Isolation and characterization of new alleles of the cyclin-dependent kinase gene CDC28 with cyclin-specific functional and biochemical defects

Efficient and rapid exact gene replacement without selection

We describe a highly efficient method for exact gene replacement in budding yeast. Induction of rapid and efficient recombination in an entire cell population results in at least 50% of the recombinants undergoing a switch of the endogenous copy to a specific mutated allele, with no remaining markers or remnant of foreign DNA, without selection. To accomplish this, a partial copy of the replacement allele, followed by an HO cut site, is installed adjacent to the wild-type locus, in a GAL-HO MATa-inc background. HO induction results in near-quantitative site cleavage and recombination/gene conversion, resulting in either regeneration of wild-type or switch of the endogenous allele to the mutant, with accompanying deletion of intervening marker sequences, yielding an exact replacement. Eliminating the need for selection (over days) of rare recombinants removes concerns about second-site suppressor mutations and also allows direct phenotypic analysis, even of lethal gene replacements, without the need of a method to make the lethality conditional or to employ regulated promoters of unknown strength compared to the endogenous promoter. To test this method, we tried two known lethal gene replacements, substituting the non-essential CDH1 gene with a dominantly lethal version mutated for its Cdk phosphorylation sites and substituting the essential CDC28 gene with two recessively lethal versions, one containing an early stop codon and another inactivating Cdc28 kinase activity. We also tested a gene replacement of unknown phenotypic consequences: replacing the non-essential CLB3 B-type cyclin with a version lacking its destruction box.

A phosphorylation-independent role for the yeast cyclin-dependent kinase activating kinase Cak1

Cdc28 is the main cyclin-dependent kinase (CDK) directing the cell cycle in the budding yeast Saccharomyces cerevisiae. Besides cyclin binding, Cdc28 requires phosphorylation by the Cak1 kinase to achieve full activity. We have previously isolated carboxy-terminal cdc28(CST) mutants that are temperature sensitive and exhibit high chromosome instability. Both phenotypes are suppressed by high copy Cak1 in a manner that is independent of its catalytic activity and conversely, combination of cdc28(CST) and cak1 mutations results in synthetic lethality. Altogether, these results suggest that for the Cdc28 complexes to remain stable and active, an interaction with Cak1 is needed via the carboxyl terminus of Cdc28. We report two-hybrid assay data that support this model, and results that indicate that actively growing yeast cells require an optimum Cdc28:Cak1 ratio. While Cak1 is constitutively active and expressed, dividing cells tightly regulate Cak1 protein levels to ensure presence of adequate levels of Cdc28 CDK activity.

Bayesian Orthogonal Least Squares (BOLS) algorithm for reverse engineering of gene regulatory networks

Background

A reverse engineering of gene regulatory network with large number of genes and limited number of experimental data points is a computationally challenging task. In particular, reverse engineering using linear systems is an underdetermined and ill conditioned problem, i.e. the amount of microarray data is limited and the solution is very sensitive to noise in the data. Therefore, the reverse engineering of gene regulatory networks with large number of genes and limited number of data points requires rigorous optimization algorithm.

Results

This study presents a novel algorithm for reverse engineering with linear systems. The proposed algorithm is a combination of the orthogonal least squares, second order derivative for network pruning, and Bayesian model comparison. In this study, the entire network is decomposed into a set of small networks that are defined as unit networks. The algorithm provides each unit network with P(D|H_i), which is used as confidence level. The unit network with higher P(D|H_i) has a higher confidence such that the unit network is correctly elucidated. Thus, the proposed algorithm is able to locate true positive interactions using P(D|H_i), which is a unique property of the proposed algorithm.

The algorithm is evaluated with synthetic and Saccharomyces cerevisiae expression data using the dynamic Bayesian network. With synthetic data, it is shown that the performance of the algorithm depends on the number of genes, noise level, and the number of data points. With Yeast expression data, it is shown that there is remarkable number of known physical or genetic events among all interactions elucidated by the proposed algorithm.

The performance of the algorithm is compared with Sparse Bayesian Learning algorithm using both synthetic and Saccharomyces cerevisiae expression data sets. The comparison experiments show that the algorithm produces sparser solutions with less false positives than Sparse Bayesian Learning algorithm.

Conclusion

From our evaluation experiments, we draw the conclusion as follows: 1) Simulation results show that the algorithm can be used to elucidate gene regulatory networks using limited number of experimental data points. 2) Simulation results also show that the algorithm is able to handle the problem with noisy data. 3) The experiment with Yeast expression data shows that the proposed algorithm reliably elucidates known physical or genetic events. 4) The comparison experiments show that the algorithm more efficiently performs than Sparse Bayesian Learning algorithm with noisy and limited number of data.

Identification of novel and conserved functional and structural elements of the G1 cyclin Cln3 important for interactions with the CDK Cdc28 in Saccharomyces cerevisiae

Regions of the budding yeast G1 cyclin Cln3 were characterized using mutational analysis and viability assays to identify functionally relevant and novel mutant alleles of CLN3. Cyclin proteins are conserved, and Cln3 contains a region with homology to the cyclin box, which is thought to mediate physical interactions with the cyclin-dependent kinase. CLN3 was found to have characteristics similar to the conserved cyclin fold found in higher eukaryotic cyclin boxes, which consist of five alpha-helices. Peptide linker sequences inserted within helices 1, 2, 3 and 5 resulted in a loss of Cln3 function, showing cyclin fold structure similar to that previously observed for the G1 cyclin Cln2. A clustered-charge-to-alanine scan mutagenesis revealed two regions of Cln3 important for Cln3-dependent viability. The first region encompasses the conserved cyclin box. The second region is identified with alanine substitutions located well past the cyclin box, just prior to the C-terminal region of Cln3 important for protein stability. Cln3 with mutational changes in each of these regions are expressed at steady-state levels higher than wild-type Cln3, and show some defect in binding to Cdc28. The conserved hydrophobic patch domain (HPD) of cyclins is present within the first helix of the cyclin box. Alanine substitutions introduced into the HPD of Cln3 and Cln2 show functional defects while maintaining physical interaction with Cdc28 as measured by co-immunoprecipitation assay.

Characterization of the Schizosaccharomyces pombe Cdk9/Pch1 protein kinase: Spt5 phosphorylation, autophosphorylation, and mutational analysis

Schizosaccharomyces pombe Cdk9/Pch1 protein kinase is a functional ortholog of the essential Saccharomyces cerevisiae Bur1/Bur2 kinase and a putative ortholog of metazoan P-TEFb (Cdk9/cyclin T). SpCdk9/Pch1 phosphorylates of the carboxyl-terminal domain (CTD) of the S. pombe transcription elongation factor Spt5, which consists of 18 tandem repeats of a nonapeptide of consensus sequence 1TPAWNSGSK9. We document the divalent cation dependence and specificity of SpCdk9/Pch1, its NTP dependence and specificity, the dependence of Spt5-CTD phosphorylation on the number of tandem nonamer repeats, and the specificity for phosphorylation of the Spt5-CTD on threonine at position 1 within the nonamer element. SpCdk9/Pch1 also phosphorylates the CTD heptaptide repeat array of the largest subunit of S. pombe RNA polymerase II (consensus sequence YSPTSPS) and does so exclusively on serine. SpCdk9/Pch1 catalyzes autophosphorylation of the kinase and cyclin subunits of the kinase complex. The distribution of phosphorylation sites on SpCdk9 (86% Ser(P), 11% Thr(P), 3% Tyr(P)) is distinct from that on Pch1 (2% Ser(P), 98% Thr(P)). We conducted a structure-guided mutational analysis of SpCdk9, whereby a total of 29 new mutations of 12 conserved residues were tested for in vivo function by complementation of a yeast bur1Delta mutant. We identified many lethal and conditional mutations of side chains implicated in binding ATP and the divalent cation cofactor, phosphoacceptor substrate recognition, and T-loop dynamics. We surmise that the lethality of the of T212A mutation in the T-loop reflects an essential phosphorylation event, insofar as the conservative T212S change rescued wild-type growth; the phosphomimetic T212E change rescued growth at 30 degrees C; and the effects of mutating the T-loop threonine were phenocopied by mutations in the three conserved arginines predicted to chelate the phosphate on the T-loop threonine.

Mechanisms controlling subcellular localization of the G(1) cyclins Cln2p and Cln3p in budding yeast

Different G(1) cyclins confer functional specificity to the cyclin-dependent kinase (Cdk) Cdc28p in budding yeast. The Cln3p G(1) cyclin is localized primarily to the nucleus, while Cln2p is localized primarily to the cytoplasm. Both binding to Cdc28p and Cdc28p-dependent phosphorylation in the C-terminal region of Cln2p are independently required for efficient nuclear depletion of Cln2p, suggesting that this process may be physiologically regulated. The accumulation of hypophosphorylated Cln2 in the nucleus is an energy-dependent process, but may not involve the RAN GTPase. Phosphorylation of Cln2p is inefficient in small newborn cells obtained by elutriation, and this lowered phosphorylation correlates with reduced Cln2p nuclear depletion in newborn cells. Thus, Cln2p may have a brief period of nuclear residence early in the cell cycle. In contrast, the nuclear localization pattern of Cln3p is not influenced by Cdk activity. Cln3p localization requires a bipartite nuclear localization signal (NLS) located at the C terminus of the protein. This sequence is required for nuclear localization of Cln3p and is sufficient to confer nuclear localization to green fluorescent protein in a RAN-dependent manner. Mislocalized Cln3p, lacking the NLS, is much less active in genetic assays specific for Cln3p, but more active in assays normally specific for Cln2p, consistent with the idea that Cln3p localization explains a significant part of Clnp functional specificity.

Pin1-dependent prolyl isomerization regulates dephosphorylation of Cdc25C and tau proteins

The reversible protein phosphorylation on serine or threonine residues that precede proline (pSer/Thr-Pro) is a key signaling mechanism for the control of various cellular processes, including cell division. The pSer/Thr-Pro moiety in peptides exists in the two completely distinct cis and trans conformations whose conversion is catalyzed specifically by the essential prolyl isomerase Pin1. Previous results suggest that Pin1 might regulate the conformation and dephosphorylation of its substrates. However, it is not known whether phosphorylation-dependent prolyl isomerization occurs in a native protein and/or affects dephosphorylation of pSer/Thr-Pro motifs. Here we show that the major Pro-directed phosphatase PP2A is conformation-specific and effectively dephosphorylates only the trans pSer/Thr-Pro isomer. Furthermore, Pin1 catalyzes prolyl isomerization of specific pSer/Thr-Pro motifs both in Cdc25C and tau to facilitate their dephosphorylation by PP2A. Moreover, Pin1 and PP2A show reciprocal genetic interactions, and prolyl isomerase activity of Pin1 is essential for cell division in vivo. Thus, phosphorylation-specific prolyl isomerization catalyzed by Pin1 is a novel mechanism essential for regulating dephosphorylation of certain pSer/Thr-Pro motifs.

Genetic analysis of the relationship between activation loop phosphorylation and cyclin binding in the activation of the Saccharomyces cerevisiae Cdc28p cyclin-dependent kinase

We showed recently that a screen for mutant CDC28 with improved binding to a defective Cln2p G1 cyclin yielded a spectrum of mutations similar to those yielded by a screen for intragenic suppressors of the requirement for activation loop phosphorylation (T169E suppressors). Recombination among these mutations yielded CDC28 mutants that bypassed the G1 cyclin requirement. Here we analyze further the interrelationship between T169E suppression, interaction with defective cyclin, and G1 cyclin bypass. DNA shuffling of mutations from the various screens and recombination onto a T169E-encoding 3' end yielded CDC28 mutants with strong T169E suppression. Some of the strongest T169E suppressors could suppress the defective Cln2p G1 cyclin even while retaining T169E. The strong T169E suppressors did not exhibit bypass of the G1 cyclin requirement but did so when T169E was reverted to T. These results suggested that for these mutants, activation loop phosphorylation and cyclin binding might be alternative means of activation rather than independent requirements for activation (as with wild type). These results suggest mechanistic overlap between the conformational shift induced by cyclin binding and that induced by activation loop phosphorylation. This conclusion was supported by analysis of suppressors of a mutation in the Cdk phosphothreonine-binding pocket created by cyclin binding.

Distinct subcellular localization patterns contribute to functional specificity of the Cln2 and Cln3 cyclins of Saccharomyces cerevisiae

The G(1) cyclins of budding yeast drive cell cycle initiation by different mechanisms, but the molecular basis of their specificity is unknown. Here we test the hypothesis that the functional specificity of G(1) cyclins is due to differential subcellular localization. As shown by indirect immunofluorescence and biochemical fractionation, Cln3p localization appears to be primarily nuclear, with the most obvious accumulation of Cln3p to the nuclei of large budded cells. In contrast, Cln2p localizes to the cytoplasm. We were able to shift localization patterns of truncated Cln3p by the addition of nuclear localization and nuclear export signals, and we found that nuclear localization drives a Cln3p-like functional profile, while cytoplasmic localization leads to a partial shift to a Cln2p-like functional profile. Therefore, forcing Cln3p into a Cln2p-like cytoplasmic localization pattern partially alters the functional specificity of Cln3p toward that of Cln2p. These results suggest that there are CLN-dependent cytoplasmic and nuclear events important for cell cycle initiation. This is the first indication of a cytoplasmic function for a cyclin-dependent kinase. The data presented here support the idea that cyclin function is regulated at the level of subcellular localization and that subcellular localization contributes to the functional specificity of Cln2p and Cln3p.

The Pho85 kinase, a member of the yeast cyclin-dependent kinase (Cdk) family, has a regulation mechanism different from Cdks functioning throughout the cell cycle

BACKGROUND

The PHO85 gene is a negative regulator of the PHO system in the yeast Saccharomyces cerevisiae and encodes a protein kinase (Pho85p) which is highly homologous to the Cdc28 kinase (Cdc28p). Although the two kinases share a 51% identity and their functional domains are well conserved, PHO85 fails to replace CDC28. Pho85p forms complexes with G1-cyclin homologues, including Pcl1p, Pcl2p and Pcl9p, and is thought to be involved in the cell-cycle regulation at G1 and the end of M. By analysing the genetic and biochemical properties of Pho85p, we studied whether the regulation of Pho85p activity is similar to other cyclin-dependent kinases (Cdks) directly involved in cell cycle regulation.

RESULTS

A functional analysis of various Pho85 mutants revealed that E53 in the PSTAIRE sequence was important for Pho85p function. On the other hand, residues in the T-loop including S166, S167 and E168, appeared dispensable for Pho85p function, suggesting that the phosphorylation of S166, corresponding to T161 of Cdc2p and T169 of Cdc28p, was not required for the kinase activity of Pho85p. Instead, we found that phosphorylation of Y18, corresponding to Y15 of Cdc2p and Y19 of Cdc28p, may be important for the binding of Pho80p but not of Pcl1p, suggesting that tyrosine phosphorylation may function as a signal which discriminates various Pho85-cyclins.

CONCLUSION

In Cdks functioning throughout the cell cycle, tyrosine phosphorylation is inhibitory to the activation of kinase, whereas the phosphorylation of threonine in the T-loop is essential for activation. Our finding indicates that the regulation mechanism of Pho85p activation appears to be distinct from these Cdks.

Directed evolution to bypass cyclin requirements for the Cdc28p cyclin-dependent kinase

To identify cyclin-dependent kinase mutants with relaxed cyclin requirements, CDC28 alleles were selected that could rescue a yeast strain expressing as its only CLN G1 cyclin a mutant Cln2p (K129A,E183A) that is defective for Cdc28p binding. Rescue of this strain by mutant CDC28 was dependent upon the mutant cln2-KAEA, but additional mutagenesis and DNA shuffling yielded multiply mutant CDC28-BYC alleles (bypass of CLNs) that could support highly efficient cell cycle initiation in the complete absence of CLN genes. By gel filtration chromatography, one of the mutant Cdc28 proteins exhibited kinase activity associated with cyclin-free monomer. Thus, the mutants' CLN bypass activity might result from constitutive, cyclin-independent activity, suggesting that Cdk targeting by cyclins is not required for cell cycle initiation.

Regulation of Cdc28 cyclin-dependent protein kinase activity during the cell cycle of the yeast Saccharomyces cerevisiae

The cyclin-dependent protein kinase (CDK) encoded by CDC28 is the master regulator of cell division in the budding yeast Saccharomyces cerevisiae. By mechanisms that, for the most part, remain to be delineated, Cdc28 activity controls the timing of mitotic commitment, bud initiation, DNA replication, spindle formation, and chromosome separation. Environmental stimuli and progress through the cell cycle are monitored through checkpoint mechanisms that influence Cdc28 activity at key cell cycle stages. A vast body of information concerning how Cdc28 activity is timed and coordinated with various mitotic events has accrued. This article reviews that literature. Following an introduction to the properties of CDKs common to many eukaryotic species, the key influences on Cdc28 activity-cyclin-CKI binding and phosphorylation-dephosphorylation events-are examined. The processes controlling the abundance and activity of key Cdc28 regulators, especially transcriptional and proteolytic mechanisms, are then discussed in detail. Finally, the mechanisms by which environmental stimuli influence Cdc28 activity are summarized.

Molecular evolution allows bypass of the requirement for activation loop phosphorylation of the Cdc28 cyclin-dependent kinase

Many protein kinases are regulated by phosphorylation in the activation loop, which is required for enzymatic activity. Glutamic acid can substitute for phosphothreonine in some proteins activated by phosphorylation, but this substitution (T169E) at the site of activation loop phosphorylation in the Saccharomyces cerevisiae cyclin-dependent kinase (Cdk) Cdc28p blocks biological function and protein kinase activity. Using cycles of error-prone DNA amplification followed by selection for successively higher levels of function, we identified mutant versions of Cdc28p-T169E with high biological activity. The enzymatic and biological activity of the mutant Cdc28p was essentially normally regulated by cyclin, and the mutants supported normal cell cycle progression and regulation. Therefore, it is not a requirement for control of the yeast cell cycle that Cdc28p be cyclically phosphorylated and dephosphorylated. These CDC28 mutants allow viability in the absence of Cak1p, the essential kinase that phosphorylates Cdc28p-T169, demonstrating that T169 phosphorylation is the only essential function of Cak1p. Some growth defects remain in suppressed cak1 cdc28 strains carrying the mutant CDC28 genes, consistent with additional nonessential roles for CAK1.