Ataxia Telangiectasia Mutated-Dependent Apoptosis after Genotoxic Stress in the Developing Nervous System Is Determined by Cellular Differentiation Status

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The Journal of Neuroscience, September 1, 2001, 21(17):6687-6693

Ataxia Telangiectasia Mutated-Dependent Apoptosis after Genotoxic Stress in the Developing Nervous System Is Determined by Cellular Differentiation Status
Youngsoo Lee, Miriam J. Chong, and Peter J. McKinnon
Department of Genetics, St. Jude Children's Research Hospital, Memphis, Tennessee 38105

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Ataxia-telangiectasia (A-T) is a neurodegenerative syndrome resulting from dysfunction of ATM (ataxia telangiectasia mutated).The molecular details of ATM function in the nervous system areunclear, although the neurological lesions in A-T are probablydevelopmental because they appear during childhood. The nervoussystems of Atm-null mice show a pronounced defect in apoptosisthat is induced by DNA damage, suggesting that ATM may functionto eliminate DNA-damaged neurons. Here we show that Atm-dependentapoptosis occurs at discrete stages of neurogenesis. Analysisof $gamma$ -irradiated mouse embryos showed that Atm-dependent apoptosisoccurred only in the postmitotic populations that were presentin the neuroepithelial subventricular zone of the developing nervoussystem. Notably, Atm deficiency did not prevent radiation-inducedapoptosis in multipotent precursor cells residing in the proliferatingventricular zone. Atm-dependent apoptosis required p53 and coincidedwith the specific phosphorylation of p53 and caspase-3 activation.Thus, these data show that Atm functions early in neurogenesisand underscore the selective requirement for Atm in eliminatingdamaged postmitotic neural cells. Furthermore, these data demonstratethat the differentiation status of neural cells is a criticaldeterminant in the activation of certain apoptoticpathways.

Key words: ataxia-telangiectasia; ATM; p53; subventricular zone; neurogenesis; apoptosis; ionizing radiation; DNA damage; DNA repair

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Individuals with the autosomal recessive disorder ataxia-telangiectasia (A-T) manifest a diverse array of symptoms, includingimmune deficiency, predisposition to cancer, progressive neurodegeneration,and hypersensitivity to ionizing radiation (IR) (for review, seeSedgwick and Boder, 1991; Lavin and Shiloh, 1997; Crawford, 1998;Gatti et al., 2001). Cell lines derived from A-T individuals alsoshow x-ray sensitivity, cell cycle checkpoint defects, prematuresenescence, and genomic instability (Lavin and Shiloh, 1997; Rotmanand Shiloh, 1998). A-T results from dysfunction of ATM (ataxiatelangiectasia mutated), a 370 kDa protein that has protein kinaseactivity with specificity for serine and threonine residues andC-terminal sequence similarity to the phosphatidyl-inositol-3-kinase(PI₃K) family (Savitsky et al., 1995; Lim et al., 2000).

The most prevalent feature of A-T is progressive neurodegeneration, although the mechanism and the etiological agent thatare responsible are unknown. Therefore, understanding ATM signalingin the nervous system is particularly relevant to the neuropathologyof A-T. It is likely that ATM dysfunction impacts during development,because the neurological defects in A-T are apparent early inlife (Sedgwick and Boder, 1991; Crawford, 1998). Furthermore,Atm is highly expressed in the developing mouse nervous systembut expressed only at low levels in the adult CNS (Soares et al.,1998).

Insight into ATM function in the nervous system has come from Atm-null mice. These mice recapitulate many of the featuresof the human disease, including cancer predisposition and severeintestinal toxicity after radiation (Barlow et al., 1996; Elsonet al., 1996; Xu et al., 1996; Herzog et al., 1998; Borghesaniet al., 2000). Additionally, cells derived from the Atm-null mousehave similar characteristics to human A-T cells, such as cellcycle checkpoint defects and replicative senescence (Rotman andShiloh, 1998). Although overt ataxia is not present in these mice,neurological deficits have been reported. These include behavioralabnormalities, dopaminergic neuron loss in the substantia nigra,and altered brain electrophysiology (Barlow et al., 1996; Eilamet al., 1998; Chiesa et al., 2000). In contrast to the extremeradiosensitivity present in A-T individuals, Atm-null mice showa striking resistance to DNA damage-induced apoptosis in the nervoussystem (Herzog et al., 1998; Chong et al., 2000). These data suggestthat ATM may function to eliminate neural cells that have incurredgenomic damage (Herzog et al., 1998; Lee and McKinnon, 2000).Additional support for this assertion comes from the prevalenceof neurodegeneration in many DNA repair-deficient syndromes (Roligand McKinnon, 2000).

The current consensus is that ATM functions as a protein kinase, and inactivation of this kinase activity is responsible forA-T. Biochemical and genetic analyses have identified varioussubstrates for ATM (Lim et al., 2000), and some of these willbe important for ATM function in the nervous system. One wellcharacterized substrate of ATM is p53 (Kastan et al., 1992; Kastanand Lim, 2000). For example, IR promotes Atm-dependent p53 stabilizationleading to G₁ arrest. ATM is required for the phosphorylationof serine-15 and serine-20 of p53 in a DNA damage-dependent mannerthat leads to stabilization and transcriptional activation (Baninet al., 1998; Canman et al., 1998; Khanna et al., 1998; Watermanet al., 1998; Ahn et al., 2000). Whereas serine-20 phosphorylationof p53 occurs via an ATM-dependent modification of Chk2, serine-15phosphorylation may be a direct event. Thus, in vitro, ATM canaffect p53 phosphorylation, and these events may contribute collectivelyto p53 function (Meek, 1999). Although these Atm-dependent modificationsof p53 are uncharacterized in the nervous system, they are likelyto be relevant because the defect in IR-induced apoptosis in Atm-nullneurons is also present in p53-null mice (Enokido et al., 1996;Morrison et al., 1996; Herzog et al., 1998; Chong et al., 2000).Therefore, we assessed Atm function in the developing nervoussystem. Here we report that Atm functions at defined developmentalstages and structures in the nervous system to regulate radiation-inducedapoptosis.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Animals. Mice were housed in an American Association of Laboratory Animal Care-accredited facility and were maintained inaccordance with the National Institutes of Health Guide for theCare and Use of Laboratory Animals. All procedures for animaluse were approved by the institutional animal care and use committeeat St. Jude Children's Research Hospital. The presence of a vaginalplug was designated as embryonic day 0.5 (E0.5) and the day ofbirth as postnatal day 0 (P0). All experimental groups containedat least three Atm or p53 knock-out mice along with wild-typelittermates. Mice were irradiated with 14 Gy from a cesium irradiator(at a rate of 0.9 Gy/min) and killed at 1, 2, 4, 6, or 18 hr afterirradiation. Littermate animals without irradiation were usedas controls. Tissues were collected after transcardial perfusionwith 4% paraformaldehyde in PBS. E12.5 and E15.5 embryos weresubmersed into paraformaldehyde solution immediately after dissection.Fixed tissues were cryoprotected in 25% buffered sucrose solutionand cryosectioned at 12 µm with a HM500M cryostat (MICROM, Walldorf,Germany).

Histology and immunohistochemistry. Neutral red staining was performed with 1% Neutral Red (Aldrich Chemical, Milwaukee, WI)in 0.1 M acetic acid, pH 4.8, for 1 min, followed by dehydrationin ethanol; the slides were coverslipped with Permount (FisherScientific, Pittsburgh, PA). For immunohistochemistry the followingantibodies were used: CM5 anti-p53 (at 1:1000 for postnatal brainsand 1:500 for embryos; Novocastra Laboratories, Newcastle on Tyne,UK), anti-phospho-p53 (Ser15, at 1:250 for postnatal brains and1:150 for embryos; New England Biolabs, Beverly, MA), anti-P27(at 1:1000; Santa Cruz Biotechnology, Santa Cruz, CA), anti active-caspase-3(CM1, at 1:1000; IDUN Pharmaceuticals, San Diego, CA), anti-Ki67(at 1:1000; Novocastra Laboratories), and anti- $beta$ -tubulin III (Tuj1,at 1:1000; Babco, Richmond, CA). Antigen retrieval (Midgley etal., 1992) was used for all immunohistochemistry. Cryosectionswere incubated with antibodies overnight at room temperature afterbeing quenched with endogenous peroxidase, using 0.6% hydrogenperoxide. Immunoreactivity was visualized with the VIP substratekit (Vector Laboratories, Burlingame, CA) according to the manufacturer'sdirections after the tissues were treated with biotinylated secondaryantibody and avidin DH-biotinylated horseradish peroxidase-H complex(Vectastain Elite Kit, Vector Laboratories). Sections were counterstainedwith 0.1% methyl green (Vector Laboratories), dehydrated, andmounted in Permount. In situ end labeling (ISEL) staining wasperformed on cryosections with the Klenow-FragEL kit (OncogeneResearch Products, San Diego, CA) according to the manufacturer'sdirections. For fluorescence detection the embryo sections weretreated with blocking solution (5% donkey serum and 1% bovineserum) and then incubated with p53 antibody (CM5 at 1:500). Signalsof p53 were visualized with TRITC-anti rabbit IgG raised in donkey(1:200). After intensive washing and blocking with 5% goat serumand 1% bovine serum, the sections were incubated with Ki67 antibody(1:500). FITC-anti rabbit IgG raised in goat (1:200) was usedto detect Ki67signals.

Nonradioactive in situ hybridization. pSPORT containing nucleotides 8345-8939 of mouse Atm was used to generate in situ probes(Soares et al., 1998). Digoxigenin (DIG)-labeled riboprobes weresynthesized by in vitro transcription according to the standardDIG-labeling reaction protocol from Roche Bioscience (Palo Alto,CA). T7 RNA polymerase was used to synthesize the sense probe,and SP6 RNA polymerase was used for the antisense probe. Cryosectionswere washed in PBS [containing (in mM) 140 NaCl, 2.7 KCl, 10 Na₂HPO₄,and 1.8 KH₂PO₄, pH 7.4] and deproteinized with 1 µg/ml proteinaseK in Tris-EDTA buffer (100 mM Tris, 50 mM EDTA, pH 8.0) for 30min. After brief post-fixation with 4% buffered paraformaldehydeand several washes, the sections were acetylated with acetic anhydride(0.25% in 0.1 M triethanolamine buffer, pH 8.0). Sections thenwere incubated with hybridization buffer (50% formamide, 50 µg/mlyeast tRNA, 50 µg/ml heparin, 1% SDS, and 5× SSC, pH 4.5) for2 hr at 56°C. Finally, the sections were incubated with the hybridizationbuffer containing 0.6 ng/µl of antisense or sense probes at 72°Covernight in a humidified chamber. On the following day the sectionswere washed sequentially in 5× SSC, 0.2× SSC, and Tris bufferI (100 mM NaCl, 100 mM Tris, pH 7.5). For immunological detectionthe sections were incubated with 5% BSA and 5% normal sheep serumin Tris buffer I containing 0.1% Triton X-100 and then with asheep anti-DIG alkaline phosphate antiserum (at 1:500; Roche)overnight at room temperature in a humidified chamber. To visualizethe positive signals, we rinsed sections with Tris buffer I andsubsequently with Tris buffer II, pH 9.5 (100 mM Tris, 100 mMNaCl, 50 mM MgCl₂). The signal for Atm mRNA was developed withNBT/BCIP solution (Roche) in Tris buffer II, and the reactionwas stopped by incubating the slides in 10 mM Tris and 1 mM EDTA,pH 8.1.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Atm-dependent apoptosis is a feature of differentiating cells in the retina

We used ISEL staining of P5 retina from Atm-null and wild-type (WT) mice 18 hr after radiation treatment to identify the cellsthat were susceptible to apoptosis in this tissue. Although WTretina was susceptible to radiation-induced apoptosis, there wasa pronounced resistance in Atm-null retina (Fig. 1A). However,the resistance to apoptosis in the Atm-null retina was confinedto the central region, because many neuroblasts in the peripheryof the Atm-null P5 retina underwent apoptosis after radiation(Fig. 1A). A distinguishing characteristic of this peripheralcell population is that they are proliferating, undifferentiatedcells, as distinct to the postmitotic central neuroblasts (Fig.1B) (Young, 1985a,b). Thus, Atm is dispensable for radiation-inducedapoptosis in cycling cells in the retina.

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Figure 1. Atm is required for apoptosis that is induced by ionizing radiation in the differentiating zone of the retina. A, ISEL-positive signal occurs throughout the P5 wild-type (WT) retina but only in the undifferentiated field of the Atm-null retina 18 hr after radiation. B, Schematic diagram shows the stage of cell differentiation in the P5 retina; a is proliferative, whereas b is the differentiating region. In both A and B the arrow demarcates the boundary between proliferation and differentiation. C, At E15.5, cell death, shown by ISEL labeling, is widespread in the WT (e, f) but markedly reduced in the Atm^/ animals (g, h). The irradiated p53^/ E15.5 retina (i, j) is indistinguishable to the unirradiated WT (c, d). Proliferative populations in the E15.5 retina are shown by Ki67 (a), and differentiating fields are shown by TuJ1 immunoreactivity (b).

To define Atm involvement in retinal cell populations further, we examined apoptosis after radiation at embryonic stages ofretinal development. We used markers for proliferating cells,such as Ki67 (Gatter et al., 1986), and differentiating neurons,such as Tuj1 (a neuron-specific $beta$ -tubulin III), to distinguishthese populations in the retina (Fig. 1Ca,Cb). Although WT retinashowed extensive apoptosis after radiation (Fig. 1Ce,Cf), Atmdeficiency resulted in a marked abrogation of IR-induced apoptosisin the neuroblasts of the developing E15.5 retina (Fig. 1Cg,Ch).However, consistent with the P5 situation, some apoptosis wasobserved in the proliferative layer of the Atm^/ retina (Fig. 1Cg,Ch). Essentially no apoptosis, as judged byISEL staining, was seen without radiation treatment in the WT(Fig. 1Cc,Cd) or Atm^/ or p53^/ (results not shown). There was a pronounced lack of apoptosisafter IR in the Tuj1-positive layer of Atm-null neuroblasts comparedwith extensive death through this layer in WT retina. Apoptosisin the Atm^/ was confined to regions harboring cells that reside in the proliferativelayer. Consistent with a requirement of p53 for radiation-inducedapoptosis, there was no cell death in the E15.5 p53-null retinaafter IR (Fig. 1Ci,Cj; seebelow).

Serine-15 phosphorylation of p53 after ionizing radiation requires Atm

Atm signaling to p53 is a critical step in IR-induced apoptosis in the postnatal cerebellum (Herzog et al., 1998); accordingly,p53 stabilization and apoptosis after IR are reduced greatly inthe P5 cerebellum of Atm-deficient animals (Fig. 2). However,p53 stabilization still occurs, although at very reduced levelscompared with WT (Fig. 2e). Because ATM is known to modify serine-15of p53 selectively after DNA damage (Banin et al., 1998; Canmanet al., 1998), we assessed serine-15 phosphorylation of p53 afterIR as a measure of Atm activation. We used phospho-specific antiseraagainst phosphorylated serine-15 of p53 to detect phosphorylationof the equivalent residue (serine-18) of mouse p53. We comparedstabilization and phosphorylation of p53, before and 1 hr afterIR, in the P5 cerebellum in WT and Atm-null mice (Fig. 2). Wefound that serine-18 phosphorylation of p53 was absent 1 hr afterIR in Atm-null animals, compared with controls (Fig. 2d,f). Thus,phosphorylation of p53 serine-18 after radiation is Atm-dependentin the developing cerebellum and reflects Atm signaling to p53.These data also indicate a portion of p53 stabilization afterIR is independent of serine-18 phosphorylation (compare Fig. 2e,f).Therefore, we also included anti-serine-15 phospho-specific immunohistochemistryin the following experiments to evaluate specific Atm signalingprecisely in the developing nervous system.

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Figure 2. Serine-18 phosphorylation of p53 after radiation in the P5 cerebellum requires Atm. The external granule layer (EGL) of the wild-type P5 cerebellum shows increased amounts of p53 (c) and phosphorylated p53 (serine-18; d) 1 hr after radiation. In the Atm-deficient P5 cerebellum, p53 stabilization is reduced dramatically (e), and serine-18 phosphorylated p53 is not detected (f). No p53 or serine-18 phosphorylated p53 is detected in unirradiated tissue (a, b).

Atm is required for IR-induced apoptosis in cell populations of the subventricular zone

Analysis of Atm in the developing retina indicates a distinct role in mitotic compared with differentiating cells in radiation-inducedapoptosis. To determine the extent of the relationship of Atmto cellular differentiation, we examined Atm function after IRduring neural development. To do this, we irradiated embryos ateither E12.5 or E15.5 and assessed Atm function via p53 stabilizationand serine-18 modification of p53. In the developing nervous systemat E12.5 there is extensive cellular proliferation, but only limiteddifferentiation. At this stage the majority of the CNS shows immunoreactivityfor the proliferation marker Ki67 (Fig. 3a) but a restricted stainingfor neuronal differentiation markers such as Tuj1 (data not shown).As reported previously (Soares et al., 1998) and shown here inFigure 3b, Atm expression as determined by in situ hybridizationis particularly abundant in the ventricular layers of the neuroepitheliumduring this stage of development.

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Figure 3. Atm function is distinct between the ventricular and subventricular zones. Comparative analysis of WT and Atm^/ embryos at E12.5 and E15.5 showed a marked reduction in radiation-induced death in the Atm^/ SVZ, as indicated by the asterisks. Regions of proliferation at E12.5 and E15.5 are indicated by Ki67 (a, k) and differentiation at E15.5 by Tuj1 (l) immunostaining. Atm expression at E12.5 is shown by in situ hybridization in b. In the ganglionic eminence and primordial plexiform layer at E12.5 (c-h), no differences in p53 immunostaining between WT and Atm^/ are observed: no irradiation (c, d), irradiated WT (e, f), or irradiated Atm^/ (g, h). In the WT E15.5 neopallial cortex (m-r) p53 stabilization and serine-18 phosphorylation are widespread (o, p), whereas they are restricted to the ventricular zone in Atm^/ (q, r). Apoptosis is present in WT (i), but not in the ventricular zone of the E12.5 p53^/ embryo (j). Regions of caspase-3 activation in E15.5 WT (s) and Atm^/ (t) coincided with p53 stabilization and phosphorylation.

After radiation at E12.5, p53 stabilization and serine-18 phosphorylation were found throughout the ventricular zones (VZ)of the CNS in both WT and Atm-null animals (Fig. 3e-h). No detectablep53 stabilization or serine-18 phosphorylation was seen withoutradiation (Fig. 3c,d). Cell death measured by ISEL was also apparentthroughout the CNS 4 hr after radiation and was confined to regionsthat showed serine-18 phosphorylation, p53 stabilization, andactivated caspase-3 immunoreactivity (data not shown). Becausethe extent of p53 activation occurring in WT and Atm-null embryoswas indistinguishable, it is unlikely that Atm is required forIR-induced apoptosis in these proliferative zones. Thus, in multipotentialproliferating cells in the E12.5 VZ, Atm status is unimportantfor radiation-inducedapoptosis.

However, in contrast to E12.5, at E15.5 there was a clear Atm dependency for IR-induced death in the subventricular zone (SVZ)of the developing nervous system. Atm was required for p53 stabilization,serine-18 phosphorylation, and caspase-3 activation in the SVZof the neopallial cortex (Fig. 3q,r,t), whereas radiation ledto widespread apoptosis in WT embryos (Fig. 3o,p,s). However,like E12.5, cell populations in the VZ of the E15.5 neopallialcortex in either WT or Atm-null are equally susceptible to radiation.Although Atm is not required for radiation-induced apoptosis inthe VZ, p53 is essential in both this region and the SVZ (Fig.3i,j). We also found an absence of radiation-induced apoptosisthroughout the nervous system of p53-null embryos at developmentalstages between E12.5 and E18.5 (results notshown).

In other regions of the CNS, such as the cingulate cortex, a similar requirement of Atm for IR-induced death in postmitoticcells (p27- and Tuj1-immunopositive regions) of the SVZ was observed(Fig. 4). Throughout the WT cingulate cortex IR induced p53 stabilization,caspase-3 activation, and cell death (Fig. 4d,h-j). However, inthe Atm-deficient embryos, the activation of p53 and caspase-3after radiation occurred only in the VZ (Fig. 4f,k-m), with nosignificant increase in immunoreactivity for p53 or active caspase-3in the SVZ of the Atm-null embryos.

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Figure 4. Postmitotic regions in the Atm^/ cingulate cortex are resistant to radiation-induced apoptosis. In the Atm^/ cingulate cortex at E15.5, the subventricular zone (SVZ) was markedly resistant to radiation-induced apoptosis. Proliferating cells were identified by Ki67 (a); to identify postmitotic regions that define the SVZ, we used p27 (b) and Tuj1 (c). The SVZ of WT embryos shows radiation-dependent serine-18 phosphorylation of p53 (d, h), whereas the Atm^/ SVZ does not (f, k). Activated caspase-3 immunoreactivity is shown at 1 hr (e, g) and 4 hr (i, l) after radiation. ISEL+ staining indicates that apoptosis occurs in WT (j), but not in Atm^/ (m), cingulate cortex SVZ.

Although Atm-dependent apoptosis coincided only with Tuj1- or p27-immunopositive regions in the SVZ, we used comparative colocalizationof Ki67 and p53 after radiation in WT and Atm-null E15.5 embryos.Figure 5 shows that the p53-positive signal in the Atm-null caudatenucleus was confined to regions that harbor Ki67-immunoreactivecells and was not present in the Ki67-negative cells (Fig. 5d-f),whereas the WT caudate nucleus showed a strong p53 signal in Ki67-negativeregions (Fig. 5a-c).

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Figure 5. Radiation-induced stabilization of p53 occurs in proliferating cells. At 1 hr after radiation, p53 stabilization in the caudate nucleus from WT E15.5 is widespread (a-c), but in Atm^/ it is restricted to Ki67-expressing regions (d-f). c and f are merged images of a, b and d, e, respectively. The arrows in c and f indicate the subventricular zone.

Thus, Atm is required for p53 activation in the SVZ, but not mitotic cells of the VZ. This is despite high Atm expressionin these proliferating areas. Consequently, whereas Atm is importantfor IR-induced apoptosis in the SVZ, it does not appear to playa role in IR-induced apoptosis of the proliferative populationsof theVZ.

Atm is required for IR-induced apoptosis in the developing peripheral nervous system

High levels of Atm expression have been found in dorsal root ganglia (DRG) throughout development and adulthood (Soares etal., 1998). However, no function has been reported for Atm inthe PNS. To determine whether Atm function in the PNS is similarto that in the CNS, we examined E12.5 DRG after radiation. Inthe Atm-null DRG there was a pronounced reduction in cells undergoingIR-induced apoptosis compared with WT tissue (Fig. 6b,d). Consistentwith the report of heterogeneity of Atm expression in the DRG(Soares et al., 1998), the apoptotic response is not entirelyuniform because there are some ISEL+ cells in the Atm-null DRG(Fig. 6d). The resistance of Atm-null DRG to radiation-inducedapoptosis occurred at all levels of the spinal cord (lumbar tosacral) in an indistinguishable manner to that shown in Figure6 (results not shown). Consistent with other CNS regions, therewas also widespread apoptosis in the spinal cord of the WT animal18 hr after radiation, but not in the spinal cord of Atm-nullmice (Fig. 6a,b). Other PNS regions, such as the trigeminal ganglion,also showed increased cell death in the wild-type, but not inthe Atm-null, embryos after radiation (data not shown). Thus,consistent with Atm expression in the DRG, we demonstrate herethat Atm is also important for radiation-induced apoptosis duringdevelopment in this structure, broadening the Atm function toa role in the developing PNS.

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Figure 6. Atm is required for radiation-induced apoptosis in the peripheral nervous system. Widespread apoptosis in the WT (a, c), but not in Atm^/ (b, d), dorsal root ganglia (DRG) is shown both as neutral red staining (a, b) and ISEL staining (c, d). Neutral red-stained pyknotic nuclei are also apparent in the WT (a), but not in Atm^/ (b), spinal cord (SC).

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In this report we showed that the developmental stage and differentiation status of the nervous system determine Atm-dependentapoptosis after radiation. Furthermore, Atm function appears tobe important only in the SVZ, where it is required for apoptosisof neural cells after radiation. It is surprising that, whereasAtm is expressed in the VZ, it is not required for radiation-inducedapoptosis in this region. Although it is possible that the deathobserved in the Atm^/ VZ was attributable to excessive radiation dose, coupled withthe extreme sensitivity of proliferating cells to radiation, thestriking resistance in the Atm^/ SVZ makes this explanation seem unlikely. Moreover, there isstill a genetic basis for this apoptosis, because p53^/ VZ cells do not undergo radiation-induced death. Therefore, analternative effector must operate in the VZ that activates p53.Although the identity of this effector is speculative, it maybe the ATM-related protein, ataxia telangiectasia Rad 3-related(ATR), which also can signal to p53 via serine-15 phosphorylation(Tibbetts et al., 1999; Shiloh, 2001). In contrast to the nervoussystem, during early development (~E6.5) multipotential precursorsin the mouse embryo show Atm-dependent apoptosis after IR (Heyeret al., 2000). This implicates a role for Atm during early stagesof development and may have some bearing on the recent reportsof early lethality in double knock-outs of Atm and DNA-PK_cs (Gurleyand Kemp, 2001), Atm and Ku (Sekiguchi et al., 2001), and Atmand PARP (Menisser-de Murcia et al., 2001).

The presence of apoptosis in the SVZ, but not in the VZ, after DNA damage has been reported in a number of different mousemodels with inactivated DNA repair genes (Barnes et al., 1998;Gao et al., 1998; Deans et al., 2000; Gilmore et al., 2000; Sugoet al., 2000). However, it is likely that the actual DNA damageoccurred in the proliferating cell populations of the VZ, possiblyduring S-phase when there is a greater opportunity for DNA strandbreakage to occur (Haber, 1999). In these situations it followsthat some sensor recognizes the incurred damage at an early stageafter cell cycle exit. Furthermore, at least in some cases, thissensor is Atm (Lee et al., 2000; Sekiguchi et al., 2001). If endogenousDNA damage does occur in proliferating cells, then it is surprisingthat there is no apparent readout, such as p53 stabilization,until cell cycle exit. Perhaps this reflects relatively low levelsof damage compared with radiation, in which the presence of p53stabilization and apoptosis within the VZ points to a greatergenomic insult than endogenous DNAdamage.

The role of ATM in the nervous system is unresolved. However, one consistent feature of ATM is involvement in the responseto selective DNA damage, such as double strand breaks. Indeed,as mentioned above, recent genetic data have highlighted the importanceof the DNA damage response in nervous system development (Barneset al., 1998; Gao et al., 1998; Deans et al., 2000; Gilmore etal., 2000; Sugo et al., 2000) and the essential role of Atm forapoptotic signal transduction associated with this response (Leeet al., 2000; Sekiguchi et al., 2001). Additionally, human diseasesresulting from DNA repair or response abnormalities often arecharacterized by neurological lesions (Rolig and McKinnon, 2000).Given this clear requirement of DNA repair or DNA damage responsefor nervous system homeostasis, it seems likely that ATM is importantin this capacity in the nervous system. The data reported heresuggest a defined developmental period as critical for ATM functionand suggest that ATM probably is involved in nervous system maintenanceas early as initial neural differentiation. Less clear from thesedata is a role for ATM at later stages in the life of the nervoussystem. We have suggested previously that the progressive neurodegenerationseen in A-T is a result of cumulative damage during development,which impacts progressively as the nervous system ages (Herzoget al., 1998; Lee and McKinnon, 2000; Lee et al., 2000). However,it is also possible that ATM performs a non-DNA damage role inthe nervous system and that this aspect of ATM function may contributeto nervous system maintenance later in life. ATM function in thenervous system has been linked to regulation of the oxidativeload in the brain (Barlow et al., 1999), to a role in neurogenesis(Allen et al., 2001), to survival of dopaminergic neurons (Eilamet al., 1998), and to a possible involvement in vesicular transport(Lim et al., 1998) although, in each of these cases, the Atm-dependentmechanism isunclear.

The progression of neurodegeneration in individuals with A-T is apparent during early childhood and becomes increasingly severewith age, resulting in a requirement for a wheelchair before theearly teens. If our hypothesis of accumulated genetic damage asthe primary lesion in the nervous system of A-T individuals iscorrect, then it is likely that the progressive nature of A-Tresults from a dysfunction of damaged cells over time. However,given that all A-T individuals have an affected cerebellum, thenthere is some selectivity in the tissues that are affected, andthe dysfunction may not be simply a stochastic event in the nervoussystem. There is still a need for a more precise description ofthe progressive pathology associated with A-T, because most datato date have been derived from autopsy samples, which providelimited details about disease progression. Advances in imagingtechniques are likely to provide a detailed analysis of the progressivenature of A-T and insight into the neuropathology. These typesof insight will generate a useful framework for resolving theprogression and relative sensitivities of nervous system compartmentsaffected by ATMinactivation.

Our data also highlight the selective nature of apoptosis as it relates to differentiation status. For example, p53 is requiredfor the completion of apoptosis in proliferative and postmitoticcells after radiation, whereas Atm appears to be required forapoptosis only in postmitotic neural cells. However, between populationsof different postmitotic neural cells that are Atm-dependent forapoptosis after radiation, different death effectors can be used.This is illustrated by comparing two regions that require Atmfor IR-induced apoptosis, the developing retina and cerebellum,where Bax is essential for death in the cerebellum but is notrequired for death in retinal neuroblasts (Chong et al., 2000).Therefore, our data describing radiation-induced apoptosis inthe nervous system have revealed a number of different levelsof genetic control that are cell type-specific and cell stage-specific.

In summary, Atm function after DNA damage is linked intimately to the differentiation status of immature neural cells. Takentogether, these data underscore an important role for Atm duringearly phases of development in response to select types of DNAdamage. We hypothesize that this stage-specific function is adevelopmental checkpoint that monitors genomic integrity of neuralcells as they exit the cell cycle and begin to differentiate.This damage, if allowed to consolidate during development, willlead to the progressive neurodegeneration that is seen in ataxia-telangiectasia.

  FOOTNOTES

Received April 19, 2001; revised June 12, 2001; accepted June 20, 2001.

These studies were supported by National Institutes of Health Grants NS-37956, NS-39867, and CA-21765 and by the AmericanLebanese and Syrian Associated Charities of St. Jude Children'sResearch Hospital. We thank Dr. Suzanne Baker for discussionsand comments on thismanuscript.
Correspondence should be addressed to Dr. Peter J. McKinnon, Department of Genetics, St. Jude Children's Research Hospital,332 North Lauderdale, Memphis, TN 38105. E-mail: peter.mckinnon{at}stjude.org.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Ahn JY, Schwarz JK, Piwnica-Worms H, Canman CE (2000) Threonine 68 phosphorylation by ataxia telangiectasia mutated is required for efficient activation of Chk2 in response to ionizing radiation. Cancer Res 60:5934-5936[Abstract/Free Full Text].
Allen DM, van Praag H, Ray J, Weaver Z, Winrow CJ, Carter TA, Braquet R, Harrington E, Ried T, Brown KD, Gage FH, Barlow C (2001) Ataxia telangiectasia mutated is essential during adult neurogenesis. Genes Dev 15:554-566[Abstract/Free Full Text].
Banin S, Moyal L, Shieh S, Taya Y, Anderson CW, Chessa L, Smorodinsky NI, Prives C, Reiss Y, Shiloh Y, Ziv Y (1998) Enhanced phosphorylation of p53 by ATM in response to DNA damage. Science 281:1674-1677[Abstract/Free Full Text].
Barlow C, Hirotsune S, Paylor R, Liyanage M, Eckhaus M, Collins F, Shiloh Y, Crawley JN, Ried T, Tagle D, Wynshaw-Boris A (1996) Atm-deficient mice: a paradigm of ataxia telangiectasia. Cell 86:159-171[Web of Science][Medline].
Barlow C, Dennery PA, Shigenaga MK, Smith MA, Morrow JD, Roberts 2nd LJ, Wynshaw-Boris A, Levine RL (1999) Loss of the ataxia telangiectasia gene product causes oxidative damage in target organs. Proc Natl Acad Sci USA 96:9915-9919[Abstract/Free Full Text].
Barnes DE, Stamp G, Rosewell I, Denzel A, Lindahl T (1998) Targeted disruption of the gene encoding DNA ligase IV leads to lethality in embryonic mice. Curr Biol 8:1395-1398[Web of Science][Medline].
Borghesani PR, Alt FW, Bottaro A, Davidson L, Aksoy S, Rathbun GA, Roberts TM, Swat W, Segal RA, Gu Y (2000) Abnormal development of Purkinje cells and lymphocytes in Atm mutant mice. Proc Natl Acad Sci USA 97:3336-3341[Abstract/Free Full Text].
Canman CE, Lim DS, Cimprich KA, Taya Y, Tamai K, Sakaguchi K, Appella E, Kastan MB, Siliciano JD (1998) Activation of the ATM kinase by ionizing radiation and phosphorylation of p53. Science 281:1677-1679[Abstract/Free Full Text].
Chiesa N, Barlow C, Wynshaw-Boris A, Strata P, Tempia F (2000) Atm-deficient mice Purkinje cells show age-dependent defects in calcium spike bursts and calcium currents. Neuroscience 96:575-583[Web of Science][Medline].
Chong MJ, Murray MR, Gosink EC, Russell HR, Srinivasan A, Kapsetaki M, Korsmeyer SJ, McKinnon PJ (2000) Atm and Bax cooperate in ionizing radiation-induced apoptosis in the central nervous system. Proc Natl Acad Sci USA 97:889-894[Abstract/Free Full Text].
Crawford TO (1998) Ataxia telangiectasia. Semin Pediatr Neurol 5:287-294[Medline].
Deans B, Griffin CS, Maconochie M, Thacker J (2000) Xrcc2 is required for genetic stability, embryonic neurogenesis, and viability in mice. EMBO J 19:6675-6685[Web of Science][Medline].
Eilam R, Peter Y, Elson A, Rotman G, Shiloh Y, Groner Y, Segal M (1998) Selective loss of dopaminergic nigrostriatal neurons in brains of Atm-deficient mice. Proc Natl Acad Sci USA 95:12653-12656[Abstract/Free Full Text].
Elson A, Wang Y, Daugherty CJ, Morton CC, Zhou F, Campos-Torres J, Leder P (1996) Pleiotropic defects in ataxia-telangiectasia protein-deficient mice. Proc Natl Acad Sci USA 93:13084-13089[Abstract/Free Full Text].
Enokido Y, Araki T, Tanaka K, Aizawa S, Hatanaka H (1996) Involvement of p53 in DNA strand break-induced apoptosis in postmitotic CNS neurons. Eur J Neurosci 8:1812-1821[Web of Science][Medline].
Gao Y, Sun Y, Frank KM, Dikkes P, Fujiwara Y, Seidl KJ, Sekiguchi JM, Rathbun GA, Swat W, Wang J, Bronson RT, Malynn BA, Bryans M, Zhu C, Chaudhuri J, Davidson L, Ferrini R, Stamato T, Orkin SH, Greenberg ME, Alt FW (1998) A critical role for DNA end-joining proteins in both lymphogenesis and neurogenesis. Cell 95:891-902[Web of Science][Medline].
Gatter KC, Dunnill MS, Gerdes J, Stein H, Mason DY (1986) New approach to assessing lung tumours in man. J Clin Pathol 39:590-593[Abstract/Free Full Text].
Gatti RA, Becker-Catania S, Chun HH, Sun X, Mitui M, Lai CH, Khanlou N, Babaei M, Cheng R, Clark C, Huo Y, Udar NC, Iyer RK (2001) The pathogenesis of ataxia-telangiectasia. Learning from a Rosetta stone. Clin Rev Allergy Immunol 20:87-108[Medline].
Gilmore EC, Nowakowski RS, Caviness Jr VS, Herrup K (2000) Cell birth, cell death, cell diversity, and DNA breaks: how do they all fit together? Trends Neurosci 23:100-105[Web of Science][Medline].
Gurley KE, Kemp CJ (2001) Synthetic lethality between mutation in Atm and DNA-PK_cs during murine embryogenesis. Curr Biol 11:191-194[Medline].
Haber JE (1999) DNA recombination: the replication connection. Trends Biochem Sci 24:271-275[Web of Science][Medline].
Herzog KH, Chong MJ, Kapsetaki M, Morgan JI, McKinnon PJ (1998) Requirement for Atm in ionizing radiation-induced cell death in the developing central nervous system. Science 280:1089-1091[Abstract/Free Full Text].
Heyer BS, MacAuley A, Behrendtsen O, Werb Z (2000) Hypersensitivity to DNA damage leads to increased apoptosis during early mouse development. Genes Dev 14:2072-2084[Abstract/Free Full Text].
Kastan MB, Lim DS (2000) The many substrates and functions of ATM. Nat Rev Mol Cell Biol 1:179-186[Web of Science][Medline].
Kastan MB, Zhan Q, El-Deiry WS, Carrier F, Jacks T, Walsh WV, Plunkett BS, Vogelstein B, Fornace Jr AJ (1992) A mammalian cell cycle checkpoint pathway utilizing p53 and GADD45 is defective in ataxia-telangiectasia. Cell 71:587-597[Web of Science][Medline].
Khanna KK, Keating KE, Kozlov S, Scott S, Gatei M, Hobson K, Taya Y, Gabrielli B, Chan D, Lees-Miller SP, Lavin MF (1998) ATM associates with and phosphorylates p53: mapping the region of interaction. Nat Genet 20:398-400[Web of Science][Medline].
Lavin MF, Shiloh Y (1997) The genetic defect in ataxia-telangiectasia. Annu Rev Immunol 15:177-202[Web of Science][Medline].
Lee Y, McKinnon PJ (2000) ATM-dependent apoptosis in the nervous system. Apoptosis 5:523-529[Web of Science][Medline].
Lee Y, Barnes DE, Lindahl T, McKinnon PJ (2000) Defective neurogenesis resulting from DNA ligase IV deficiency requires Atm. Genes Dev 14:2576-2580[Abstract/Free Full Text].
Lim DS, Kirsch DG, Canman CE, Ahn JH, Ziv Y, Newman LS, Darnell RB, Shiloh Y, Kastan MB (1998) ATM binds to $beta$ -adaptin in cytoplasmic vesicles. Proc Natl Acad Sci USA 95:10146-10151[Abstract/Free Full Text].
Lim DS, Kim ST, Xu B, Maser RS, Lin J, Petrini JH, Kastan MB (2000) ATM phosphorylates p95/nbs1 in an S-phase checkpoint pathway. Nature 404:613-617[Medline].
Meek DW (1999) Mechanisms of switching on p53: a role for covalent modification? Oncogene 18:7666-7675[Web of Science][Medline].
Menisser-de Murcia J, Mark M, Wendling O, Wynshaw-Boris A, de Murcia G (2001) Early embryonic lethality in PARP-1 Atm double-mutant mice suggests a functional synergy in cell proliferation during development. Mol Cell Biol 21:1828-1832[Abstract/Free Full Text].
Midgley CA, Fisher CJ, Bartek J, Vojtesek B, Lane D, Barnes DM (1992) Analysis of p53 expression in human tumours: an antibody raised against human p53 expressed in Escherichia coli. J Cell Sci 101:183-189[Abstract/Free Full Text].
Morrison RS, Wenzel HJ, Kinoshita Y, Robbins CA, Donehower LA, Schwartzkroin PA (1996) Loss of the p53 tumor suppressor gene protects neurons from kainate-induced cell death. J Neurosci 16:1337-1345[Abstract/Free Full Text].
Rolig RL, McKinnon PJ (2000) Linking DNA damage and neurodegeneration. Trends Neurosci 23:417-424[Web of Science][Medline].
Rotman G, Shiloh Y (1998) ATM: from gene to function. Hum Mol Genet 7:1555-1563[Abstract/Free Full Text].
Savitsky K, Bar-Shira A, Gilad S, Rotman G, Ziv Y, Vanagaite L, Tagle DA, Smith S, Uziel T, Sfez S, Ashkenazi M, Pecker I, Frydman M, Harnik R, Patanjali SR, Simmons A, Clines GA, Sartiel A, Gatti RA, Chessa L, Sanal O, Lavin MF, Jaspers NGJ, Taylor AMR, Arlett CF, Miki T, Weissman SM, Lovett M, Collins FS, Shiloh Y (1995) A single ataxia-telangiectasia gene with a product similar to PI₃ kinase. Science 268:1749-1753[Abstract/Free Full Text].
Sedgwick RP, Boder E (1991) Ataxia-telangiectasia. In: Handbook of clinical neurology (Vinken P, Bruyn G, Klawans H, eds), pp 347-423. New York: Elsevier.
Sekiguchi J, Ferguson DO, Chen HT, Yang EM, Earle J, Frank K, Whitlow S, Gu Y, Xu Y, Nussenzweig A, Alt FW (2001) Genetic interactions between ATM and the nonhomologous end-joining factors in genomic stability and development. Proc Natl Acad Sci USA 98:3243-3248[Abstract/Free Full Text].
Shiloh Y (2001) ATM and ATR: networking cellular responses to DNA damage. Curr Opin Genet Dev 11:71-77[Web of Science][Medline].
Soares HD, Morgan JI, McKinnon PJ (1998) Atm expression patterns suggest a contribution from the peripheral nervous system to the phenotype of ataxia-telangiectasia. Neuroscience 86:1045-1054[Web of Science][Medline].
Sugo N, Aratani Y, Nagashima Y, Kubota Y, Koyama H (2000) Neonatal lethality with abnormal neurogenesis in mice deficient in DNA polymerase $beta$ . EMBO J 19:1397-1404[Web of Science][Medline].
Tibbetts RS, Brumbaugh KM, Williams JM, Sarkaria JN, Cliby WA, Shieh SY, Taya Y, Prives C, Abraham RT (1999) A role for ATR in the DNA damage-induced phosphorylation of p53. Genes Dev 13:152-157[Abstract/Free Full Text].
Waterman MJ, Stavridi ES, Waterman JL, Halazonetis TD (1998) ATM-dependent activation of p53 involves dephosphorylation and association with 14-3-3 proteins. Nat Genet 19:175-178[Web of Science][Medline].
Xu Y, Ashley T, Brainerd EE, Bronson RT, Meyn MS, Baltimore D (1996) Targeted disruption of ATM leads to growth retardation, chromosomal fragmentation during meiosis, immune defects, and thymic lymphoma. Genes Dev 10:2411-2422[Abstract/Free Full Text].
Young RW (1985a) Cell proliferation during postnatal development of the retina in the mouse. Brain Res 353:229-239[Medline].
Young RW (1985b) Cell differentiation in the retina of the mouse. Anat Rec 212:199-205[Medline].

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