Implications of CLSPN Variants in Cellular Function and Susceptibility to Cancer.

Claspin is a multifunctional protein that participates in physiological processes essential for cell homeostasis that are often defective in cancer, namely due to genetic changes. It is conceivable that Claspin gene (CLSPN) alterations may contribute to cancer development. Therefore, CLSPN germline alterations were characterized in sporadic and familial breast cancer and glioma samples, as well as in six cancer cell lines. Their association to cancer susceptibility and functional impact were investigated. Eight variants were identified (c.-68C>T, c.17G>A, c.1574A>G, c.2230T>C, c.2028+16G>A, c.3595-3597del, and c.3839C>T). CLSPN c.1574A>G (p.Asn525Ser) was significantly associated with breast cancer and was shown to cause partial exon skipping and decreased Claspin expression and Chk1 activation in a minigene splicing assay and in signalling experiments, respectively. CLSPN c.2028+16G>A was significantly associated with familial breast cancer and glioma, whereas c.2230T>C (p.Ser744Pro), was exclusively detected in breast cancer and glioma patients, but not in healthy controls. The remaining variants lacked a significant association with cancer. Nevertheless, the c.-68C>T promoter variant increased transcriptional activity in a luciferase assay. In conclusion, some of the CLSPN variants identified in the present study appear to modulate Claspin's function by altering CLSPN transcription and RNA processing, as well as Chk1 activation.

USP7 controls Chk1 protein stability by direct deubiquitination.

Chk1, an essential checkpoint kinase in the DNA damage response pathway (DDR), is tightly regulated by both ATR-dependent phosphorylation and proteasome-mediated degradation. Here we identify ubiquitin hydrolase USP7 as a novel regulator of Chk1 protein stability. USP7 was shown before to regulate other DDR proteins such as p53, Hdm2 and Claspin, an adaptor protein in the ATR-Chk1 pathway required for Chk1 activation. Depletion or inhibition of USP7 leads to lower Chk1 levels. The decreased Chk1 protein after USP7 knock down cannot be rescued by simultaneously elevating Claspin levels, demonstrating that the effect of USP7 on Chk1 is independent of its known effect on Claspin. Conversely, overexpression of USP7 wild type, but not a catalytic mutant version, elevates Chk1 levels and increases the half-life of Chk1 protein. Importantly, wild type, but not catalytic mutant USP7 can deubiquitinate Chk1 in vivo and in vitro, confirming that USP7 directly regulates Chk1 protein levels. Finally we show that USP7 catalytic mutant is (mono-)ubiquitinated, which suggests auto-deubiquitination by this ubiquitin hydrolase, possibly important for its regulation.

Dub3 controls DNA damage signalling by direct deubiquitination of H2AX.

A crucial event in the DNA damage response is the phosphorylation and subsequent ubiquitination of H2AX, required for the recruitment of proteins involved in DNA repair. Here we identify a novel regulator of this process, the ubiquitin hydrolase Dub3. Overexpression of wild type, but not catalytic inactive, Dub3 decreases the DNA damage-induced mono-ubiquitination of H2A(X) whereas downregulation of Dub3 has the opposite effect. Dub3 overexpression abrogates focus formation of 53BP1 and BRCA1 in response to genotoxic stress. However, focus formation of MDC1 and γH2AX, earlier events in this response, are unaffected by Dub3 overexpression. We show that Dub3 counteracts H2AX E3 ligases RNF8 and RNF168. Moreover, Dub3 and H2AX interact and Dub3 deubiquitinates H2AX in vitro. Importantly, overexpression of Dub3 delays H2AX dephosphorylation and recovery of MDC1 focus formation at later time points after DNA damage, whereas H2AX dephosphorylation at later time points is faster after Dub3 depletion. Altogether these results show that Dub3 regulates a correct DNA damage response by controlling H2AX ubiquitination.

K(+) uptake systems in the yeast Hansenula polymorpha. Transcriptional and post-translational mechanisms involved in high-affinity K(+) transporter regulation.

We have identified the two main K(+) transporters in the yeast Hansenula polymorpha. So far this is the only yeast with these transporters amenable to molecular genetic analysis. Two ORF-encoding permeases with high similarity to Trk1 and Hak1 are present in the genome of this yeast. Deletion of either of these genes led to defective growth in low K(+). The K(+) and Rb(+) uptake rates showed high affinity of Hak1 for K(+), while the affinity estimated for Trk1 was two orders of magnitude lower. TRK1 was not transcriptionally regulated and HAK1 was strongly induced in response to very low K(+) and down-regulated by the presence of K(+). This process is clearly dependent on calcineurin. The use of a set of strains carrying mutations affecting intracellular protein trafficking revealed that in response to K(+), Hak1 is endocytosed and degraded in the vacuole, this depending on the ubiquitin ligase Rsp5. This is a first insight into the transcriptional and post-translational mechanisms regulating a high-affinity K(+) transporter (HAK-type transporter) that allows cells to respond and adapt to K(+) availability.

Novel insights into maintaining genomic integrity: Wee1 regulating Mus81/Eme1.

Maintenance of genomic integrity is essential for cell survival. Specifically, during DNA replication cells use a complex network of mechanisms that prevents genomic instability. Recently, we and others identified Wee1, a serine/threonine and tyrosine kinase, as a new modulator of the genomic stability during S phase. Loss of its activity causes a general DNA damage response activation and a decrease in replication fork speed. These effects are counteracted by the downregulation of the endonuclease complex Mus81-Eme1, showing a new link between this endonuclease and Wee1 during DNA replication. Here we discuss the function of Wee1 in genomic stability and its relationship with the Mus81-Eme1 complex.

Wee1 controls genomic stability during replication by regulating the Mus81-Eme1 endonuclease.

Correct replication of the genome and protection of its integrity are essential for cell survival. In a high-throughput screen studying H2AX phosphorylation, we identified Wee1 as a regulator of genomic stability. Wee1 down-regulation not only induced H2AX phosphorylation but also triggered a general deoxyribonucleic acid (DNA) damage response (DDR) and caused a block in DNA replication, resulting in accumulation of cells in S phase. Wee1-deficient cells showed a decrease in replication fork speed, demonstrating the involvement of Wee1 in DNA replication. Inhibiting Wee1 in cells treated with short treatment of hydroxyurea enhanced the DDR, which suggests that Wee1 specifically protects the stability of stalled replication forks. Notably, the DDR induced by depletion of Wee1 critically depends on the Mus81-Eme1 endonuclease, and we found that codepletion of Mus81 and Wee1 abrogated the S phase delay. Importantly, Wee1 and Mus81 interact in vivo, suggesting direct regulation. Altogether, these results demonstrate a novel role of Wee1 in controlling Mus81 and DNA replication in human cells.

Npr1 Ser/Thr protein kinase links nitrogen source quality and carbon availability with the yeast nitrate transporter (Ynt1) levels.

Ynt1, the single high affinity nitrate and nitrite transporter of the yeast Hansenula polymorpha, is regulated by the quality of nitrogen sources. Preferred nitrogen sources cause Ynt1 dephosphorylation, ubiquitinylation, endocytosis, and vacuolar degradation. In contrast, under nitrogen limitation Ynt1 is phosphorylated and sorted to the plasma membrane. We show here the involvement of the Ser/Thr kinase HpNpr1 in Ynt1 phosphorylation and regulation of Ynt1 levels in response to nitrogen source quality and the availability of carbon. In Δnpr1, Ynt1 phosphorylation does not take place, although Ynt1 ubiquitin conjugates increase. As a result, in this strain Ynt1 is sorted to the vacuole, from both plasma membrane and the later biosynthetic pathway in nitrogen-free conditions and nitrate. In contrast, overexpression of NPR1 blocks down-regulation of Ynt1, increasing Ynt1 phosphorylation at Ser-244 and -246 and reducing ubiquitinylation. Furthermore, Npr1 is phosphorylated in response to the preferred nitrogen sources, and indeed it is dephosphorylated in nitrogen-free medium. Under conditions where Npr1 is phosphorylated, Ynt1 is not and vice versa. We show for the first time that carbon starvation leads to Npr1 phosphorylation, whereas Ynt1 is dephosphorylated and degraded in the vacuole. Rapamycin prevents this, indicating a possible role of the target of rapamycin signaling pathway in this process. We concluded that Npr1 plays a key role in adapting Ynt1 levels to the nitrogen quality and availability of a source of carbon.

Mechanisms of ATR-mediated checkpoint signalling.

Cell cycle checkpoints maintain genomic integrity by delaying cell division in the presence of DNA damage or replication problems. A crucial player in this process is the ATR kinase. The rapid localisation of ATR to sites of genotoxic stress and the central role of this kinase in the checkpoint response lead to the suggestion that ATR functions as a sensor of DNA lesions. After activation, ATR phosphorylates and activates the effector kinase Chk1, thereby causing an inhibition in cell cycle progression. However, this would not be possible without the existence of many other proteins operating in this pathway. Here we review current progress in our understanding of the regulatory factors involved in the ATR-mediated checkpoint response, as well as resumption of cell cycle progression upon repair of the damage, thereby focussing on the mechanisms in mammalian cells.

Phosphorylation of the yeast nitrate transporter Ynt1 is essential for delivery to the plasma membrane during nitrogen limitation.

Ynt1 is the sole high affinity nitrate transporter of the yeast Hansenula polymorpha. It is highly regulated by the nitrogen source, by being down-regulated in response to glutamine by repression of the YNT1 gene and Ynt1 ubiquitinylation, endocytosis, and vacuolar degradation. On the contrary, we show that nitrogen limitation stabilizes Ynt1 levels at the plasma membrane, requiring phosphorylation of the transporter. We determined that Ser-246 in the central intracellular loop plays a key role in the phosphorylation of Ynt1 and that the nitrogen permease reactivator 1 kinase (Npr1) is necessary for Ynt1 phosphorylation. Abolition of phosphorylation led Ynt1 to the vacuole by a pep12-dependent end4-independent pathway, which is also dependent on ubiquitinylation, whereas Ynt1 protein lacking ubiquitinylation sites does not follow this pathway. We found that, under nitrogen limitation, Ynt1 phosphorylation is essential for rapid induction of nitrate assimilation genes. Our results suggest that, under nitrogen limitation, phosphorylation prevents Ynt1 delivery from the secretion route to the vacuole, which, aided by reduced ubiquitinylation, accumulates Ynt1 at the plasma membrane. This mechanism could be part of the response that allows nitrate-assimilatory organisms to cope with nitrogen depletion.

Functional characterization of the Arabidopsis thaliana nitrate transporter CHL1 in the yeast Hansenula polymorpha.

CHL1 (AtNRT1.1) is a dual-affinity nitrate transporter of Arabidopsis thaliana, in which phosphorylation at Thr 101 switches CHL1 from low to high nitrate affinity. CHL1 expressed in a Hansenula polymorpha high-affinity nitrate-transporter deficient mutant (Deltaynt1) restores nitrate uptake and growth. These events take place at nitrate concentrations as low as 500 microM, suggesting that CHL1 has a high-affinity for nitrate in yeast. Accordingly, CHL1 expressed in H. polymorpha presents a K(m) for nitrate of about 125 microM. The absence of nitrate, the CHL1 gene inducer, showed the high turnover rate of CHL1 expressed in yeast, which is counteracted by nitrate CHL1 induction. Furthermore, H. polymorpha strains expressing CHL1 become sensitive to 250 microM chlorate, as expected for CHL1 high-affinity behaviour. Given that CHL1 presented high affinity by nitrate, we study the role of CHL1 Thr101 in yeast. Strains producing CHL1Thr101Ala, unable to undergo phosphorylation, and CHL1Thr101Asp, where CHL1 phosphorylation is constitutively mimicked, were used. Yeast strains expressing CHL1Thr101Ala, CHL1Thr101Asp and CHL1 at the same rate showed that Deltaynt1CHL1Thr101Ala is strikingly unable to transport nitrate and contains a very low amount of CHL1 protein; however, Deltaynt1CHL1Thr101Asp restores nitrate uptake and growth, although no significant changes in nitrate affinity were observed. Our results show that CHL1-Thr101 is involved in regulating the levels of CHL1 expressed in yeast and suggest that the phosphorylation of this residue could be involved in targeting this nitrate transporter to the plasma membrane. The functional expression of CHL1 in H. polymorpha reveals that this yeast is a suitable tool for evaluating the real nitrate transport capacity of plant putative nitrate transporters belonging to different families and study their regulation and structure function relationship.

Down-regulation of eukaryotic nitrate transporter by nitrogen-dependent ubiquitinylation.

In the yeast Hansenula polymorpha, the YNT1 gene encodes the high affinity nitrate transporter, which is repressed by reduced nitrogen sources such as ammonium or glutamine. Ynt1 protein is degraded in response to glutamine in the growth medium. Ynt1 disappears independently of YNT1 glutamine repression as shown in strains where YNT1 repression is abolished. Ynt1-green fluorescent protein chimera and a mutant defective in vacuolar proteinase A (deltapep4) showed that Ynt1 is degraded in the vacuole in response to glutamine. The central hydrophilic domain of Ynt1 contains PEST-like sequences whose deletion blocked Ynt1 down-regulation. Site-directed mutagenesis showed that Lys-253 and Lys-270, located in this sequence, were involved in internalization and subsequent vacuolar degradation of Ynt1. Ynt1-ubiquitin conjugates were induced by glutamine and not nitrate. We conclude that glutamine triggers Ynt1 down-regulation via ubiquitinylation of lysines in the central hydrophilic domain, and proteolysis in the vacuole.

Functional properties and differential mode of regulation of the nitrate transporter from a plant symbiotic ascomycete.

Nitrogen assimilation by plant symbiotic fungi plays a central role in the mutualistic interaction established by these organisms, as well as in nitrogen flux in a variety of soils. In the present study, we report on the functional properties, structural organization and distinctive mode of regulation of TbNrt2 (Tuber borchii NRT2 family transporter), the nitrate transporter of the mycorrhizal ascomycete T. borchii. As revealed by experiments conducted in a nitrate-uptake-defective mutant of the yeast Hansenula polymorpha, TbNrt2 is a high-affinity transporter (K(m)=4.7 microM nitrate) that is bispecific for nitrate and nitrite. It is expressed in free-living mycelia and in mycorrhizae, where it preferentially accumulates in the plasma membrane of root-contacting hyphae. The TbNrt2 mRNA, which is transcribed from a single-copy gene clustered with the nitrate reductase gene in the T. borchii genome, was specifically up-regulated following transfer of mycelia to nitrate- (or nitrite)-containing medium. However, at variance with the strict nitrate-dependent induction commonly observed in other organisms, TbNrt2 was also up-regulated (at both the mRNA and the protein level) following transfer to a nitrogen-free medium. This unusual mode of regulation differs from that of the adjacent nitrate reductase gene, which was expressed at basal levels under nitrogen deprivation conditions and required nitrate for induction. The functional and expression properties, described in the present study, delineate TbNrt2 as a versatile transporter that may be especially suited to cope with the fluctuating (and often low) mineral nitrogen concentrations found in most natural, especially forest, soils.