Proviral inactivation of the Npat gene of Mpv 20 mice results in early embryonic arrest

Histone deficiency and hypoacetylation in the aging retinal pigment epithelium

Histones serve as a major carrier of epigenetic information in the form of post-translational modifications which are vital for controlling gene expression, maintaining cell identity, and ensuring proper cellular function. Loss of histones in the aging genome can drastically impact the epigenetic landscape of the cell leading to altered chromatin structure and changes in gene expression profiles. In this study, we investigated the impact of age-related changes on histone levels and histone acetylation in the retinal pigment epithelium (RPE) and retina of mice. We observed a global reduction of histones H1, H2A, H2B, H3, and H4 in aged RPE/choroid but not in the neural retina. Transcriptomic analyses revealed significant downregulation of histones in aged RPE/choroid including crucial elements of the histone locus body (HLB) complex involved in histone pre-mRNA processing. Knockdown of HINFP, a key HLB component, in human RPE cells induced histone loss, senescence, and the upregulation of senescence-associated secretory phenotype (SASP) markers. Replicative senescence and chronological aging in human RPE cells similarly resulted in progressive histone loss and acquisition of the SASP. Immunostaining of human retina sections revealed histone loss in RPE with age. Acetyl-histone profiling in aged mouse RPE/choroid revealed a specific molecular signature with loss of global acetyl-histone levels, including H3K14ac, H3K56ac, and H4K16ac marks. These findings strongly demonstrate histone loss as a unique feature of RPE aging and provide critical insights into the potential mechanisms linking histone dynamics, cellular senescence, and aging.

Spatiotemporal Epigenetic Control of the Histone Gene Chromatin Landscape during the Cell Cycle

Higher-order genomic organization supports the activation of histone genes in response to cell cycle regulatory cues that epigenetically mediates stringent control of transcription at the G1/S-phase transition. Histone locus bodies (HLBs) are dynamic, non-membranous, phase-separated nuclear domains where the regulatory machinery for histone gene expression is organized and assembled to support spatiotemporal epigenetic control of histone genes. HLBs provide molecular hubs that support synthesis and processing of DNA replication-dependent histone mRNAs. These regulatory microenvironments support long-range genomic interactions among non-contiguous histone genes within a single topologically associating domain (TAD). HLBs respond to activation of the cyclin E/CDK2/NPAT/HINFP pathway at the G1/S transition. HINFP and its coactivator NPAT form a complex within HLBs that controls histone mRNA transcription to support histone protein synthesis and packaging of newly replicated DNA. Loss of HINFP compromises H4 gene expression and chromatin formation, which may result in DNA damage and impede cell cycle progression. HLBs provide a paradigm for higher-order genomic organization of a subnuclear domain that executes an obligatory cell cycle-controlled function in response to cyclin E/CDK2 signaling. Understanding the coordinately and spatiotemporally organized regulatory programs in focally defined nuclear domains provides insight into molecular infrastructure for responsiveness to cell signaling pathways that mediate biological control of growth, differentiation phenotype, and are compromised in cancer.

RNA polymerase II condensate formation and association with Cajal and histone locus bodies in living human cells

In eukaryotic nuclei, a number of phase‐separated nuclear bodies (NBs) are present. RNA polymerase II (Pol II) is the main player in transcription and forms large condensates in addition to localizing at numerous transcription foci. Cajal bodies (CBs) and histone locus bodies (HLBs) are NBs that are involved in transcriptional and post‐transcriptional regulation of small nuclear RNA and histone genes. By live‐cell imaging using human HCT116 cells, we here show that Pol II condensates (PCs) nucleated near CBs and HLBs, and the number of PCs increased during S phase concomitantly with the activation period of histone genes. Ternary PC–CB–HLB associates were formed via three pathways: nucleation of PCs and HLBs near CBs, interaction between preformed PC–HLBs with CBs and nucleation of PCs near preformed CB–HLBs. Coilin knockout increased the co‐localization rate between PCs and HLBs, whereas the number, nucleation timing and phosphorylation status of PCs remained unchanged. Depletion of PCs did not affect CBs and HLBs. Treatment with 1,6‐hexanediol revealed that PCs were more liquid‐like than CBs and HLBs. Thus, PCs are dynamic structures often nucleated following the activation of gene clusters associated with other NBs.

Higher order genomic organization and regulatory compartmentalization for cell cycle control at the G1/S-phase transition

Fidelity of histone gene regulation, and ultimately of histone protein biosynthesis, is obligatory for packaging of newly replicated DNA into chromatin. Control of histone gene expression within the 3-dimensional context of nuclear organization is reflected by two well documented observations. DNA replication-dependent histone mRNAs are synthesized at specialized subnuclear domains designated histone locus bodies (HLBs), in response to activation of the growth factor dependent Cyclin E/CDK2/HINFP/NPAT pathway at the G1/S transition in mammalian cells. Complete loss of the histone gene regulatory factors HINFP or NPAT disrupts HLB integrity that is necessary for coordinate control of DNA replication and histone gene transcription. Here we review the molecular histone-related requirements for G1/S-phase progression during the cell cycle. Recently developed experimental strategies, now enable us to explore mechanisms involved in dynamic control of histone gene expression in the context of the temporal (cell cycle) and spatial (HLBs) remodeling of the histone gene loci.

Coordinating cell cycle-regulated histone gene expression through assembly and function of the Histone Locus Body

Metazoan replication-dependent (RD) histone genes encode the only known cellular mRNAs that are not polyadenylated. These mRNAs end instead in a conserved stem-loop, which is formed by an endonucleolytic cleavage of the pre-mRNA. The genes for all 5 histone proteins are clustered in all metazoans and coordinately regulated with high levels of expression during S phase. Production of histone mRNAs occurs in a nuclear body called the Histone Locus Body (HLB), a subdomain of the nucleus defined by a concentration of factors necessary for histone gene transcription and pre-mRNA processing. These factors include the scaffolding protein NPAT, essential for histone gene transcription, and FLASH and U7 snRNP, both essential for histone pre-mRNA processing. Histone gene expression is activated by Cyclin E/Cdk2-mediated phosphorylation of NPAT at the G1-S transition. The concentration of factors within the HLB couples transcription with pre-mRNA processing, enhancing the efficiency of histone mRNA biosynthesis.

Maternal expression and early induction of histone gene transcription factor Hinfp sustains development in pre-implantation embryos

Fidelity of histone gene expression is important for normal cell growth and differentiation that is stringently controlled during development but is compromised during tumorigenesis. Efficient production of histones for packaging newly replicated DNA is particularly important for proper cell division and epigenetic control during the initial pre-implantation stages of embryonic development. Here, we addressed the unresolved question of when the machinery for histone gene transcription is activated in the developing zygote to accommodate temporal demands for histone gene expression. We examined induction of Histone Nuclear Factor P (HINFP), the only known transcription factor required for histone H4 gene expression, that binds directly to a unique H4 promoter-specific element to regulate histone H4 transcription. We show that Hinfp gene transcripts are stored in oocytes and maternally transmitted to the zygote. Transcripts from the paternal Hinfp gene, which reflect induction of zygotic gene expression, are apparent at the 4- to 8-cell stage, when most maternal mRNA pools are depleted. Loss of Hinfp expression due to gene ablation reduces cell numbers in E3.5 stage embryos and compromises implantation. Reduced cell proliferation is attributable to severe reduction in histone mRNA levels accompanied by reduced cell survival and genomic damage as measured by cleaved Caspase 3 and phospho-H2AX staining, respectively. We conclude that transmission of maternal Hinfp transcripts and zygotic activation of the Hinfp gene together are necessary to control H4 gene expression in early pre-implantation embryos in order to support normal embryonic development.

The role of nuclear bodies in gene expression and disease

This review summarizes the current understanding of the role of nuclear bodies in regulating gene expression. The compartmentalization of cellular processes, such as ribosome biogenesis, RNA processing, cellular response to stress, transcription, modification and assembly of spliceosomal snRNPs, histone gene synthesis and nuclear RNA retention, has significant implications for gene regulation. These functional nuclear domains include the nucleolus, nuclear speckle, nuclear stress body, transcription factory, Cajal body, Gemini of Cajal body, histone locus body and paraspeckle. We herein review the roles of nuclear bodies in regulating gene expression and their relation to human health and disease.

FLASH is essential during early embryogenesis and cooperates with p73 to regulate histone gene transcription

Replication-dependent histone gene expression is a fundamental process occurring in S-phase under the control of the cyclin-E/CDK2 complex. This process is regulated by a number of proteins, including Flice-Associated Huge Protein (FLASH) (CASP8AP2), concentrated in specific nuclear organelles known as HLBs. FLASH regulates both histone gene transcription and mRNA maturation, and its downregulation in vitro results in the depletion of the histone pull and cell-cycle arrest in S-phase. Here we show that the transcription factor p73 binds to FLASH and is part of the complex that regulates histone gene transcription. Moreover, we created a novel gene trap to disrupt FLASH in mice, and we show that homozygous deletion of FLASH results in early embryonic lethality, owing to arrest of FLASH(-/-) embryos at the morula stage. These results indicate that FLASH is an essential, non-redundant regulator of histone transcription and cell cycle during embryogenesis.

Functional coupling of transcription factor HiNF-P and histone H4 gene expression during pre- and post-natal mouse development

Transcription factor Histone Nuclear Factor P (HiNF-P; gene symbol Hinfp) mediates cell cycle control of histone H4 gene expression to support the packaging of newly replicated DNA as chromatin. The HiNF-P/p220(NPAT) complex controls multiple H4 genes in established human cell lines and is critical for cell proliferation. The mouse Hinfp(LacZ) null allele causes early embryonic lethality due to a blastocyst defect. However, neither Hinfp function nor its temporal expression relative to histone H4 genes during fetal development has been explored. Here, we establish that expression of Hinfp is biologically coupled with expression of twelve functional mouse H4 genes during pre- and post-natal tissue-development. Both Hinfp and H4 genes are robustly expressed at multiple embryonic (E) days (from E5.5 to E15.5), coincident with ubiquitous LacZ staining driven by the Hinfp promoter. Five highly expressed mouse H4 genes (Hist1h4d, Histh4f, Hist1h4m and Hist2h4) account for >90% of total histone H4 mRNA throughout development. Post-natal expression of H4 genes in mice is most evident in lung, spleen, thymus and intestine, and with few exceptions (e.g., adult liver) correlates with Hinfp gene expression. Histone H4 gene expression decreases butHinfp levels remain constitutive upon cell growth inhibition in culture. The in vivo co-expression of Hinfp and histone H4 genes is consistent with the biological function of Hinfp as a principal transcriptional regulator of histone H4 gene expression during mouse development.

The histone gene activator HINFP is a nonredundant cyclin E/CDK2 effector during early embryonic cell cycles

Competency for DNA replication is functionally coupled to the activation of histone gene expression at the onset of S phase to form chromatin. Human histone nuclear factor P (HiNF-P; gene symbol HINFP) bound to its cyclin E/cyclin-dependent kinase 2 (CDK2) responsive coactivator p220(NPAT) is a key regulator of multiple human histone H4 genes that encode a major subunit of the nucleosome. Induction of the histone H4 transcription factor (HINFP)/p220(NPAT) coactivation complex occurs in parallel with the CDK-dependent release of pRB from E2F at the restriction point. Here, we show that the downstream CDK-dependent cell cycle effector HINFP is genetically required and, in contrast to the CDK2/cyclin E complex, cannot be compensated. We constructed a mouse Hinfp-null mutation and found that heterozygous Hinfp mice survive, indicating that 1 allele suffices for embryogenesis. Homozygous loss-of-function causes embryonic lethality: No homozygous Hinfp-null mice are obtained at or beyond embryonic day (E) 6.5. In blastocyst cultures, Hinfp-null embryos exhibit a delay in hatching, abnormal growth, and loss of histone H4 gene expression. Our data indicate that the CDK2/cyclin E/p220(NPAT)/HINFP/histone gene signaling pathway at the G1/S phase transition is an essential, nonredundant cell cycle regulatory mechanism that is established early in embryogenesis.

Transcriptional activation of the histone nuclear factor P (HiNF-P) gene by HiNF-P and its cyclin E/CDK2 responsive co-factor p220NPAT defines a novel autoregulatory loop at the G1/S phase transition

Histone nuclear factor P (HiNF-P) activates histone H4 gene transcription at the G1/S phase transition upon association with its cyclin E/CDK2 responsive co-factor p220NPAT. Here we characterize the gene regulatory pathways that control the proliferation-related expression of HiNF-P. The HiNF-P locus contains a single TATA-less 0.6 kbp promoter with multiple phylogenetically conserved transcription factor recognition motifs. Transient reporter gene assays with HiNF-P promoter deletions show that there are at least three distinct activating regions (-387/-201, -201/-100 and -100/-1) that support maximal transcription. HiNF-P gene transcription is activated by SP1 through the -100/-1 domain and repressed by E2F1 through the -201/-100 domain. The multifunctional co-regulators CBP and p300 also stimulate HiNF-P gene transcription through the -201/-1 core promoter. Importantly, the HiNF-P promoter is activated by both HiNF-P and p220NPAT. This autoregulatory activation is further enhanced by cyclin E and CDK2, while blocked by CDK inhibition (i.e., p57KIP2 p27KIP1, p21CIP). Thus, the HiNF-P gene is a key non-histone target of p220NPAT and HiNF-P. The dependence of HiNF-P gene transcription on cyclin E/CDK2/p220NPAT signaling defines a novel feed-forward loop that may sustain HiNF-P expression in proliferating cells to support the cell cycle regulated synthesis of histone H4 proteins.

HiNF-P is a bifunctional regulator of cell cycle controlled histone H4 gene transcription

Cell cycle progression beyond the G1/S phase transition requires the activation of a transcription complex containing histone nuclear factor P (HiNF-P) and nuclear protein mapped to ataxia telangiectasia (p220(NPAT)) in response to cyclin dependent kinase 2 (CDK2)/cyclin E signaling. We show here that the potent co-activating properties of HiNF-P/p220(NPAT) on the histone H4 gene promoter, which are evident in the majority of human cell types, are sporadically neutralized in distinct somatic cell lines. In cells where HiNF-P and p220(NPAT) do not activate the H4 gene promoter, HiNF-P instead represses transcription. Our data suggest that the cell type specific expression of the cyclin-dependent kinase inhibitory (CKI) protein p57(KIP2) inhibits the HiNF-P dependent activation of the histone H4 promoter. We propose that, analogous to E2F proteins and other cell cycle regulatory proteins, HiNF-P is a bifunctional transcriptional regulator that can activate or repress cell cycle controlled genes depending on the cellular context.

An architectural perspective of cell-cycle control at the G1/S phase cell-cycle transition

A prominent role for the execution of cell cycle and growth regulatory mechanisms within the three-dimensional context of nuclear architecture is becoming increasingly evident. Signaling pathways and regulatory networks that govern activation and suppression of genes controlling proliferation are functionally integrated for the organization and assembly of transcriptional machinery in nuclear microenvironments. The transcriptional activation of histone genes at the G1/S phase transition (S-point) is temporarily, functionally, and spatially distinct from transcriptional mechanisms at the restriction point (R-point). The spatial distinction in R-point versus S-point control is the localization of clustered histone gene loci at cajal bodies, which is modulated during the cell cycle. Histone nuclear factor P (HiNF-P), the principal factor mediating H4 histone gene transcription, is the final link in the signaling cascade that is initiated with growth factor dependent induction of cyclin E/CDK2 kinase activity at the R-point and culminates in the NPAT-mediated activation of histone H4 genes through HiNF-P at the G1/S phase cell-cycle transition.

Deficiency of the zinc finger protein ZPR1 causes defects in transcription and cell cycle progression

The zinc finger protein ZPR1 is present in both the cytoplasm and nucleoplasm. Cell cycle analysis demonstrates that ZPR1 undergoes major changes in subcellular distribution during proliferation. ZPR1 is diffusely localized throughout the cell during the G(1) and G(2)/M phases of the cell cycle. In contrast, ZPR1 redistributes to the nucleus during S phase and ZPR1 exhibits prominent co-localization with the survival motor neurons protein and the histone gene-specific transcription factor NPAT in subnuclear foci, including Cajal bodies that associate with histone gene clusters. ZPR1 deficiency causes disruption of survival motor neurons and NPAT localization within the nucleus, blocks S phase progression, and arrests cells in both the G(1) and G(2) phases of the cell cycle. These changes in subnuclear architecture and cell cycle progression may be caused by transcriptional defects in ZPR1-deficient cells, including decreased histone gene expression.

Dynamic interaction of p220(NPAT) and CBP/p300 promotes S-phase entry

Cajal bodies contain cyclin E/cdk2 and the substrate p220(NPAT) to regulate the transcription of histones, which is essential for cell proliferation, however, recent mouse knockout studies indicate that cyclin E and cdk2 are dispensable for these events. Because the CBP/p300 histone acetyltransferase are also known to be involved in cell proliferation, we examined the molecular and functional interactions of p220(NPAT) with the CBP/p300 at the G1/S boundary as cell cycle regulators. The subnuclear localization of p220(NPAT) and CBP/p300 proteins showed that their foci partially overlapped in a cell cycle dependent manner. Overexpression of p220(NPAT) and CBP/p300 cooperatively enhanced G1/S transition and DNA synthesis even without cdk2 phosphorylation site. Finally, molecular alignment analysis indicated that p220(NPAT) contains several potential substrate sites for CBP/p300. Overall, our findings demonstrate that p220(NPAT) and CBP/p300 form a transient complex at the G1/S boundary to play cooperative roles to promote the S-phase entry.

Identification of HiNF-P, a key activator of cell cycle-controlled histone H4 genes at the onset of S phase

At the G(1)/S phase cell cycle transition, multiple histone genes are expressed to ensure that newly synthesized DNA is immediately packaged as chromatin. Here we have purified and functionally characterized the critical transcription factor HiNF-P, which is required for E2F-independent activation of the histone H4 multigene family. Using chromatin immunoprecipitation analysis and ligation-mediated PCR-assisted genomic sequencing, we show that HiNF-P interacts with conserved H4 cell cycle regulatory sequences in vivo. Antisense inhibition of HiNF-P reduces endogenous histone H4 gene expression. Furthermore, we find that HiNF-P utilizes NPAT/p220, a substrate of the cyclin E/cyclin-dependent kinase 2 (CDK2) kinase complex, as a key coactivator to enhance histone H4 gene transcription. The biological role of HiNF-P is reflected by impeded cell cycle progression into S phase upon antisense-mediated reduction of HiNF-P levels. Our results establish that HiNF-P is the ultimate link in a linear signaling pathway that is initiated with the growth factor-dependent induction of cyclin E/CDK2 kinase activity at the restriction point and culminates in the activation of histone H4 genes through HiNF-P at the G(1)/S phase transition.

The cyclin E/Cdk2 substrate p220(NPAT) is required for S-phase entry, histone gene expression, and Cajal body maintenance in human somatic cells

Cyclin E/Cdk2, a central regulator of the G1/S transition, coordinates multiple cell cycle events, including DNA replication, centrosome duplication, and activation of the E2F transcriptional program. Recent studies suggest a role for cyclin E/Cdk2 in activation of histone transcription during S phase via the Cajal body-associated protein p220NPAT, and in addition, p220 can promote S-phase entry independently of histone transcriptional activation when overexpressed. Here we have examined the requirement for p220 in histone transcription, cell cycle progression, and Cajal body function through analysis of human somatic HCT116 cells engineered to contain a conditional p220 allele. p220 is required for proliferation of HCT116 cells, as assessed after expression of Cre recombinase in p220(flox/-) cells. This defect was due to an inability of these cells to transit from G0/G1 into S phase, and cell cycle arrest occurred in the presence of elevated Cdk2 kinase activity. Expression of human papillomavirus E7, but not E6, eliminated cell cycle arrest in response to p220 depletion. Optimal expression of all four core histone genes required p220, as did optimal transcription of a histone H4 promoter-luciferase construct. Basal histone H4 expression in G0/G1, although p220 dependent, occurs in the absence of detectable phosphorylation of p220 on Cdk2 sites. Cells lacking p220 displayed defects in the localization of the Cajal body component p80coilin as cells progressed from G0 to S phase in response to mitogenic signals. These finding indicate that p220 is an essential downstream component of the cyclin E/Cdk2 signaling pathway and functions to coordinate multiple elements of the G1/S transition.

NPAT expression is regulated by E2F and is essential for cell cycle progression

NPAT is an in vivo substrate of cyclin E-Cdk2 kinase and is thought to play a critical role in coordinated transcriptional activation of histone genes during the G(1)/S-phase transition and in S-phase entry in mammalian cells. Here we show that NPAT transcription is up-regulated at the G(1)/S-phase boundary in growth-stimulated cells and that the NPAT promoter responds to activation by E2F proteins. We demonstrate that endogenous E2F proteins interact with the promoter of the NPAT gene in vivo and that induced expression of E2F1 stimulates NPAT mRNA expression, supporting the idea that the expression of NPAT is regulated by E2F. Consistently, we find that the E2F sites in the NPAT promoter are required for its activation during the G(1)/S-phase transition. Moreover, we show that the expression of NPAT accelerates S-phase entry in cells released from quiescence. The inhibition of NPAT expression by small interfering RNA duplexes impedes cell cycle progression and histone gene expression in tissue culture cells. Thus, NPAT is an important E2F target that is required for cell cycle progression in mammalian cells. As NPAT is involved in the regulation of S-phase-specific histone gene transcription, our findings indicate that NPAT links E2F to the activation of S-phase-specific histone gene transcription.

Cell cycle-regulated phosphorylation of p220(NPAT) by cyclin E/Cdk2 in Cajal bodies promotes histone gene transcription

Cyclin E/Cdk2 acts at the G1/S-phase transition to promote the E2F transcriptional program and the initiation of DNA synthesis. To explore further how cyclin E/Cdk2 controls S-phase events, we examined the subcellular localization of the cyclin E/Cdk2 interacting protein p220(NPAT) and its regulation by phosphorylation. p220 is localized to discrete nuclear foci. Diploid fibroblasts in Go and G1 contain two p220 foci, whereas S- and G2-phase cells contain primarily four p220 foci. Cells in metaphase and telophase have no detectable focus. p220 foci contain cyclin E and are coincident with Cajal bodies (CBs), subnuclear organelles that associate with histone gene clusters on chromosomes 1 and 6. Interestingly, p220 foci associate with chromosome 6 throughout the cell cycle and with chromosome 1 during S phase. Five cyclin E/Cdk2 phosphorylation sites in p220 were identified. Phospho-specific antibodies against two of these sites react with p220 within CBs in a cell cycle-specific manner. The timing of p220 phosphorylation correlates with the appearance of cyclin E in CBs at the G1/S boundary, and this phosphorylation is maintained until prophase. Expression of p220 activates transcription of the histone H2B promoter. Importantly, mutation of Cdk2 phosphorylation sites to alanine abrogates the ability of p220 to activate the histone H2B promoter. Collectively, these results strongly suggest that p220(NPAT) links cyclical cyclin E/Cdk2 kinase activity to replication-dependent histone gene transcription.

NPAT links cyclin E-Cdk2 to the regulation of replication-dependent histone gene transcription

In eukaryotic cells, histone gene expression is one of the major events that mark entry into S phase. While this process is tightly linked to cell cycle position, how it is regulated by the cell cycle machinery is not known. Here we show that NPAT, a substrate of the cyclin E-Cdk2 complex, is associated with human replication-dependent histone gene clusters on both chromosomes 1 and 6 in S phase. We demonstrate that NPAT activates histone gene transcription and that this activation is dependent on the promoter elements (SSCSs) previously proposed to mediate cell cycle-dependent transcription. Cyclin E is also associated with the histone gene loci, and cyclin E-Cdk2 stimulates the NPAT-mediated activation of histone gene transcription. Thus, our results both show that NPAT is involved in a key S phase event and provide a link between the cell cycle machinery and activation of histone gene transcription.

Transfection of mouse eggs and embryos using DNA combined to cationic liposomes

We have used plasmid DNA in combination with cationic liposomes to transfect mouse eggs and embryos. The plasmid was rhodamine labeled, which allowed a direct visualization of the DNA uptake by the cells. Immature eggs, collected from the ovaries, were easily transfected, but once the egg was ovulated the zona pellucida (ZP) acted as a barrier and prevented transfection. Permeabilization or removal of the ZP was therefore a requirement to allow transfection. Transfected eggs were capable of being fertilized in vitro giving raise to embryos that expressed the recombinant protein. Morulae and blastocysts were also transfected when the ZP was permeabilized, but the efficiency of transfection decreased and in some cases not all the blastomeres incorporated the plasmid. Pronuclear embryos were cultured and showed expression of the transgene from the 2-cell stage. This indicates that liposome-transfection of oocytes or pronuclear embryos could be a simple and suitable method to introduce foreign genes in embryos and perhaps could be also useful to generate transgenic animals.

Expression of NPAT, a novel substrate of cyclin E-CDK2, promotes S-phase entry

To understand the mechanisms by which CDKs regulate cell cycle progression, it is necessary to identify and characterize the physiological substrates of these kinases. We have developed a screening method to identify novel CDK substrates. One of the cDNAs identified in the screen is identical to the recently isolated NPAT gene. Here we show that NPAT associates with cyclin E-CDK2 in vivo and can be phosphorylated by this CDK. The protein level of NPAT peaks at the G1/S boundary. Overexpression of NPAT accelerates S-phase entry, and this effect is enhanced by coexpression of cyclin E-CDK2. These results suggest that NPAT is a substrate of cyclin E-CDK2 and plays a role in S-phase entry.