Abstract:
A method of identifying cellular regulatory circuits which employ at least one component of a subcomplex of regulatory proteins within the RNA II polymerase holoenzyme which behaves as a signal processor for gene-specific regulators (at least one component of a eukaryotic transcription initiation apparatus) and of determining the set of components of the apparatus which are responsible for regulation of each gene and the set of genes which are coordinately controlled by each transcription factor.

Description:
RELATED APPLICATIONS 
     This application claims the benefit of the following applications: 
     U.S. patent application No. 60/087,909 filed Jun. 4, 1998, entitled Genome Control Map by Frank Holstege and Richard A. Young; 
     U.S. patent application No. 60/097,498 filed Aug. 21, 1998, entitled Dissecting the Regulatory Circuitry of a Eukaryotic Genome by Frank Holstege and Richard A. Young; 
     U.S. patent application No. 60/109,534, filed Nov. 23, 1998, entitled Dissecting the Regulatory Circuitry of a Eukaryotic Genome by Frank Holstege and Richard A. Young; and 
     U.S. patent application No. 60/110,051 filed Nov. 25, 1998 entitled Dissecting the Regulatory Circuitry of a Eukaryotic Genome by Richard A. Young. 
     This application is also related to U.S. patent application No. 60/075,291 filed Feb. 20, 1998, entitled Temperature Sensitive ts SRB4 Mutation by Rick Young. 
     The entire teachings of the referenced applications are incorporated herein by reference. 
    
    
     BACKGROUND OF THE INVENTION 
     Much of biological regulation occurs at the level of transcription initiation. Genes contain promoter sequences which are bound by transcriptional activators and repressors (Struhl, K. (1995)  Annu Rev Genet  29, 651-74; Ptashne, M. and Gann, A. (1997)  Nature  386, 569-77). Activators recruit the transcriptional initiation machinery, which for protein-coding genes consists of RNA polymerase II and at least 50 additional components (Orphanides et al. (1996)  Genes Dev  10, 2657-83; Roeder, R. G., (1996)  Trends Biochem Sci  21, 327-35; Greenblatt, J. (1997)  Curr Opin Cell Biol  9, 310-9; Hampsey, M. (1998)  Microbiology and Molecular Biology Reviews  62, 465-503; Myer, V. and Young, R. A. (1998)  J. Biol. Chem.  273, 27757-27760). The transcriptional initiation machinery includes factors which bind to DNA, cyclin-dependent kinases which regulate polymerase activity, and acetylases and other enzymes which modify chromatin (Burley, S. K., and Roeder, R. G. (1996)  Annu Rev Biochem  65, 769-99; Kingston, R. E. et al.,  Genes and Development  10, 905-20; Roth, S. Y. and Allis, C. D. (1996)  Cell  87, 5-8; Sgeger, D. J. and Wovleman, J. L. (1996)  Bioessays  18, 875-84, Tsukiyama, T. and Wu, C. (1997)  Curr. Opin. Genet. Dev.  7, 182-91; Hengartner C. J. et al., (1998)  Genes and Development  9, 897-910). 
     The understanding of eukaryotic gene expression remains limited in several ways. The complete set of transcriptional regulators has yet to be identified. How these regulators interact with and regulate components of the transcriptional machinery is not yet clear. The functions of just a fraction of the components of the transcriptional machinery are understood, and then only with respect to a small set of genes. Cells must adjust genome expression to accommodate changes in their environment and in their programs of growth control and development, but precisely how to coordinate remodeling of genome expression is accomplished for signal transduction pathways or for the cell cycle clock has yet to be learned. 
     SUMMARY OF THE INVENTION 
     Described herein are results of genome-wide expression analysis, which was carried out to identify the key components of the transcription initiation machinery in a eukaryote, in order to dissect the regulatory circuitry of the genome. Key components of the transcription initiation machinery (key components of the RNA polymerase II transcriptional machinery) were identified in yeast, as described herein. Assessment of the requirement for key components was carried out using high density oligonucleotide arrays (HDAs) (Wodicka, L. et al (1997)  Nat. Biotech.,  15, 1359-67) to determine the genome-wide effects of mutations in components of the transcriptional machinery. At any given promoter, the transcriptional machinery might include any or all of the following, among others: the RNA polymerase II core enzyme, the general transcription factors (GTFs), the core Srb/mediator complex, the Srb10 CDK complex, the Swi/Snf complex and the SAGA complex. The components of the transcription apparatus which were the focus of this study were selected because they are among the key subunits of the major multiprotein complexes which have roles in transcription of protein-coding genes. One or more subunits of each of these components has been investigated for its role in genome-wide gene expression through the use of mutations which affect either the function or the physical presence of the subunit. 
     Results showed that components of the RNA polymerase II holoenzyme, the general transcription factor TFIID and the SAGA chromatin modification complex have roles in expression of distinct sets of genes. They further showed that the Rpb1 subunit of core RNA polymerase II, the Srb4 subunit of the Srb/mediator complex and the Kin28 subunit of TFIIH are generally required for transcription of protein-coding genes. Two were found to be required for more than half, but not all, genes (Tfa1, Taf17). Most components investigated thus far were necessary for transcription of less than a fifth of the genome (Srb5, Med6, Srb10, Swi2, Taf145, Gcn5). In this latter group, the evidence indicates that Srb5, Med6, and Taf 145 have predominantly positive roles, Srb10 has an almost exclusively negative role, and Swi2 and Gcn5 can have either a positive or a negative role in gene expression. 
     Work described herein shows that distinct sets of genes require the function of distinct components of the transcription machinery. Thus, coordinate regulation of large sets of genes can be accomplished by affecting the function of specific components of the transcription machinery. It follows that functional relationships exist among some genes within the sets of genes whose regulation is accomplished in this manner. Results described herein also revealed an unanticipated level of regulation that is available to the cell in addition to that provided by gene-specific regulators; the expression of specific sets of genes can be regulated by affecting the availability or function of a specific component of the general machinery. Results also showed a novel mechanism for co-ordinate regulation of specific sets of genes when cells encounter nutrient deprivation or limitation and evidence that the ultimate targets of signal transduction pathways can be identified within the initiation apparatus. 
     In one embodiment, the present invention is a method of determining regulatory interrelationships among genes in a cell. The method comprises the steps of: 
     (a) hybridizing a transcription indicator of a test cell to a set of nucleic acid probes; 
     (b) hybridizing a transcription indicator of a control cell to the set of nucleic acid probes, 
     wherein the transcription indicators are selected from the group consisting of mRNA, cDNA and cRNA, wherein the test cell contains a mutant component of the general transcription machinery and the control cell is the wild-type isogenic counterpart of the test cell; 
     (c) detecting amounts of the transcription indicators which hybridize to each of said set of nucleic acid probes; and 
     (d) identifying a gene as a member of the regulatory pathway of the general transcription factor if hybridization of the transcription indicator of the test cell to a probe comprising a portion of the gene is higher or lower than hybridization using a transcription indicator from the control cell. 
     In various embodiments of the method, the difference in hybridization between the control and the test cell varies. There can be, for example, at least a 2-fold difference in hybridization between the control and the test cell, at least a 3-fold difference, at least a 5-fold difference or at least a 10-fold difference in hybridization between the control and the test cell. In various embodiments of the method, the mutant component of the general transcription machinery is a mutual general transcription factor, such as a temperature sensitive mutant, a point mutant or a deletion mutant. The mutant component of the general transcription machinery can be, for example, a component of RNA polymerase II holoenzyme. The mutant component of the general transcription machinery can be a component necessary to reconstitute promoter-dependent transcription in vitro with core RNA polymerase II. Also the subject of this invention is a pair of isogenic eukaryotic cells which comprises a test cell which contains a mutant component of the general transcription machinery and a control cell which is the wild-type isogenic counterpart of the test cell. Such pairs can include a test cell in which the mutant component of the general transcription machinery is a mutant general transcription factor. They also can include a test cell in which the mutant component of the general transcription machinery is a temperature sensitive mutant, a point mutant or a deletion mutant. In such pairs, the mutant component of the general transcription machinery can be a component of RNA polymerase II holenzyme; the mutant component of the general transcription machinery can be one which is necessary to reconstitute promoter-dependent transcription id vitro with core RNA polymerase II. 
     The invention further relates to a method of studying the effects of drugs on cells. The method comprises: 
     (a) contacting a cell with a drug; and 
     (b) determining the effect of the drug on the cell by assessing expression of one or more of the genes which are determined to be members of the regulatory pathway of the general transcription factor according to methods described herein. 
     A further embodiment of the invention is a method of identifying a cellular regulatory circuit which employs a component of a subcomplex of regulatory proteins within the RNA polymerase II holoenzyme, referred to as the transcription initiation apparatus. 
     The method comprises: 
     (a) comparing genome expression signature during cellular responses to environmental or other stimuli with the genome expression signature produced by a defect in the transcription initiation apparatus; and 
     (b) determining differences between the two genome expression signatures and relating the differences to the defect in the transcription initiation apparatus, thereby identifying a component of the transcription initiation apparatus which is responsible for regulation of genes in the cells. 
     In various embodiments the cellular regulatory circuit is a yeast cell regulatory circuit, a primate (e.g., human) or other vertebrate cell regulatory circuit or a non-vertebrate cell regulatory circuit. 
     Thus, genome-wide expression analysis provides insights into the transcriptional regulatory circuitry of eukaryotic cells, as well as the foundation and context for interpreting mechanistic studies in control of gene expression. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The file of this patent contains at least one drawing executed in color. Copies of the patent with color drawing(s) will be provided by the Patent and Trademark Office upon request and payment of the necessary fee. 
     FIGS. 1A-1B show genes which go up in Srb5 mutants. 
     FIGS. 2A-2B show genes which go up in Srb5 mutants. 
     FIGS. 3A-3U show genes which go down in Srb5 mutants. 
     FIGS. 4A-4U show genes which go down in Srb5 mutants. 
     FIGS. 5A-5E show genes which go up in Sin4 mutants. 
     FIGS. 6A-6E show genes which go up in Sin4 mutants. 
     FIGS. 7A-7C show genes which go down in Sin4 mutants. 
     FIGS. 8A-8C show genes which go down in Sin4 mutants. 
     FIGS. 9A-9C show genes which go up in Gcn5 mutants. 
     FIGS. 10A-10C show genes which go up in Gcn5 mutants. 
     FIGS. 11A-11F show genes which go down in Gcn5 mutants. 
     FIGS. 12A-12F show genes which go down in Gcn5 mutants. 
     FIGS. 13A-13C show genes which go up in Srb2 mutants. 
     FIGS. 14A-14C show genes which go up in Srb2 mutants. 
     FIGS. 15A-15F show genes which go down in Srb2 mutants. 
     FIGS. 16A-16F show genes which go down in Srb2 mutants. 
     FIGS. 17A-17F show genes which go up in Swi2 mutants. 
     FIGS. 18A-18F show genes which go up in Swi2 mutants. 
     FIGS. 19A-19D show genes which go down in Swi2 mutants. 
     FIGS. 20A-20D show genes which go down in Swi2 mutants. 
     FIGS. 21A-21B show genes which go up in TAF145 (45 min 37 deg) mutants. 
     FIGS. 22A-22P show genes which go down in TAF 145 (45 min 37 deg) mutants. 
     FIGS. 23A-23E show genes which go up in Srb10 mutants. 
     FIGS. 24A-24E show genes which go up in Srb10 mutants. 
     FIGS. 25A-25B show genes which go down in Gal11 mutants. 
     FIGS. 26A-26B show genes which go down in Gal11 mutants. 
     FIGS. 27A-27C show genes which go up in Gal11 mutants. 
     FIGS. 28A-28C show genes which go up in Gal 11 mutants. 
     FIG. 29 shows genes which go up in Med6 mutants. 
     FIGS. 30A-30E show genes which go down in Med6 mutants. 
     FIGS. 31A-31E show genes which go down in Med6 mutants. 
     FIGS. 32A-32E show genes which go down in Med6 mutants. 
     FIGS. 33A-33F show genes which are affected in Srb10 mutants; all of these genes go up and the list is in rank order of degree affected. See especially column headed Gene and column headed Fold up. 
     FIGS. 34A-34L show genes which are affected in SWI2 mutants; those in FIGS. 34A-34F go up and those in FIGS. 34G-34L go down. See especially column headed Fold up and column headed Fold down. 
     FIGS. 35A-35E show genes which go down in TAF 145  mutants. See especially columns headed Gene and % of WT expression. 
     FIG. 36 is a schematic representation of a model of RNA polymerase II transcription initiation machinery which, as depicted here, encompasses more than 85 polypeptides in 10 (sub) complexes: core RNA polymerase II (RNAPII) consists of 12 subunits; TFIIH, 9 subunits; TFIIE, 2 subunits; TFDIIF, 3 subunits; TFIID, 14 subunits; core SRB/mediator, more than 16 subunits; Swi/Snf complex, 11 subunits; Srb10 kinase complex, 4 subunits and SAGA, 13 subunits (see http://www.wi.mit.edu/young/expression.html. site for more details). As detailed in Table 1, representative subunits of these complexes were chosen for analysis of genome-wide transcription dependence. 
     FIGS. 37A-37D show genome-wide expression data for selected components of the RNA polymerase II holoenzyme; data reflecting the change in mRNA levels when a mutant is compared to its isogenic wild type counterpart is presented in a grid format. In the grid, the upper left grid square represents the left-most gene on chromosome I, and the squares to its right represent adjacent genes, proceeding in a linear fashion through chromosome I, then II, the III, etc., until the last gene on the right arm of chromosome XVI is reached at the bottom of the grid. 
     FIG. 37A shows results for Rpb1;  37 B shows results for Med6;  37 C shows results for Srb10; and  37 D shows results for Swi2. 
     FIG. 38A and 38B are Venn diagrams illustrating the genome-wide dependence on key components of the transcription machinery. FIG. 38A illustrates that RNA polymerase II holoenzyme components show distinct patterns of genome control. It is a Venn diagram depicting Srb5-, Swi2-, Srb10- and Med6-dependent genes (small circles) in relation to the whole transcriptome (Rpb1-, Srb4- and Kin28 dependent, large circle). The numbers under each subunit name are the sum of genes whose expression depends on that subunit. FIG. 38B illustrates genome control patterns of components of TFIID and SAGA. 
     FIGS. 39A and 39B present results showing that Srb5 is required for expression of pheromone response genes. FIG. 39A shows the pheromone response genes whose expression is reduced in the absence of Srb5. FIG. 39B is a graph showing that cells lacking Srb5are defective in mating. The mating efficiencies for mutant strains are expressed as a percentage of the mating efficiency of an isogenic wildtype strain. For comparison, strains with mutations in two components of the mating signal transduction pathway (FUS3 and STE2) are included. 
     FIGS. 40A-40C present results showing that Srb10 CDK represses genes elevated during response to nutrient starvation. FIG. 40A is a subset of 173 genes whose expression is depressed in cells lacking Srb10 kinase activity. FIG. 40B is a Venn diagram showing the number of genes which are depressed during the nutrient deprivation which occurs during the diauxic shift and the fraction of these which are depressed in cells lacking Srb10 kinase activity. FIG. 40C is a graph which shows that Srb10 protein is depleted from cells as they enter the diauxic shift. The graph shows the growth curve of a yeast strain allowed to grow to stationary phase (33 hours). 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     Detailed information and databases supporting all aspects of the work described herein, including experimental procedures, genetic reagents, HDA technology and data analysis can be found on the Internet at http://www.wi.mit.edu/young/expression.html. The entire contents of this Web site are incorporated herein by reference. 
     As described herein, HDAs were used to determine the effects of mutations on key components of the RNA polymerase II transcriptional machinery genome-wide in eukaryotic cells and, as a result, to assess the requirements for these components. As described in the examples which follow, the levels of all detectable mRNA species in yeast were determined using HDAs. Results showed that transcripts from 80% of expressed yeast genes exist at steady state levels of 0.1 to 2 molecules/cell. 
     Dependence of genome expression on key components of the transcriptional machinery was assessed, using mutations which affect either the function or the physical presence of one or more subunits of machinery components (RNA polymerase II core enzyme, the general transcriptional factors (GTFs), the core Srb/mediator complex, the Srb10 CDK complex, the Swi/Snf complex and the SAGA complex). Specifically described in the examples is work which resulted in determination of the levels of all detectable mRNA species in yeast, which is useful in evaluating the degree to which these levels depend on any one component of the transcription apparatus. Also described in the examples is assessment of the roles of components of the transcriptional machinery in genome-wide gene expression, using yeast as a eukaryotic model. As described, one or more subunits of the RNA polymerase II core enzyme, the general transcription factors (GTFs), the core Srb/mediator complex, the Srb10 CDK complex, the Swi/Snf complex and the SAGA complex have been investigated for their roles in genome-wide expression. This was carried out through the use of mutations which affect either the function or the physical presence of the subunit being assessed (see Table 1). The work described herein was carried out using yeast, but a similar approach (in which mutations which affect either the function or physical presence of one or more subunits of the transcription initiation machinery are used to assess dependence of genome expression on machinery components) can be used in other eukaryotic cells, including cells from vertebrates (e.g., cells of human and other primate origin, murine, canine, feline and bovine origin) and cells from non-vertebrates (e.g., cells from worms and flies). 
     Results showed that the Rpb1 subunit of core RNA polymerase II, the Srb4 subunit of the Srb/mediator complex and the Kin28 subunit of the general transcription factor TFIIH are generally required for transcription of protein-coding genes. Results also showed that only a subset of genes is dependent on Med6, Srb5, Srb10, Swi2, TAF II 145, TAF II 17 and Gcn5. The sets of genes whose expression requires various RNA polymerase II holoenzyme components are compared in the Venn diagram of FIG.  38 A. The sets of genes whose expression requires various TFIID and SAGA components are shown in the Venn diagram of FIG.  38 B. Together, these diagrams show how distinct sets of genes require the function of distinct components of the transcription machinery. 
     Thus, coordinate regulation of large sets of genes can be accomplished by affecting the function of specific components of the transcriptional machinery. For example, FIG. 38A shows, in addition to the three key RNAPII holoenzyme components which are generally required for transcription of protein-coding genes, at least four other components which regulate expression of subsets of genes. Specifically, Srb5 regulates expression of 698 genes; Med6 regulates expression of 506 genes; Swi2 regulates expression of 329 genes and Srb10 regulates expression of 173 genes. Coordinate regulation of genes in each of these sets of genes can be effected by altering (enhancing or reducing/repressing) function or activity of the respective regulating components (e.g., Srb5, Med6, Swi2, Srb10). Even broader coordination can be accomplished by altering (enhancing or reducing/repressing) function of one or more of the three RNAPII holoenzyme components (Rpb1, Srb4, Kin28) shown to be generally required for transcription of protein-coding genes. It is interesting to note the “overlap” of genes regulated; that is, the fact that expression of some genes is regulated by two components(e.g., 62 genes are regulated by Srb5 and Med6; 86 by Srb5 and Swi2; 12 by Srb5 and Srb10; 30 by Srb10 and Swi2 and 28 by Swi2 and Med6). FIG. 38B presents comparable information for TFIID and SAGA components. In addition to Rpb1, Srb4 and Kin28, other components regulate a large number of genes: TAF II  17, 3180 genes; TAF II 145, 766 genes; and Gcn5, 268 genes. Here, too, overlap is evident: TAF II 17 and TAF II 145 regulate 562 genes in common; TAF II 17 and Gcn5 regulate 50 genes in common; TAF II 145 and Gcn5 regulate 7 genes in common and the three regulate 15 genes in common. 
     The following is a summary of results described in greater detail herein. 
     General Factors 
     Rpb1 and Srb4 proteins are generally required for expression of protein-coding genes, and they are both associated tightly and exclusively with RNA polymerase II and the mediator complex, respectively (Koleske, A. J. and Young, R. A. (1994)  Nature  368, 29970-7; Kim, Y. J. et al., (1994)  Cell  77, 599-608; Myers, L. C. et al.,  Genes Dev  12, 45-54). Therefore, it is reasonable to infer that RNA polymerase II and the core mediator complex are generally required for transcription. Assuming that the function of Kin28 is restricted to TFIIH, the data obtained with the Kin28 mutant demonstrates that TFIIH is a general factor. The expression of 54% of yeast genes is as dependent on Tfal as it is on Rpb1, supporting the idea that TFIIE is directly involved in expression of at least 54% of protein-coding genes. Without knowing the contribution of Tfa2, the other subunit of TFIIE, one cannot eliminate the possibility that TFIIE has roles at additional genes. 
     SRB/Mediator Complex 
     The SRB/mediator core complex is essential for general transcription, as evidenced by the requirement for Srb4, but components such as Srb5 and Med6 have roles at specific subsets of genes. These results are consistent with the proposal that the Srb/mediator complex is recruited to promoters of most genes together with RNA polymerase II, where it acts in a manner analogous to a signal processor with the capacity to integrate the combinatorial effects of multiple inputs from gene-specific transcriptional activators and repressors. (Koleske, A. J. and Young, R. A. (1994)  Nature  368, 466-9; Kim, Y. J. et al., (1994)  Cell  77, 599-608; Koh, S. S. et al., (1998)  Cell  1, 895-904; Myers, L. C. et al.,  Genes Dev  12, 45-54; Sun, X. et al., (1998)  Molecular Cell  2,1-11) 
     Srb10 CDK Complex 
     The function of the Srb10 CDK complex can be defined by the kinase itself, since loss-of-function mutations in any of the four components of this complex produce identical phenotypes (Hengartner, C. J. et al (1995)  Genes and Development  9, 897-910). The Srb10 kinase is a negative regulator of a substantial fraction of genes which are repressed when cells grow vegetatively in rich media and are induced as cells experience nutrient deprivation. The genes regulated by Srb10 include those which are critical for the morphological change which permits foraging for nutrients and stress responses. Srb10 is physically depleted from cells as they enter the diauxic shift, providing a mechanism for derepression of this set of genes. Srb10 in wild type cells is, thus, responsible for repressing this set of genes when cells are in exponential growth on glucose, but no longer performs this function as cells enter the diauxic shift. 
     Swi/Snf Complex 
     If the function of the Swi/Snf complex is ATP-dependent remodeling of chromatin, (Laurent, B. C. et al., (1993)  Genes Development  7, 583-91; Cote, J. et al., (1994)  Science  265, 53-60), then the effects observed herein due to the Swi2 ATPase mutation should represent the dependence of genome-wide expression on the entire Swi/Snf complex. The results indicate that a greater number of genes is negatively regulated by Swi/Snf than is positively regulated. This is surprising in view of the model that Swi/Snf-catalyzed remodeling of chromatin facilitates activator binding. It is possible that chromatin remodeling may facilitate binding of negative factors as well as positive factors. An alternative possibility is suggested by recent data indicating that the Swi/Snf complex can remodel chromatin in both directions: it can convert a repressive nucleosome structure towards a more accessible state and vice versa (Schnitzler, G. et al (1998)  Cell  94, 17-27). It is thus possible that Swi/Snf helps produce a nucleosome structure conducive to transcription at some promoters, and a structure which is repressive at others. 
     TFIID and SAGA 
     The general transcription factor TFIID and the SAGA complex share two features: they both contain a subunit capable of histone acetylation (TAF II 145 in the case of TFIID and Gcn5 in the case of SAGA) and they share multiple subunits, among which is the histone H3-like TAF, TAF II 17 (Grant, P. A. et al (1998)  Cell  94, 45-53). As summarized in FIGS. 39A-39B, the results indicate that Gcn5, TAF II 145 and TAF II 17 are necessary for expression of 5%, 16% and 67% of yeast genes, respectively. Two models can account for this data: one posits that TAF II 17 functions exclusively within the TFIID and SAGA complexes, and the other that TAF II 17 is a component of one or more additional complexes. If TAF II 17 functions exclusively within the TFIID and SAGA, then TAF II 45 and Gcn5 do not fully represent the functions of the two complexes, since the sum of genes which require TAF II 145 and Gcn5 function is much smaller than the number of genes which require TAF II 17. In this model, one or both complexes contain subunits which make different contributions to gene expression, as might be expected if different subunits are targets of different transcriptional activators and repressors. The results can also be accommodated in a second model, in which TAF II 17 is a component of one or more complexes in addition to TFIID and SAGA. The results described here lay a useful foundation for the additional experiments necessary to gain a fuller understanding of the roles of TFIID and SAGA subunits in gene expression. 
     The data presented herein, in conjunction with that of previous studies, reveal several striking similarities between TAF II 145 and prokaryotic sigma factors. First, both sigma factors and TAF II 145 are components of the general transcription machinery. Second, many sigma factors are required for the expression of a related subset of genes; similarly, it has been shown that TAF II 145 appears to be required for expression of a set of genes involved in chromosomal synthesis and G1/S progression. Finally, both sigma factors and TAF II 145 act through core promoter elements by direct DNA contacts. 
     An unexpected finding of the work described herein is the role Srb5 has in pheromone response. It was striking that many of the genes whose mRNA levels are most dramatically affected by the loss of Srb5 fall into the pheromone response pathway. The 15 genes involved in the pheromone response which are expressed at substantially lower levels in the absence of Srb5 are shown in FIG.  39 A. Dramatic effects are seen in genes involved in mating factor production and export; the expression of MFA 1 and MFA2, the two genes encoding mating pheromone a-factor, are down 28-fold and 11-fold, respectively. Additional genes involved in maturation (STE13) and export (STE6) of mating factor are expressed at substantially lower levels than in the cognate wild type. Furthermore, several components of the signal transduction pathway that responds to mating pheromone are expressed at reduced levels in the Srb5 mutant. These genes include the receptor for pheromone (STE2), subunits of the signaling G-protein (GPA1), and the transcription factor which is itself the target of the signaling response and directly regulates subsequent gene expression (STE12). 
     The genome-wide expression profile for the Srb5 mutant suggests that these cells should exhibit a defect in mating efficiency, a phenotype which was not previously suspected or investigated. Indeed, quantitative mating assays show that Srb5 mutant does have a significant defect in mating (FIG.  39 B). The mating defect was more pronounced than that due to mutations in Fus3, a MAP kinase required for cell cycle arrest and cell fusion during mating, but less pronounced than that due to mutations in STE12. The defect in mating deficiency exhibited by the Srb5 mutant may reflect coordinate regulation of the set of pheromone response genes identified through genome-wide expression analysis. 
     The present invention is illustrated by the following examples, which are not intended to be limiting in any way. Detailed information and databases supporting all aspects of this study can be found on the Internet at http://www.wi.mit.edu/young/expression.html. The entire content of this web site, including the content of all linked sites (e.g., hypertext) is expressly incorporated herein by reference in its entirety. 
     EXAMPLE 2 
     Determination of the Levels of All Detectable MRNA Species in Yeast 
     Knowledge of the levels of all detectable mRNA species in yeast is useful for evaluating the degree to which these levels depend on any one component of the transcription apparatus. To obtain this information and to assess the reproducibility of the HAD technology, RNA was harvested from two independent wild type cultures and compared using two sets of HDAs on two separate days (see Example 1, above. The HDAs used here can score mRNA levels for up to 6181 genes. This is a more accurate representation of the transcriptome than that previously determined because it is better able to score mRNA species which are expressed at very low levels (5460 genes were scored using HDAs, whereas 4465 genes were scored with SAGA). It is particularly valuable to have information on transcripts from genes expressed at low levels because many of the regulatory components of the cell are expressed at low levels. 
     Of the 5460 genes whose mRNA levels were accurately determined and compared in both experiments, 99% of the mRNAs differed no more than 1.7 fold, and only 35 transcripts (0.65) showed more than a two-fold change. In order to prevent these minimal variations from influencing the results, all experiments were performed in duplicate. The levels determined for the 5460 transcripts in wild type yeast cells and additional information derived from this experiment are described above. The SAGA method has previously been used to determine values for 4465 transcripts, the results of which has been termed the yeast transcriptome. (Velculescu, V. E. et al (1997)  Cell,  88, 243-51). The sensitivity of the HDA technology permitted a determination of the levels of many additional gene products, and revealed that transcripts from 80% of expressed yeast genes exist at steady state levels of 0.1 to 2 molecules/cell. 
     EXAMPLE 2 
     Assessment of the Role of Components of Transcriptional Machinery in Genome-Wide Gene Expression 
     At any one promoter, the transcriptional machinery might include the RNA polymerase II core enzyme, the general transcription factors (GTFs), the core Srb/mediator complex, the Srb10 CDK complex, the Swi/Snf complex, and the SAGA complex, among others (FIG.  36 ). One or more subunits of each of these components has been investigated for its role in genome-wide gene expression through the use of mutations which affect either the function or the physical presence of the subunit (Table 1). Loss-of-function mutations in various components of the transcription apparatus were constructed or obtained from various investigators Example 1, above. Two types of mutations have proven to be useful in this study. For essential components of the apparatus, temperature-sensitive (ts) mutations are valuable because they allow the investigator to examine effects on gene expression at any point after inactivating the factor. Point mutations which knock out the catalytic function of known enzymatic activities or complete deletion mutations were used to study non-essential components. In each experiment, a mutant cell and its isogenic wild-type counterpart are grown to mid-log phase, the two populations are harvested, RNA is prepared, and hybridization to HDAs is carried out, all in duplicate. 
     Dependence on Core RNA Polymerase II 
     To determine the genome-wide dependence of gene expression on core RNA polymerase II, RNA was isolated from an rpb1-1 temperature sensitive ts cell and its wild type counterpart 45 minutes after a shift to the nonpermissive temperature and was hybridized to HDAs. Because rpb1-1 cells shut down transcription of protein-coding genes immediately after a temperature shift, these cells have been used as described here and by other investigators to determine the half-life of various yeast mRNAs (Nonet M. et al. (1987)  Mol Cell Biol  7, 1602-11; Herrick D. et al (1990)  Mol Cell Biol  10, 2269-84). The 45 minute time point was used for the analysis of all ts mutants in this study because it is sufficiently long to detect a significant (i.e. a two-fold or more) loss of mRNA levels for 94% of detectable gene products without any loss of rRNA (Nonet M. et al., (1987)  Mol Cell Biol  7, 1602-11). In addition, the 45 minutes time point is short enough to minimize the potentially complicating effects of cell cycle arrest and cell death. 
     The results of genome wide expression analysis of the rpb1-1 mutant as compared to an isogenic wild type strain are shown in a grid format in FIG.  37 A. The grid shows the change in mRNA level for each gene, beginning with the left most gene on chromosome I and proceeding in a linear fashion, left to right, through chromosome I and II, then III, etc., until the last gene on the right arm of chromosome IVI is reached at the lower right hand corner. 5735 genes were scored in this analysis. The vast majority of mRNAs are reduced more than two-fold in the mutant cells relative to wild type cells, and this reduction provides an apparent half-life for each of the mRNA species Example 1, above. The value determined with this approach is an approximation, but is useful for comparative purposes. Comparison of this data with that obtained for another ts factor identifies the set of genes whose expression is equivalently dependent on RNA polymerase II and the factor of interest. 
     There is a set of genes whose mRNAs are not significantly reduced in the mutant cells. These consist of genes that have stable messages as well as genes whose mRNA levels are slightly elevated in the mutant cells relative to wild-type. In this latter group are many known heat shock or stress response genes (e.g. SSA4, SSA3, HSP26, HSP30, HSP42 and SSL2), plus additional ORFs of unknown but perhaps related function. Similar results were obtained using ts mutants in other general transcription factors. 
     Dependence on Srb/Mediator Core Subunits 
     The Srb/mediator complex is tightly associated with RNA polymerase II in a complex which has been termed the holoenzyme (Koleske A. J., and Young, R. A. (1994)  Nature  368, 466-9; Kim, Y. J. et al., (1994)  Cell  77, 599-608). Srb4 is an essential component of the Srb/mediator complex (Thompson, C. M. et al., (1993)  Cell  73, 1361-75; Kim, Y. J. et al., (1994)  Cell  77, 599-608); Hengartner, et al., (1995)  Genes and Development  9, 897-910). A ts mutant in Srb4 (srb4-138) was previously used to obtain evidence that several protein-coding genes require the function of Srb4, and are thus likely to have the holoenzyme form of RNA polymerase II recruited to their promoters (Thompson, C. M., and Young, R. A. (1995)  Proc Natl Acad Sci USA  92, 4587-90). Genome-wide expression analysis provides a more rigorous test of the model that expression of all protein-coding genes is dependent on Srb4. The experiment was carried out with the same protocol used with the Rpb1 ts mutant. Of the 5361 genes whose mRNA expression levels could be compared (i.e., those that had a greater than two-fold decrease in the experiment with Rpb1 ts and were scored in the Srb4 ts experiment), 93% showed a decrease that closely fit the decreased observed in the Rpb1 ts experiment. Of the mRNAs that did not closely fit the Rpb1 ts decay, only 2 could be found that reproducibly showed large differences in their decay in the two experiments performed. Furthermore, the set of genes whose mRNAs are not significantly reduced in the Rpb1 ts mutant exhibit the same behavior in the Srb4 ts experiment. The results indicate that genome-wide expression is a dependent on Srb4 as it is on core RNA polymerase II (see Genome-Wide Expression Data on the Web site for details). Srb4 is associated tightly and exclusively with the RNA polymerase II holoenzyme (Koleske, A. J., and Young, R. A. (1994)  Nature  368, 466-9; Kim, Y. J. et al., (1994)  Cell  77, 599-608; and Myers, L. C. et al., (1998)  Genes Development  12, 45-54). Thus, it is reasonable to infer Srb4-containing RNA polymerase II holoenzyme is generally required for transcription. 
     Med6 is another essential component of the Srb/Mediator complex and appears to be physically associated with Srb4 (Li, Y. et al., (1995)  Proc Natl Acad Sci USA  92, 1064-68; Myers, L. C. et al., (1998)  Genes Development  12, 45-54; Lee, T. I. et al., (1998). A Med6 ts mutant has been generated and used to demonstrate that Med6 is necessary for full induction of GAL, SUC2, MFA1 and PKY1 genes, but is not required for expression of several others. (Lee, Y. C. et al., (1997)  Mol Cell Biol  17,4622-32). The genome-wide dependence of gene expression on Med6 was determined with this Med6 ts strain as described above for Rpb1. The results indicate that the expression of 10% of yeast genes is as dependent on Med6 as it is on Rpb1 (FIG. 37B; see the Web site for detailed information). 
     The reduction in mRNA levels observed in ts mutants soon after a temperature shift (i.e., 45 minutes) is likely a consequence of primary effects due to factor inactivation because the time required to produce most secondary effects involves a substantial reduction in both a transcript and its translation product. Nonetheless, the results obtained in this type of experiment must be regarded as the sum of primary and secondary effects. To identify the set of genes whose change in expression is most likely a direct consequence of the loss of function of the ts factor, data from ts inactivation of RNA polymerase II was compared with that obtained by ts inactivation of any other factor. Comparison of the two data sets reveals the transcripts with equivalent decay kinetics in rpb1-1 and the other ts mutant Example 1, above. For those genes affected by ts disruption of Med6 where such a comparison could be made, the mRNAs of 506 genes decreased with similar kinetics in the Med6 and Rpb1 experiments. Thus, the expression of 10% of yeast genes is as dependent on Med6 as it is on Rpb1. These 506 genes are most likely to have a direct requirement for Med6 function. The genes whose transcript levels do not fit the Rpb1 kinetics could have a direct, but partial, requirement for Med6 function, or the effects observed at these genes are a secondary consequence of some other gene&#39;s altered mRNA levels. The 506 genes identified which require Med6 function to the same extent as Rpb1 function are those at which promoter-associated transcriptional regulators are most likely to function through interactions with Med6. 
     Srb5 is a component of the Srb/Mediator complex whose function is also not known (Thompson, C. M. et al., (1993)  Cell  73, 1361-75; Kim, Y. J. et al., (1994)  Cell  77, 599-608); Koleske, A. J., and Young, R. A., (1994)  Nature  368, 466-9; Hengartner, C. J. et al., (1995)  Genes and Development  9, 897-910; Myers, L. C. et al., (1998)  Genes and Development  12, 45-54). To determine the genome-wide dependence of gene expression on Srb5, a strain lacking an SRB5 gene and its wild type counterpart were compared (Example 1 above). The results indicate that 16% of all genes require Srb5 function for their expression. With the SRB5 deletion strain and other constitutive mutants analyzed here, it is not possible to distinguish between results which are a direct consequence of the loss of Srb5 function and those which are due to a secondary effect such as the loss of another transcriptional regulator. Nonetheless, these results provide important information in that they reveal the complete set of genes which are directly or indirectly affected by loss of Srb5 function. It was striking that expression of many genes central to the pheromone response pathway are dramatically affected by the loss of Srb5, as discussed herein. 
     Dependence on SRb10 CDK Complex 
     Srb10 is cyclin dependent kinase which is part of a holoenzyme subcomplex containing Srb8, 9, 10 and 11 proteins (Liao, S. M. et al., (1995)  Nature  374, 193-6; Hengartner, C. J. et al., (1995)  Genes and Development  9, 897-910). Srb10 and its associated proteins have been proposed to form a negative regulatory complex which functions through phosphorylation of the RNA polymerase II complex CTD (Hengartner, C. J. et al., (1998)  Molecular Cell  2, 45-53). To determine how gene expression depends on Srb10, RNA was isolated from an Srb10 point mutant which lacks catalytic activity and the expression profile was compared to that of its wild type counterpart. The results are shown in a grid format in FIG.  37 C. Of the 5626 genes which were scored, 173 gene products showed 2-fold or greater increases in mRNA levels in the mutant relative to the wild type. This indicates that Srb10 is normally a negative regulator of these 173 genes (approximately 3% of the genome). 
     It is notable that nearly half of these genes are derepressed during the nutrient deprivation which occurs during the diauxic shift. (DeRisi, J. et al., (1997)  Science  278, 680-86). (FIGS. 40A-40C) Yeast cells undergo a diauxic shift as nutrients are depleted in culture, and a variety of genes which enable the cell to survive nutrient-limiting conditions are derepressed (Johnston, M., and Carlson, M. (1992)  Gene Expression p.  193; Yin, Z. et al., (1996)  Molecular Microbiology  20, 751-64). These include genes involved in dimorphic morphology (nutrient starved cells alter their morphology to permit foraging for nutrients) and stress responses (starved cells are apparently better able to survive nutrient deprivation when stress proteins are elevated). Srb10 in wild type cells is most likely responsible for repressing this set of genes when cells are in exponential growth on glucose, but no longer performs this function as cells enter the diauxic shift. Coordinate regulation of this set of genes could be accomplished by eliminating the function of Srb10 as cells enter the diauxic shift. 
     To determine whether Srb10 is physically lost from cells as they enter the diauxic shift, cells containing an epitope-tagged Srb10 protein were grown in YPD media and sampled at various times during the growth curve. (FIG.  40 C). Cell lysates were prepared from each sample and the levels of Srb10 were assayed by Western blot. Results showed that Srb10 is physically depleted as cells enter the diauxic phase of growth. This result is consistent with evidence that the levels of Srbl 1, the cyclin partner of Srb10, are reduced when cells are exposed to the limiting nutrient environment in sporulation media. (Cooper, K. F. et al., (1997)  EMBOJ  16, 4665-75.) It may also explain why a form of yeast holoenzyme purified from commercially available yeast cells lacks the Srb10/Srb11 kinase/cyclin pair (Li, Y. et al., (1995)  Proc Natl Acad Sci USA  92, 10864-8; Myers, L. C. et al., (1998)  Genes Development  12, 45-54), as these cells are typically grown past mid-log phase. The results thus indicate that the nutrient starvation response is mediated, in part, through the physical loss of the Srb10 CDK from the holoenzyme. This novel mechanism provides one example of how coordinate regulation of gene expression can be accomplished through regulation of components of the general initiation machinery. 
     FLO11, which encodes a cell wall protein which is highly expressed in pseudohyphal cells, is expressed at 15-fold higher levels when Srb10 function is lost (FIG.  40 A). The dramatic increase in the expression of FLO11 and other genes whose products are involved in the dimorphic shift led Applicants to determine whether the absence of Srb10 function produces a pseudohyphal phenotype. Both copies of the SRB10 gene were deleted from a diploid strain which is generally used to assay this phenotype, and colony morphology was examined under the microscope. Results demonstrated that the loss of Srb10 causes cells to grow preferentially in a pseudohyphal form. This again shows that expression analysis is useful for predicting unexpected phenotypes. More importantly, specific signal transduction pathways control the dimorphic shift (Madhani, H. D., and Fink, G. R., (1998)  Trends Cell Biology  8, 348-53), and these results suggest that one of the ultimate targets of these pathways is the Srb10 kinase. 
     Dependence on Swi/Snf 
     Swi2 ATPase activity plays an essential role in the ability of the Swi/Snf complex to remodel chromatin (Laurent, B. C. et al., (1993)  Genes Development  7, 583-91; Cote, J. et al., (1994)  Science  265, 53-60; Khavari, P. A. et al., (1993)  Nature  366, 170-4). This activity is thought to facilitate activator and transcription apparatus binding to promoter regions for a small number of genes, thereby overcoming repression by nucleosomes at those promoters (Cote, J. et al., (1994)  Science  265, 53-60; Imbalzano, A. N. et al., (1994)  Nature  370, 481-5; Kwon, H. et al., (1994)  Nature  370, 477-81; Burns, L. G. and Peterson, C. L., (1997)  Mol Cell Biol  17, 4811-9). Consequently, it was expected that a small number of genes would be reduced in expression levels in the Swi2/Snf2 mutant. To determine the genome-wide dependence of gene expression on the Swi/Snf complex, RNA was isolated from a Swi2/Snf2 point mutant which lacks ATPase activity and its wild type counterpart and the two RNA preparations were hybridized to HDAs. The surprising result was that a greater number of genes appear to be negatively regulated by Swi/Snf than are positively regulated (FIG. 37D; Example 1, above). The data show that 203 gene products were elevated 2-fold or more in the mutant relative to the wild type, while just 126 transcripts decreased 2-fold or more (See Genome-Wide Expression Data on the Web site). As described herein, this result may be explained by recent data indicating that the Swi/Snf complex can catalyze chromatin remodeling in either direction (Schnitzler, G. et al., (1998)  Cell  94, 17-27). 
     Dependence on General Transcription Factors 
     The general transcription factors are necessary to reconstitute promoter-dependent transcription in vitro with core RNA polymerase II. These factors include TFIID, TFIIB, TFIIF, TFIIE and TFIIH. Among these factors, TFIIE and TFIIH are of particular interest because numerous reports have suggested that they are in fact not generally required for gene expression (Parvin, J. D. et al., (1992)  Cell  68, 1135-44; Serizawa, H. et al., (1993)  Nature  363, 371-4; Timmers, H. (1994)  EMBOJ  13, 391-9; Holstege, F. C. et al., (1995)  EMBOJ  14, 810-9; Sakurai, H. et al., (1997)  J Biol Chem  272, 15936-42; Kuldell, N. H., and Buratowski, S., (1997)  Mol Cell Biol  17, 5288-98; Tijerina, P., and Sayre, M. H., (1998)  J Biol Chem  273, 1107-13). Genome-wide expression analysis was carried out on a Kin28 ts cell and its isogenic wild type counterpart using the same experimental protocol used for the Rpb1 ts mutant. Kin28, a CDK subunit of TFIIH, is an RNA polymerase II CTD kinase which is involved in the transition from initiation to elongation (Dahmus, M. (1996)  J Biol Chem.  271, 19009-19012). The results reveal that Kin28 is generally required for expression of protein-coding genes (Example 1, above). TFIIE is thought to facilitate certain functions of TFIIH. In contrast to the results obtained with Kin28, analysis of genome-wide expression with a Tfa1 ts mutant shows that only 54% of yeast genes require the largest subunit of TFIIE to the same extent as core RNA polymerase II (see Example 1, above). 
     The TBP-associated factors (TAF II S) of TFIID are especially interesting because they have been postulated to play important roles in promoter selectivity and gene activation (Burley, S. K., and Roeder, R. G., (1996)  Annu Rev Biochem  65, 769-99; Veirijzer, C. P., and Tijan, R., (1996)  Trends Biochem Sci  21, 338-42; Lee, T. I., and Young, R. A., (1998)  Genes and Development  12, 1398-1408). A ts mutation in the TFIID subunit TAF II 145 (Walker, S. S. et al., (1997)  Cell  90, 607-14) was used to determine the genome-wide dependence of gene expression on this TAF. Of the 5441 genes which were scored, 1618 genes products were reduced by 2-fold or greater on average in the two comparisons made, 45 minutes after temperature shift. For those genes where a comparison with the Rpb1 experiment could be made, 16% showed a dependence on TAF II 145 that was similar to their dependence on Rpb1 (see Example 1, above). Interestingly, a large number of genes involved in functions associated with progression through the cell cycle are among the genes most likely to have a direct requirement for TAF II 145 function. The TAF II 145 ts mutant has a cell cycle phenotype: it arrests growth in G1-S after cells are shifted to the nonpermissive temperature. Previous studies showed that several G1-S cyclin genes are expressed at reduced levels in these cells, perhaps accounting for the cell cycle arrest phenotype TAF II 145. (Walker, S. S. et al., (1997)  Cell  90, 607-14) A subset of the genes that have a direct requirement for TAF II 145 function and which are involved in functions associated with progression through the cell cycle are listed in Table 2. For example a significant decrease in mRNA levels was observed for Ctr9, which is required for expression of G1 cyclins Cln1 and Cln2. In addition, genes which are involved in DNA repair and DNA synthesis are dependent on TAF II 145 function. Thus, the G1/S arrest phenotype of TAF II 145 mutants may be due to multiple defects in cyclin and chromosome synthesis which occur during this period of the cell cycle. 
     Analysis of which genes depend on TAF II 17, a histonc H3-like TAF which is shared by TFIID and SAGA complexes, for their expression was also carried out. RNA was isolated from a TAF II 17 temperature sensitive cell (TAF17-ts) and its wild type counterpart 45 minutes after a shift to the nonpermissive temperature and was hybridized to RDAs. Of the yeast genes identified in the TAF II 17 experiment and appropriate for comparison, 67% are as dependent on TAF II 17 function as they are on Rpb1, and are thus most likely to have a direct requirement for TAF II 17 function Example 1, above. This indicates that TAF II 17 is critical for the expression of a much larger portion of the transcriptome than TAF II 145. The presence of TAF II 7 in two different complexes may account for this observation. 
     Dependence on Gcn5 Subunit of SAGA 
     The recent discovery that certain TAFs are components of both the TFIID general transcription factor and the SAGA complex (Grant, P. A. et al., (1998)  Cell  94, 45-53) makes it particularly interesting to compare the effects of a mutation in a component specific to each complex (TAF II 145 in the case of TFIID and Gcn5 in the case of SAGA) with those of a mutation in a component shared by the two complexes (TAF II 17). The expression profile of a GCN5 deletion mutant was compared with its isogenic counterpart (Example 1, above). Of the 4912 genes which were scored, 185 transcripts were reduced by 2-fold or more and 83 increased by 2-fold or more. 
     The Gcn5 results indicate that this component of SAFA is necessary for normal expression of no more than 5% of yeast genes. Expression of 16% of protein-coding genes depends on the TAF II 145 subunit of TFIID to the same extent they depend on Rpb1. In contrast, the expression of 67% of yeast genes depends on the function of the TAF II 17 subunit shared by SAGA and TFIID. 
     
       
         
               
             
               
               
               
             
           
               
                 TABLE 1 
               
             
             
               
                   
               
               
                 Transcriptional Machinery 
               
             
          
           
               
                   
                   
                 Fraction 
               
               
                   
                   
                 of genes 
               
               
                   
                   
                 depen- 
               
               
                   
                   
                 dent on 
               
               
                 Complex 
                   
                 subunit 
               
               
                 and Subunit 
                 Features 
                 function 
               
               
                   
               
               
                 RNA Polymerase II 
                   
                   
               
               
                 Rpb1 
                 Largest subunit, mRNA catalysis, 
                 100%  
               
               
                   
                 contains CTD 
               
               
                 Srb/mediator (core) 
               
               
                 Srb4 
                 Target of Gal4 activator 
                  93%* 
               
               
                 Srb5 
                 Unknown function 
                 16% 
               
               
                 Med6 
                 Role in activation of some genes 
                 10% 
               
               
                 Srb CDK complex 
               
               
                 Srb10 
                 CTD kinase, negative regulator 
                  3% 
               
               
                 Swi/Snf 
               
               
                 Swi2 
                 ATP-dependent chromatin remodeling 
                  6% 
               
               
                 General Transcription 
               
               
                 Factors 
               
               
                 TFIID (TAF II 145) 
                 Large TBP-associate factor, histone 
                 16% 
               
               
                   
                 acetylase 
               
               
                 (TAF II 17) 
                 Component of both TFIID and SAGA 
                 67% 
               
               
                 TFIIE (Tfal) 
                 Promoter opening 
                 54% 
               
               
                 TFIIH (Kin28) 
                 CTD kinase 
                  87%* 
               
               
                 SAGA 
               
               
                 Gcn5 
                 Histone acetylase 
                  5% 
               
               
                 TAF II 17 
                 Component of both TFIID and SAGA 
                 67% 
               
               
                   
               
               
                 *Srb4 and Kin28 results were essentially identical to Rpb1, but because of the stringency applied by the fit algorithm, a minimal estimate is produced.  
               
             
          
         
       
     
     
       
         
               
             
               
               
               
             
           
               
                 TABLE 2 
               
             
             
               
                   
               
               
                 Genes That Require Taf145 Function 
               
               
                 Cell Cycle 
               
             
          
           
               
                   
                   
                 FOLD 
               
               
                   
                   
                 RE- 
               
               
                   
                   
                 DUC- 
               
               
                 GENE 
                 DESCRIPTION 
                 TION 
               
               
                   
               
               
                 *DDCI 
                 DNA damage checkpoint protein 
                 10  
               
               
                 YER066W 
                 Similar to CDC4, which degrades G1 cyclins 
                 9 
               
               
                 SPO1 
                 Possible role in spindle pole body duplication 
                 8 
               
               
                 *LTE1 
                 GDP/GTP exchange factor 
                 8 
               
               
                 *MKK2 
                 Kinase involved in cell wall integrity 
                 8 
               
               
                 *BIM1 
                 Possible role in early spindle pole body assembly 
                 8 
               
               
                 *MDM1 
                 Involved in mitochondrial segregation 
                 7 
               
               
                 *CTR9 
                 Required for normal expression of G1 cyclins 
                 7 
               
               
                 *PAC1 
                 Possible role in spindle pole body orientation 
                 6 
               
               
                 *SCP160 
                 Involved in control of chromosome transmission 
                 6 
               
               
                 CDC13 
                 Telomere binding protein 
                 6 
               
               
                 *TOP3 
                 DNA topoisomerase III 
                 5 
               
               
                 *TRX1 
                 Thioredoxin I 
                 5 
               
               
                 ARD1 
                 N-acetyltransferase 
                 5 
               
               
                 *SCC2 
                 Required for sister chromatid cohesion 
                 5 
               
               
                 *CLB2 
                 G2/M cyclin 
                 5 
               
               
                 *KIP2 
                 Kinesin related protein 
                 5 
               
               
                 *MEC1 
                 Cell cycle checkpoint protein 
                 4 
               
               
                 RAD9 
                 DNA repair checkpoint protein 
                 4 
               
               
                 *SPC98 
                 Spindle pole body component 
                 4 
               
               
                 *BCK1 
                 Kinase involved in cell wall integrity 
                 4 
               
               
                 DNA Repair 
               
               
                 *RAD3 
                 Involved in nucleotide excision repair 
                 8 
               
               
                 *YHR031C 
                 Possible role in chromosome repair 
                 7 
               
               
                 *RAD5 
                 Involved in DNA repair 
                 6 
               
               
                 *HSM3 
                 Involved in mismatch repair 
                 6 
               
               
                 *RAD50 
                 Involved in recombinational repair 
                 5 
               
               
                 *EXO1 
                 Involved in mismatch repair 
                 5 
               
               
                 *MSH3 
                 Involved in mismatch repair 
                 5 
               
               
                 YER041W 
                 Similar to DNA repair protein, Rad2 
                 5 
               
               
                 REV1 
                 Involved in translesion DNA synthesis 
                 4 
               
               
                 HDF2 
                 Involved in DNA end-joining repair pathway 
                 4 
               
               
                 MSH6 
                 Involved in mismatch repair 
                 4 
               
               
                 DNA 
               
               
                 Synthesis 
               
               
                 *MCM3 
                 Involved in replication initiation, MCM/P1 family 
                 13  
               
               
                 RLF2 
                 Chromatin assembly complex, subunit 2 
                 9 
               
               
                 *MCM6 
                 Involved in replication initiation, MCM/P1 family 
                 9 
               
               
                 REV7 
                 DNA polymerase subunit zeta 
                 7 
               
               
                 *MIP1 
                 Mitochrondial DNA-directed DNA polymerase 
                 6 
               
               
                 *CDC47 
                 Involved in replication initiation, MCM/P1 family 
                 6 
               
               
                 *CDC5 
                 Kinase 
                 5 
               
               
                 *CDC46 
                 Involved in replication initiation, MCM/P1 family 
                 5 
               
               
                 *RFC1 
                 DNA replication protein RFC large subunit 
                 5 
               
               
                 *CAC2 
                 Chromatin assembly complex, subunit 1 
                 5 
               
               
                   
               
               
                 *Gene exhibits equivalent dependence on Taf145 and Rbp1 for normal expression  
               
             
          
         
       
     
     While this invention has been particularly shown and described with reference to preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as described herein and/or as defined by the appended claims.