Cdt1 protein is covalently attached to a peptide epitope or a detectable label, and c) an instruction leaflet.