The hypoxia responsive transcription factor genes ERF71/HRE2 and ERF73/HRE1 of Arabidopsis are differentially regulated by ethylene.

The AR2/ERF transcription factor genes ERF71/HRE2 and ERF73/HRE1 were induced at hypoxic conditions in Arabidopsis thaliana roots. ERF73/HRE1 but not its related gene ERF71/HRE2 was furthermore regulated by ethylene. Treatment with 1 ppm ethylene promoted ERF73/HRE1 expression fivefold. This induction did not occur in the presence of the ethylene receptor inhibitor 1-methylcyclopropene. ERF73/HRE1 expression positively regulated alcohol dehydrogenase (ADH) activity, which was analyzed as a marker enzyme for metabolic adaptation to hypoxic stress. The knock out lines erf73/hre1-1 and erf73/hre1-2 showed lowered ADH activity; the overexpressing lines ERF73/HRE1-ox1 and ERF73/HRE1-ox5 displayed elevated ADH activity. Treatment of wild-type Arabidopsis with 5% O2 and 1 ppm ethylene resulted in higher induction of ADH activity than that observed with 5% O2 or 1 ppm ethylene alone. ERF73/HRE1-ox1 and ERF73/HRE1-ox5 plants that were exposed to 5% O2 did not show enhanced ADH activity after treatment with ethylene, indicating that the ethylene response with respect to ADH activity was saturated in the ERF73/HRE1ox lines. In contrast, erf73/hre1-1 and erf73/hre1-2 lines displayed ethylene-dependent ADH activity pointing to redundant factor(s) that can mediate ethylene regulation of ADH activity in the Arabidopsis root. Our data show that ethylene regulates metabolic adaptation to low oxygen stress in the Arabidopsis root through ERF73/ HRE1.

Endogenous hSNM1B/Apollo interacts with TRF2 and stimulates ATM in response to ionizing radiation.

Human SNM1B/Apollo is involved in the cellular response to DNA-damage, however, its precise role is unknown. Recent reports have implicated hSNM1B in the protection of telomeres. We have found hSNM1B to interact with TRF2, a protein which functions in telomere protection and in an early response to ionizing radiation. Here we show that endogenous hSNM1B forms foci which colocalize at telomeres with TRF1 and TRF2. However, we observed that additional hSNM1B foci could be induced upon exposure to ionizing radiation (IR). In live-cell-imaging experiments, hSNM1B localized to photo-induced double-strand breaks (DSBs) within 10s post-induction. Further supporting a role for hSNM1B in the early stages of the cellular response to DSBs, we observed that autophosphorylation of ATM, as well as the phosphorylation of ATM target proteins in response to IR, was attenuated in cells depleted of hSNM1B. These observations suggest an important role for hSNM1B in the response to IR damage, a role that may be, in part, upstream of the central player in maintenance of genome integrity, ATM.

Evidence for hSNM1B/Apollo functioning in the HSP70 mediated DNA damage response.

The hSNM1B/Apollo protein is involved in the cellular response to DNA-damage as well as in the maintenance of telomeres during S-phase. TRF2 has been shown to interact physically with hSNM1B. As a core component of shelterin, TRF2 functions in organization and protection of telomeres. However, TRF2 was also shown to have a role in the early DNA-damage response, suggesting that hSNM1B and TRF2 cooperate in this dual function. Here we have used Tandem-Affinity-Purification in combination with mass spectrometry to identify additional binding partners of hSNM1B. This revealed HSC70, HSP72, HSP60 and beta-Tubulin to be hSNM1B-interactors. We have confirmed the interaction of hSNM1B and HSP70 in co-immunoprecipitation assays and found that hSNM1B binds to a C-terminal fragment of HSP72, known to contain the substrate binding domain. Depletion of HSP72 in human fibroblasts resulted in a significant reduction of nuclear hSNM1B foci. We also found the phosphorylation of CHK1 at serine 317 to be attenuated in response to UVC irradiation as a consequence of hSNM1B depletion, a result which extends our previous findings on the DNA-damage response function of hSNM1B. HSP70 chaperones have been implicated in the maintenance of genome stability and their expression is often aberrant in cancer. Our results presented here, suggest that the role in genome stability might not be specific to HSP70 but rather can be attributed, at least in part, to hSNM1B. This, together with its stimulating effect on ATM and ATR substrate phosphorylation in response to DNA-damage qualify hSNM1B as a putative target in cancer therapy.

A systematic proteomic study of irradiated DNA repair deficient Nbn-mice.

BACKGROUND: The NBN gene codes for the protein nibrin, which is involved in the detection and repair of DNA double strand breaks (DSBs). The NBN gene is essential in mammals. METHODOLOGY/PRINCIPAL FINDINGS: We have used a conditional null mutant mouse model in a proteomics approach to identify proteins with modified expression levels after 4 Gy ionizing irradiation in the absence of nibrin in vivo. Altogether, amongst approximately 8,000 resolved proteins, 209 were differentially expressed in homozygous null mutant mice in comparison to control animals. One group of proteins significantly altered in null mutant mice were those involved in oxidative stress and cellular redox homeostasis (p<0.0001). In substantiation of this finding, analysis of Nbn null mutant fibroblasts indicated an increased production of reactive oxygen species following induction of DSBs. CONCLUSIONS/SIGNIFICANCE: In humans, biallelic hypomorphic mutations in NBN lead to Nijmegen breakage syndrome (NBS), an autosomal recessive genetic disease characterised by extreme radiosensitivity coupled with growth retardation, immunoinsufficiency and a very high risk of malignancy. This particularly high cancer risk in NBS may be attributable to the compound effect of a DSB repair defect and oxidative stress.

CUL4 associates with DDB1 and DET1 and its downregulation affects diverse aspects of development in Arabidopsis thaliana.

Cullins are central scaffolding subunits in eukaryotic E3 ligases that facilitate the ubiquitination of target proteins. Arabidopsis contains at least 11 cullin proteins but only a few of them have been assigned biological roles. In this work Arabidopsis cullin 4 is shown to assemble with DDB1, RBX1, DET1 and DDB2 in vitro and in planta. In addition, by using T-DNA insertion and CUL4 antisense lines we demonstrate that corresponding mutants are severely affected in different aspects of development. Reduced CUL4 expression leads to a reduced number of lateral roots, and to abnormal vascular tissue and stomatal development. Furthermore, cul4 mutants display a weak constitutive photomorphogenic phenotype. These results therefore assign an important function to CUL4 during plant development and provide strong evidence that CUL4 assembles together with RBX1 and DDB1 proteins to form a functional E3 ligase in Arabidopsis.